header image

Page 27«..1020..26272829..4050..»

Incredible Story And Purpose Behind New Houlton Business – q961.com

We all know that dogs have been forever called mans best friendand throughout the pandemic dog adoptions increased because more people wanted to have acompanion during lockdowns. In our area there were several pets adopted and there is a new service that will help you train your newfour-leggedfriend.

Purpose Pups LLC in Houlton is now open and hosting a grand opening this Saturday June 12from noon until 5:00 pm.The family-owned business specializes in full-servicedog training and several Elite Dog Trainings solutions. Tyler Jonesis the trainer for Purpose Pups which is owned by his parents David and Helen Jones. David is a retired Navy veteran and Helen has been achildren'sdisabilityadvocate for over 40 years.

Meet Tyler Jones:

Whats behind the name?

Purpose Pups name is not incidental. P.U.R.P.O.S.E.ProvideUsefulReliablePartnershipsOurSocietyEmploys. If youve ever adopted a pet for general purposes or for therapeutic reasons then you know that the intention behind the name is spot on.

But theres got to be more to the story?

Yes,there is more to the story of Purpose Pups and how the business came into realization.It's a great story of redemption and a reminder that even when you get knocked down in life theres always a chance to get back up and keep fighting. Tylercame up with the idea for Purpose Pups while in the NEADS(National Education for Assistance Dog Services)Prison Pup program.After being sentenced to 9 years for a nonviolent marijuana crimeTyler was able to receive excess of 7,000 hours of positivereinforcement-basedtraining.

Take on Tyler's attitude

At a time in life when many people would give up or continue on the same journey, Tyler made the choice to better himself. He hit the ground running with his vision of Purpose Pups. As you cansee,he is well versed in dog traininghad has his animal trainer certifications from the Department of Labor.

Purpose Pups can train your dog for obedience training, loose leash walking andcommand response.In my opinion, the most valuable service Tyler offers our area isService Dog Training. This is a huge need in Aroostook County right now and with adoptions on the rise there is a need for thisspecification.Tyler can work with service dogs, emotional support dogs, therapy dogs, and much more.

For more information stop by Purpose Pups at 70 Bangor Street in Houlton or follow Purpose Pups LLC Facebook page.A complete list of servicesareavailable at the Purpose Pups website

To prepare yourself for a potential incident, always keep your vet's phone number handy, along with an after-hours clinic you can call in an emergency. The ASPCA Animal Poison Control Center also has a hotline you can call at (888) 426-4435 for advice.

Even with all of these resources, however, the best cure for food poisoning is preventing it in the first place. To give you an idea of what human foods can be dangerous, Stacker has put together a slideshow of 30 common foods to avoid. Take a look to see if there are any that surprise you.

See more here:
Incredible Story And Purpose Behind New Houlton Business - q961.com

Keep Your Dog Safe This Summer: Tips from the SPCA of SW Michigan – wkfr.com

Walking out of my home at 4am to 72 degree, humid weather was a stark reminder that summer is pretty much here. Yes, the official start of summer is on June 20th, but with 90 degree days I'm sure we're all ready to get out and enjoy the sun.

However, if you're a dog owner there are a few things to look out for to make sure your pup stays safe during the hotter months.

The SPCA of SW Michigan recently shared a Facebook post outlining what to look out for and how to avoid summertime issues with your pet.

First, let's start with the 'top tips'...they may be common knowledge but it's always nice to have a reminder:

There are a few things you should always avoid when it comes to your dog and the summertime heat:

Now, with the introduction of newer, smarter cars you may be able to leave the car parked and running with the air conditioning going. However, there are still far too many cases of people leaving their animals in a parked, locked, hot car because they'll 'only be in the store for a minute'.

Earlier in my life I worked as a receptionist at a veterinarian's office in Florida. We only saw one dog for heat stroke but it was because they left this poor baby in the car. They had only been in the store for 10, maybe 15 minutes but that was all it took. Cars become much hotter much faster than any of us realize.

We can do our best to plan and prepare but what happens to a dog when they're overheated or experiencing a heat stroke? Here's what to look out for:

Those are among the few signs and symptoms to look out for. See the full list here.

As well, there are specific breeds that are more susceptible to heat stroke. If you have any of the following breeds, or dogs that fall under these categories, make sure to monitor them closely:

If you're anything like me the instinct to rescue an animal in a dangerous situation is...strong. However, laws regarding breaking windows to save a dog from overheating vary from state to state. Brush up on Michigan's laws, which prohibit you from breaking that window, below:

With the majority of cats residing indoors, the SPCA says you don't usually have to worry about them overheating in normal circumstances. After all, they never leave the house. If, however, you have an outdoor cat the SPCAsays that you can always provide a little outdoor shelter to offer a bit of shade.

To prepare yourself for a potential incident, always keep your vet's phone number handy, along with an after-hours clinic you can call in an emergency. The ASPCA Animal Poison Control Center also has a hotline you can call at (888) 426-4435 for advice.

Even with all of these resources, however, the best cure for food poisoning is preventing it in the first place. To give you an idea of what human foods can be dangerous, Stacker has put together a slideshow of 30 common foods to avoid. Take a look to see if there are any that surprise you.

LOOK: The least obedient dog breeds

Visit link:
Keep Your Dog Safe This Summer: Tips from the SPCA of SW Michigan - wkfr.com

The Canine Stem Cell Therapy Market To Witness An Exponential Satiation In The Next 10 Years The Courier – The Courier

Like all the other verticals, the healthcare vertical is poised to witness an amalgamation of collaborations and networks as a result of the culture of belonging and inclusion being the new DNA therein. Also, remote work arrangements will be simplified with shared services, cloud technologies, and AI is in place. The Canine Stem Cell Therapy Market is meant to capture these happenings and give insights regarding the same.

Persistence Market Research (PMR) has published a new research report on canine stem cell therapy. The report has been titled, Canine Stem Cell Therapy Market: Global Industry Analysis 2016 and Forecast 20172026.Veterinary research has been used in regenerative and adult stem cell therapy andhas gained significant traction over the last decade.

Canine stem cell therapy products are identified to have gained prominence over the past five years, and according to the aforementioned research report, the market for canine stem cell therapy will expand at a moderate pace over the next few years.

Get Sample Copy of Report @https://www.persistencemarketresearch.com/samples/15550

Company Profiles

Get To Know Methodology of Report @https://www.persistencemarketresearch.com/methodology/15550

Though all animal stem cells are not approved by FDA, veterinary stem-cell manufacturers and university researchers have been adopting various strategies in order to meet regulatory approvals, and streamline and expedite the review-and-approval process. The vendors in the market are incessantly concentrating on research and development to come up with advanced therapy, in addition to acquiring patents.

In September 2017, VetStem Biopharma, Inc. received European patent granted to the University of Pittsburgh and VetStem received full license of the patent then. This patent will eventually provide the coverage for the ongoing commercial and product development programs of VetStem and might be also available for licensing to other companies who are rather interested in this field.

The other companies operating in the global market for canine stem cell therapy are VETherapy Corporation, Aratana Therapeutics, Inc., Regeneus Ltd, Magellan Stem Cells, Animal Cell Therapies, Inc., and Medrego, among others.

According to the Persistence Market Research report, the globalcanine stem cell therapy marketis expected to witness aCAGR of 4.2%during the forecast period 2017-2026. In 2017, the market was valued at US$ 151.4 Mn and is expected to rise to a valuation ofUS$ 218.2 Mnby the end of 2026.

Burgeoning Prevalence of Chronic Diseases in Dogs to Benefit Market

Adipose Stem Cells (ASCs) are the most prevalent and in-demand adult stem cells owing to their safety profile, ease of harvest, and use and the ability to distinguish into multiple cell lineages. Most early clinical research is focused on adipose stem cells to treat various chronic diseases such as arthritis, tendonitis, lameness, and atopic dermatitis in dogs.

A large area of focus in veterinary medicine is treatment of osteoarthritis in dogs, which becomes more prevalent with age. Globally, more than 20% dogs are suffering from arthritis, which is a common form of canine joint and musculoskeletal disease. Out of those 20%, merely 5% seem to receive the treatment.

However, elbow dysplasia in canine registered a prevalence rate of 64%, converting it into an alarming disease condition to be treated on priority. Thereby, with the growing chronic disorders in canine, the demand for stem cell therapy is increasing at a significant pace.

Access Full Report @https://www.persistencemarketresearch.com/checkout/15550

Expensive Nature of Therapy to Obstruct Growth Trajectory

Expensive nature and limited access to canine stem cell therapy has demonstrated to be a chief hindrance forestalling its widespread adoption. The average tier II and tier III veterinary hospitals lack the facilities and expertise to perform stem cell procedures, which necessitates the referral to a specialty vet hospital with expertise veterinarians.

A trained veterinary physician charges high treatment cost associated with stem cell therapy for dogs. Generally, dog owners have pet insurance that typically covers maximum cost associated with steam cell therapy to treat the initial injury but for the succeeding measures in case of retreatment, the costs are not covered under the pet insurance. The stem cell therapy is thus cost-prohibitive for a large number of pet owners, which highlights a major restraint to the market growth. Stem cell therapy is still in its developmental stage and a positive growth outcome for the market cannot be confirmed yet.

About Us:

Persistence Market Research is here to provide companies a one-stop solution with regards to bettering customer experience. It does engage in gathering appropriate feedback after getting through personalized customer interactions for adding value to customers experience by acting as the missing link between customer relationships and business outcomes. The best possible returns are assured therein.

Contact Us:

Persistence Market ResearchAddress 305 Broadway, 7th Floor, New York City, NY 10007 United StatesU.S. Ph. +1-646-568-7751USA-Canada Toll-free +1 800-961-0353Salessales@persistencemarketresearch.comWebsite https://www.persistencemarketresearch.com

See more here:
The Canine Stem Cell Therapy Market To Witness An Exponential Satiation In The Next 10 Years The Courier - The Courier

Fate Therapeutics Highlights Positive Interim Data from its Phase 1 Study of FT516 in Combination with – GlobeNewswire

8 of 11 Patients in Dose Escalation Cohorts 2 and 3 Achieved Objective Response

6 of 11 Patients Achieved Complete Response, including 2 Patients Previously Treated with Autologous CD19 CAR T-cell Therapy

Favorable FT516 Safety Profile Was Observed; No FT516-related Serious Adverse Events or FT516-related Grade 3 or Greater Adverse Events

Outpatient Treatment Regimen Was Well-tolerated; No Events of Any Grade of Cytokine Release Syndrome, Immune Effector Cell-Associated Neurotoxicity Syndrome, or Graft-vs-Host Disease

SAN DIEGO, June 04, 2021 (GLOBE NEWSWIRE) -- Fate Therapeutics, Inc. (NASDAQ: FATE), a clinical-stage biopharmaceutical company dedicated to the development of programmed cellular immunotherapies for cancer, today highlighted positive interim Phase 1 data from the Companys FT516 program for patients with relapsed / refractory B-cell lymphoma at the 2021 American Society of Clinical Oncology (ASCO) Annual Meeting being held virtually June 4-8, 2021. FT516 is the Companys universal, off-the-shelf natural killer (NK) cell product candidate derived from a clonal master induced pluripotent stem cell (iPSC) line engineered with a novel high-affinity, non-cleavable CD16 (hnCD16) Fc receptor, which is designed to maximize antibody-dependent cellular cytotoxicity (ADCC), a potent anti-tumor mechanism by which NK cells recognize, bind and kill antibody-coated cancer cells. The ongoing Phase 1 dose-escalation study of FT516 is currently enrolling patients in the fourth dose cohort of 900 million cells per dose.

As of the data cutoff date of March 11, 2021, four patients in the second dose cohort of 90 million cells per dose and seven patients in the third dose cohort of 300 million cells per dose were evaluable for assessment of safety and efficacy. Eight of eleven patients achieved an objective response, including six patients who achieved a complete response, as assessed by PET-CT scan per Lugano 2014 criteria (see Table 1). Patients had received a median of three prior lines of therapy and a median of two prior lines containing CD20-targeted therapy. Of the eleven patients, eight patients had aggressive B-cell lymphoma, five patients were refractory to their most recent prior therapy, and four patients were previously treated with autologous CD19 CAR-T cell therapy.

These additional data from our Phase 1 study of FT516 administered off-the-shelf in the outpatient setting continue to reinforce its differentiated safety profile and underscore its potential clinical benefit, said Wayne Chu, M.D., Senior Vice President of Clinical Development of Fate Therapeutics. Based on the favorable therapeutic profile of FT516 that continues to emerge and the potential to treat patients on-demand without delay, we plan to initiate multiple indication-specific, dose-expansion cohorts for patients with B-cell lymphomas to broadly assess FT516 in combination with CD20-targeted monoclonal antibody regimens, including those used as standard-of-care in earlier-line settings.

The ongoing Phase 1 clinical trial in relapsed / refractory B-cell lymphoma is assessing FT516 in an off-the-shelf treatment regimen of up to two cycles, with each cycle consisting of three days of conditioning chemotherapy (500 mg/m2 of cyclophosphamide and 30 mg/m2 of fludarabine), a single-dose of rituximab (375 mg/m2), and three weekly doses of FT516 each with IL-2 cytokine support. The FT516 treatment regimen is designed to be administered in the outpatient setting.

Safety DataNo dose-limiting toxicities, and no FT516-related serious adverse events or FT516-related Grade 3 or greater adverse events, were observed. The FT516 treatment regimen was well tolerated, and no treatment-emergent adverse events (TEAEs) of any grade of cytokine release syndrome, immune effector cell-associated neurotoxicity syndrome, or graft-versus-host disease were reported by investigators (see Table 2). All Grade 3 or greater TEAEs were consistent with lympho-conditioning chemotherapy and underlying disease. Of note, a Grade 3 or greater TEAE of infection was reported in one patient only. There were no discontinuations due to adverse events, and no patients withdrew from the study except in the setting of disease progression. In addition, no evidence of anti-product T- or B-cell mediated host-versus-product alloreactivity was detected, supporting the potential to safely administer up to six doses of FT516 in the outpatient setting without the need for patient matching.

Activity DataAs of the data cutoff date of March 11, 2021, eleven relapsed / refractory patients in the second and third dose cohorts were evaluable for assessment of safety and efficacy. Of the eleven patients, nine patients completed both FT516 treatment cycles and eight patients achieved an objective response, including six patients who achieved a complete response, as assessed by PET-CT scan per Lugano 2014 criteria. Notably, two of four patients previously treated with autologous CD19 CAR-T cell therapy achieved a complete response. Two patients showed progressive disease following the first FT516 treatment cycle and discontinued treatment. The Company previously reported that two patients treated in the first dose cohort (30 million cells per dose) showed progressive disease.

Patient Case StudyThe ASCO presentation featured a case study of a 36-year old male with triple-hit, high-grade B-cell lymphoma with rearrangements of MYC, BCL2, and BCL6 genes. The patient was refractory to all prior lines of therapy with the exception of autologous CD19 CAR T-cell therapy, for which a complete response of two months duration was achieved. The patient was most recently refractory to an investigational CD20-targeted T-cell engager and presented with bulky lymphadenopathy with the largest lesion measuring approximately 10 centimeters. The first FT516 treatment cycle resulted in a complete response with resolution of all metabolically active disease and 85% reduction in the size of target lesions. Subsequent to the data cutoff date of March 11, 2021, the patient completed a second FT516 treatment cycle after which the response assessment continued to show complete response.

As of March 11, 2021 database entry. Data subject to source document verification.CR = Complete Response; PR = Partial Response; PD = Progressive DiseaseCAR = Chimeric antigen receptor; DH/DE = Double-hit / double expressor; DLBCL = Diffuse large B-cell lymphoma; FL = Follicular lymphoma; Gr = Grade; HGBCL = High-grade B-cell lymphoma; iNHL = Indolent non-Hodgkin lymphoma; TH = Triple-hit; Transformed iNHL = Aggressive B-cell lymphoma transformed from indolent non-Hodgkin lymphoma1 Cycle 2 Day 29 protocol-defined response assessment per Lugano 2014 criteria2 Subject did not proceed to Cycle 23 Confirmed DLBCL (transformation from Gr3A FL) subsequent to the data cutoff date of March 11, 20214 Cycle 2 Day 29 protocol-defined response assessment reported subsequent to the data cutoff date of March 11, 2021

CRS = Cytokine Release Syndrome; DL = Dose Level; GvHD = Graft vs. Host Disease; ICANS = Immune Cell-Associated Neurotoxicity Syndrome;M = Million; SAE = Serious Adverse Event; TEAE = Treatment-Emergent Adverse Event1 Includes two subjects in the first dose cohort of 30 million cells per dose

About Fate Therapeutics iPSC Product PlatformThe Companys proprietary induced pluripotent stem cell (iPSC) product platform enables mass production of off-the-shelf, engineered, homogeneous cell products that are designed to be administered with multiple doses to deliver more effective pharmacologic activity, including in combination with other cancer treatments. Human iPSCs possess the unique dual properties of unlimited self-renewal and differentiation potential into all cell types of the body. The Companys first-of-kind approach involves engineering human iPSCs in a one-time genetic modification event and selecting a single engineered iPSC for maintenance as a clonal master iPSC line. Analogous to master cell lines used to manufacture biopharmaceutical drug products such as monoclonal antibodies, clonal master iPSC lines are a renewable source for manufacturing cell therapy products which are well-defined and uniform in composition, can be mass produced at significant scale in a cost-effective manner, and can be delivered off-the-shelf for patient treatment. As a result, the Companys platform is uniquely designed to overcome numerous limitations associated with the production of cell therapies using patient- or donor-sourced cells, which is logistically complex and expensive and is subject to batch-to-batch and cell-to-cell variability that can affect clinical safety and efficacy. Fate Therapeutics iPSC product platform is supported by an intellectual property portfolio of over 350 issued patents and 150 pending patent applications.

About FT516FT516 is an investigational, universal, off-the-shelf natural killer (NK) cell cancer immunotherapy derived from a clonal master induced pluripotent stem cell (iPSC) line engineered to express a novel high-affinity 158V, non-cleavable CD16 (hnCD16) Fc receptor, which has been modified to prevent its down-regulation and to enhance its binding to tumor-targeting antibodies. CD16 mediates antibody-dependent cellular cytotoxicity (ADCC), a potent anti-tumor mechanism by which NK cells recognize, bind and kill antibody-coated cancer cells. ADCC is dependent on NK cells maintaining stable and effective expression of CD16, which has been shown to undergo considerable down-regulation in cancer patients. In addition, CD16 occurs in two variants, 158V or 158F, that elicit high or low binding affinity, respectively, to the Fc domain of IgG1 antibodies. Scientists from the Company have shown in a peer-reviewed publication (Blood. 2020;135(6):399-410) that hnCD16 iPSC-derived NK cells, compared to peripheral blood NK cells, elicit a more durable anti-tumor response and extend survival in combination with anti-CD20 monoclonal antibodies in an in vivo xenograft mouse model of human lymphoma. Numerous clinical studies with FDA-approved tumor-targeting antibodies, including rituximab, trastuzumab and cetuximab, have demonstrated that patients homozygous for the 158V variant, which is present in only about 15% of patients, have improved clinical outcomes. FT516 is being investigated in a multi-dose Phase 1 clinical trial as a monotherapy for the treatment of acute myeloid leukemia and in combination with CD20-targeted monoclonal antibodies for the treatment of advanced B-cell lymphoma (NCT04023071). Additionally, FT516 is being investigated in a multi-dose Phase 1 clinical trial in combination with avelumab for the treatment of advanced solid tumor resistant to anti-PDL1 checkpoint inhibitor therapy (NCT04551885).

About Fate Therapeutics, Inc.Fate Therapeutics is a clinical-stage biopharmaceutical company dedicated to the development of first-in-class cellular immunotherapies for patients with cancer. The Company has established a leadership position in the clinical development and manufacture of universal, off-the-shelf cell products using its proprietary induced pluripotent stem cell (iPSC) product platform. The Companys immuno-oncology pipeline includes off-the-shelf, iPSC-derived natural killer (NK) cell and T-cell product candidates, which are designed to synergize with well-established cancer therapies, including immune checkpoint inhibitors and monoclonal antibodies, and to target tumor-associated antigens using chimeric antigen receptors (CARs). Fate Therapeutics is headquartered in San Diego, CA. For more information, please visit http://www.fatetherapeutics.com.

Forward-Looking StatementsThis release contains "forward-looking statements" within the meaning of the Private Securities Litigation Reform Act of 1995 including statements regarding the safety and therapeutic potential of the Companys iPSC-derived NK cell product candidates, including FT516, its ongoing and planned clinical studies, and the expected clinical development plans for FT516. These and any other forward-looking statements in this release are based on management's current expectations of future events and are subject to a number of risks and uncertainties that could cause actual results to differ materially and adversely from those set forth in or implied by such forward-looking statements. These risks and uncertainties include, but are not limited to, the risk that results observed in studies of its product candidates, including preclinical studies and clinical trials of any of its product candidates, will not be observed in ongoing or future studies involving these product candidates, the risk that the Company may cease or delay clinical development of any of its product candidates for a variety of reasons (including requirements that may be imposed by regulatory authorities on the initiation or conduct of clinical trials, the amount and type of data to be generated, or otherwise to support regulatory approval, difficulties or delays in subject enrollment and continuation in current and planned clinical trials, difficulties in manufacturing or supplying the Companys product candidates for clinical testing, and any adverse events or other negative results that may be observed during preclinical or clinical development), and the risk that its product candidates may not produce therapeutic benefits or may cause other unanticipated adverse effects. For a discussion of other risks and uncertainties, and other important factors, any of which could cause the Companys actual results to differ from those contained in the forward-looking statements, see the risks and uncertainties detailed in the Companys periodic filings with the Securities and Exchange Commission, including but not limited to the Companys most recently filed periodic report, and from time to time in the Companys press releases and other investor communications.Fate Therapeutics is providing the information in this release as of this date and does not undertake any obligation to update any forward-looking statements contained in this release as a result of new information, future events or otherwise.

Contact:Christina TartagliaStern Investor Relations, Inc.212.362.1200christina@sternir.com

Read this article:
Fate Therapeutics Highlights Positive Interim Data from its Phase 1 Study of FT516 in Combination with - GlobeNewswire

Clinical evaluation of intra-articular injection of Tin-117m | VMRR – Dove Medical Press

Introduction

Canine elbow osteoarthritis (OA) is a common sequela from elbow dysplasia.1 Elbow OA is a progressive joint disease characterized by decreased joint range of motion, pain, cartilage destruction, and osteophyte formation.1,2 Treatment is mainly palliative and current strategies often consist of medical management including NSAIDs, analgesics, nutraceuticals, weight control, physical rehabilitation, and changes in activity level.13 Although daily use of NSAIDs may reduce OA pain, these agents have the potential to cause or exacerbate renal, gastrointestinal, and hepatobiliary disorders.4 In addition, it may not be practical for some owners to administer daily medications. Surgery often fails to prevent progression of OA and may not provide superior outcomes to medical management.5,6 Salvage procedures such as elbow replacement have inconsistent outcomes and a high complication rate.1,7,8

Nonsurgical management will likely remain a viable treatment option for dogs with elbow OA; therefore, optimization of current nonsurgical options and development of new innovative nonsurgical treatments are important. The use of intra-articular (IA) injections including platelet-rich plasma, dextrose prolotherapy, autologous protein solution, or stem cells has been reported for OA treatment with mixed results.912 Larger clinical studies are needed to fully understand the effects of these therapies on dogs with OA.

Synovitis precedes development of radiographic OA changes in humans and dogs.2,13,14 It is characterized by marked hyperplasia and permeability of the synovial lining, overexpression of proinflammatory cytokines, infiltration of inflammatory cells, production of degradative enzymes, and synovial neovascularization and proliferation.15 Inflammation sensitizes peripheral neurons in synovial tissue, resulting in joint pain.16 Marked synovitis precedes structural changes in the progression of OA and early intervention targeting joint inflammation, prior to radiographic changes, can delay or prevent chronic arthritic changes.15 Low-dose radiation therapy has direct anti-inflammatory effects on the synovium.17 A small study of 5 dogs with elbow OA concluded that use of single-low-dose radiotherapy may have short-term clinical benefits.18

As synovitis is strongly implicated in OA pathogenesis, surgical and nonsurgical synovectomy (synoviorthesis) have been used to alleviate human synovitis symptoms.19 Another reported method to relieve synovitis is via radiosynoviorthesis (RSO), which involves IA injection of low-energy ionizing radiation to induce apoptosis and ablate inflamed synovial cells.20 Use of this therapy has been reported in humans to treat synovitis in an effort to prevent, delay, or limit arthritic changes.20 Radiosynoviorthesis, primarily involving yttrium-90 (90Y), erbium-169 (169Er), and rhenium-186 (186Re), is an accepted outpatient therapy for treatment of early-stage chronic synovitis in humans with rheumatoid arthritis, psoriatic arthritis, hemophilic arthritis or OA.20,21 The success rate of RSO reported by Zuderman et al was 89% for rheumatoid arthritis and 79% for OA in humans.22 Tin 117m (117mSn) homogeneous colloid was specifically developed to avoid the serious outcomes following treatment with high-energy beta emitters.23 Tin 117m colloid is a non-beta emitter with lower energy from which the conversion electrons have a therapeutic distance of activity of only 300 microns (0.3 mm).

Despite its many advantages, RSO is seldom performed in veterinary medicine, with limited reports including use of 177lutetium-labeled zirconia in dogs and 117mSn homogeneous colloid in rats.2426 In a recent prospective safety study of 5 dogs, blood, urine, feces, and organ scintigraphy counts showed that >99% of 117mSn activity was retained in the elbow joint for approximately 67 weeks.23 There were no adverse effects, and post-mortem evaluation revealed no joint damage. These findings, combined with the potential for protracted clinical improvement after a single IA injection, justify further evaluation of 117mSn for the management of canine OA. The authors designed the current study to assess the value of IA 117mSn for pain management in dogs with naturally occurring elbow OA. Specifically, the authors aimed to quantify changes in peak vertical force (PVF) from force plate gait analysis as the primary outcome measure and canine brief pain inventory (CBPI) scores and elbow goniometry as secondary outcome measures, at multiple time-points for one year after a single unilateral IA injection of 117mSn in dogs with grade 1 or 2 elbow OA. By limiting the study to unilateral elbow injection, the opposite leg is a source of comparison data. The hypothesis was that IA 117mSn-colloid treatment is associated with clinically relevant beneficial effects in dogs with elbow OA.

The study was designed as a long-term longitudinal and prospective study using serial measurements in dogs. The study protocol was approved by the Institutional Animal Care and Use Committee and informed client consent was obtained prior to study enrollment.

A convenience sample of 23 dogs was used in this study. No sample size calculation was performed. Dogs were eligible if they were, 8kg, at least 1 year of age, had a visible forelimb lameness or pain localizable to one or both elbows, had radiographic evidence of grade 1 or 2 OA in one or both elbows based on international elbow working group (IEWG) classification,27 had no clinically detectable abnormalities including pain in any other joint in the forelimbs, had no comorbid condition likely to preclude a 1-year survival, and had no surgical procedure on any leg in the past 4 months or received any joint injections previously. Elbow OA grading was performed by a single board-certified radiologist. All images were calibrated, and osteophyte size was prioritized over trabecular pattern. Dogs with orthopedic disease affecting either hind limb were considered eligible as long as there was no visible lameness present in any of the hind limbs. Dogs being treated with nutraceuticals and/or medications such as NSAIDs were eligible provided they still had lameness or pain localizable to one or both elbow/s.

Initially, information was collected from dog owners including signalment, duration of OA, and type and duration of current medications/supplements. Owners also completed the CBPI.28,29 After meeting initial evaluation requirements, all dogs received a baseline assessment within 30 days of treatment prior to study participation. Dogs had a physical examination, and the following variables were obtained: CBC, serum biochemistry, urinalysis (UA), bilateral elbow radiographs, bilateral elbow goniometry and PVF using force plate gait analysis. These parameters were also collected post-treatment at 1, 3, 6, 9, and 12 months. Bilateral elbow radiographs were performed at the 12-month follow-up exam. Treatment included a unilateral IA injection of 117mSn in the elbow that was determined to be the source of observable lameness or was more painful when observable lameness was not noted. Dogs were randomly assigned to one of the three 117mSn dose groups (normalized based on body surface area, Supplementary Table 1): low dose (LD): 1.0 mCi (millicuries) or 37 MBq (MegaBequerel), medium dose (MD): 1.75mCi or 64.75 MBq and high dose (HD): 2.5mCi or 92.5 MBq, using a computer-generated randomized table. Observers and owners were masked to the dose group except the radiologist who injected the colloid.

Both sites used the same model force-plate (OR6-WP-1000, Advanced Medical Technology Inc, Newton, MA) and commercially available force-plate analysis software. Data logging (100Hz, Acquire version 7.3, Sharon Software Inc, Dewitt, MI) was triggered by a force of 5N on the force plate. Five successful trials at a velocity of 1.52.5m/sec and acceleration of 0.9 to 0.9m/sec2 were recorded for each leg. Dogs were acclimated and trained to walk across the force plate during the pretreatment gait trial. Trained handlers walked the dogs for all testing. PVF (N/kg) was recorded and normalized to body weight and the mean value of five trials was used for statistical analyses. Body weight distribution % (BW-D%) between the forelimbs was calculated according to the formula: BW-D% = PVFT/(PVFUT + PVFT) 100%, where PVFT = mean PVF of the treated leg, and PVFUT = mean PVF of the contralateral untreated leg.

A positive response was defined as 5% increase in mean PVF at a single time point in the treated leg2934 at months 1, 3, 6, 9, and/or 12 compared with baseline (0 month) for each individual dog evaluated on the force plate.

Owners completed the CBPI28,35 scores at initial evaluation and then monthly from 1 through 12 months except for the 2nd month post treatment. The same individual was required to complete the survey each time. Owners did not have access to their previous scores at each follow-up visit.

A single boarded surgeon from each site performed a physical/orthopedic examination. Elbow goniometry was performed using a standard two-arm plastic goniometer as previously described.36

Dogs were anesthetized, positioned in dorsal recumbency, and the medial aspect of the elbow to be injected was aseptically prepped. The homogeneous 117mSn-colloid (Synovetin OA, Exubrion Therapeutics, Buford, GA) was injected into the joint as previously described.23 After completion of the injection, dogs were recovered from anesthesia and discharged the following morning. Instructions for care and handling with regards to the radioisotope were provided to the owners. All disposables coming in contact with 117Sn were disposed of following all State Regulatory Commission guidelines. Tin 117m is a non-beta emitter in which radiation burns do not occur. The low-energy characteristics of the therapeutic conversion electrons are very different from the higher energy beta emitters (90Y, 169Er, 186Re) commonly used in human RSO.20 As mentioned, elbow injection doses of Tin 117m were based on a chart based on body surface area (Supplementary Table 1) to allow clinicians to adhere to the ALARA (as low as reasonably achievable) principle. Previous studies in both laboratory rats and dogs in which histologic sections were obtained have shown that even with higher doses of homogeneous Tin 117m colloid, beta burns did not occur.23,25 Standard industry precautions were taken when handling homogeneous tin colloid as with any unsealed radiation source as prescribed by the Nuclear Regulatory Commission.

Data analyses were performed using JMP Pro 15.0 (SAS Institute Inc., Cary, NC). All continuous parameters were presented as mean SD and assessed with a repeated measure ANOVA with a mixed effect model was used with time as the fixed effect and each dog as the random effects with the variance compounds covariance structure within each dose group and within treated or untreated elbow. Kenward-Roger approximation was used to determine the degrees of freedom in the model. A contrast hypothesis was performed at each time point against baseline. Assumptions of these models (linearity, normality of residuals, and homoscedasticity of residuals) and influential data points were assessed by examining standardized residual and quantile plots, and the normality of residual was confirmed with the ShapiroWilk test. Ordinal subjective variables at each time point were presented as median (range). Due to small sample size, the data was combined and compared with baseline and untreated elbow using a Wilcoxon signed-rank test. The outcomes of positive response among 3 groups were evaluated with Fishers exact test. Significance was set at P <0.05.

Demographic characteristics of the study population are shown in Table 1. One dog in the LD-group received a much lower dose, about 40% lower than the prescribed dose of 117mSn-colloid, so that dog was excluded from the study. Another dog (female intact) from the HD-group was excluded because the owner reported the dog had rough play with two other large housemate dogs and was very sore in the front limbs especially on the treated limb at the one-month recheck and the same dog was bred later during the three-month recheck. The exclusion of these 2 dogs resulted in a total of 21 dogs in our study population. Duration of arthritis and type of medical management are shown in Supplementary Table 2. All dogs had visible unilateral lameness except 3 dogs (2 had bilateral grade 1 OA and 3rd one had bilateral grade 2 OA). No adverse effects were observed on physical/orthopedic examination or reported by owners, and no clinically significant laboratory findings were noted related to the IA injection of 117mSn at regularly scheduled re-evaluations.

Table 1 Demographic Characteristics for 21 Dogs with Naturally Occurring Elbow OA Based on 117mSn Dose Group

Both PSS and PIS significantly improved at all time-points except for the 10-month (PSS) and the 10- and 11-month (PIS) (Table 2) scores compared to baseline. No significant differences were noted in QoL scores.

Table 2 Canine Brief Pain Inventory (CBPI) Scores for 21 Dogs with Elbow OA at Pretreatment and at Each Time-Point Post Treatment. Values are Presented as Median (Range)

In the HD group for elbow extension there was a trend in improvement (approaching significance) in the treated leg at 6, and 9 months, respectively, compared to baseline (Table 3). Elbow extension also increased in the untreated leg at 9-month in the HD group and at 6-month in the MD group. In 1 dog from the MD-group, baseline force-plate data for the treated leg was missing and this dog died secondary to GDV after its 3-month evaluation. In 1 dog from the LD-group, five successful repeatable trials during force-plate data collection could not be obtained at the baseline evaluation. These 2 dogs were not included in the force plate data analysis. This resulted in a total of 19 dogs for force plate data analysis. The mean peak vertical force improved in the treated leg in the HD group by 5.4%, 12.0%, 10.1% and 12.3% at 1, 3, 6, and 9 months, respectively, compared to baseline. This increase was statistically significant at the 3- and 9-month time points. The mean PVF was significantly lower (by 9%) in the untreated leg at the12-month time point compared to baseline (Table 4). In the HD group, the mean BW-D% for the treated leg improved compared to baseline and this improvement approached significance at 3- and 9-month time points (Table 4).

Table 3 Evolution of Elbow Extension, Flexion and Range of Motion from Baseline to Month-12 in Treated and Untreated Elbows in 21 Dogs with Elbow OA for All Three 117mSn Dose Groups. The Means of Three Values for Elbow Extension and Flexion Were Recorded Bilaterally. The Data is Summarized as Mean Standard Deviation (SD)

Table 4 Evolution of PVF and BW-D% from Baseline to Month-12 in Nineteen Dogs with Elbow OA for All Three 117Sn Dose Groups. The Data is Summarized as Mean Standard Deviation (SD)

Based on the criteria mentioned above for a positive response, 17 of 19 dogs (89.5%) had a positive response (Table 5). There was no significant difference between the three dose groups for positive responses.

Table 5 Dog Number, 117mSn Dose Group, and Treatment Outcome in 19 Dogs Undergoing Force-Plate Analysis

The radiographic OA scores significantly increased both in treated elbows and untreated elbows at 12-month recheck compared to pretreatment scores (Table 6). There was no significant difference in OA score change from baseline between treated and untreated elbows at the time of the 12-month evaluation for all dose groups (Table 6).

Table 6 Radiographic OA Scores for Treated and Untreated Elbows for Study Dogs with Elbow OA at Pretreatment and at 12-Month Recheck. The 12-Month Radiographs Were Available for 18 Dogs

The ability to use RSO as a localized treatment with lasting results and no systemic adverse effects could make it a valuable therapeutic option for veterinary patients with OA. In our study, the use of IA 117mSn in dogs with elbow OA resulted in clinically relevant beneficial effects lasting for up to 9 months-based on force plate data with statistically significant improvement at 3 and 9 months post-injection and trending towards improvement (approaching significance) at 6 months post injection. The beneficial effects lasted for 1-year post injection based on CBPI data. This duration of RSO response is similar to what has been reported in humans where the response can last for a few months to several years.17

Radiosynoviorthesis (RSO) has been successfully used in human medicine for more than 60 years in many countries, particularly in Europe where it was first described and where its use conforms to guidelines published by the European Association of Nuclear Medicine.22,3739 RSO has been an accepted outpatient therapy for treatment of early stage chronic synovitis in rheumatoid arthritis, psoriatic arthritis, hemophilic arthritis and OA patients for decades.3941 Current standards in human clinical practice generally take a conservative approach by recommending initial treatment with front-line therapies including systemic NSAIDs, glucocorticoids, and local joint therapies such as corticosteroid and hyaluronic acid injections prior to RSO.37 However, in patients that either respond poorly or have adverse side effects following these traditional therapies, RSO is a useful option that should now be considered in veterinary medicine. Traditional veterinary arthritis therapies when successful are oftentimes less costly than RSO using homogeneous tin colloid (117mSn). It can become costly when these initial traditional therapies cannot successfully manage elbow osteoarthritis and alternatives such as stem cell or platelet-rich plasma therapies are considered. The treatment in our study was evaluated specifically to manage canine arthritic elbows because oftentimes traditional veterinary arthritis therapies are not successful in dogs with elbow OA.1,2,4,912

The patients in this study were treated with homogeneous tin colloid (117mSn) containing microparticles (diameter 1.5 to 20.0 microns) of the radioisotope tin 117m (117mSn). These microparticles when injected into a joint are engulfed by intra-articular macrophages, which are killed by apoptosis due to the tin 117m conversion electron (CE) radiation.41 Admittedly, we had limited short-term evaluation for any adverse effects related to 117mSn injection. The absence of any adverse effects in the present study and in a previous experimental study, is most likely due to unique characteristics of 117mSn.23,25,26 Tin 117m emits abundant conversion electrons, low-energy particles with a short, non-diminishing penetration range of approximately 300m in tissue. Other radionuclides that emit beta particles result in variable tissue penetration and can result in damaging irradiation of adjacent non-target tissues.20 117mSn has a life of nearly 14 days, providing an ideal duration of effect spanning several lives to achieve therapeutic results and to enable short-term stability during storage and handling. Studies in rats and colony bred dogs have confirmed the safety of structures within the joint (cartilage, bone) and adnexal structures following IA injection with homogeneous tin colloid (117mSn).23,26 In addition to conversion electrons, 117mSn emits radiation, which is non-therapeutic but readily detectable by scintigraphy. In humans, the risk of infection after IA RSO is very small (1:35,000) and septic arthritis is uncommon.20 Similarly, none of the dogs in our study developed any infection related to 117mSn IA injection. Overall, in humans RSO has very low rate of adverse effects.41 Joint flare ie more pain and joint effusion due to intensification of inflammation (radiosynovitis) within 24 weeks after RSO is the most common adverse effect.20 This may be considered a natural course of the treatment due to rapid and extensive synovial necrosis when using higher energy beta-emitters. In humans, the joint flare from radiosynovitis is the main reason to consider co-injection of steroids. Routinely steroids are co-injected into large joints (shoulder, knee, and hip) because radiosynovitis is common in these joints.20 Even though canine joints are much smaller than human joint but this should be taken into consideration in dogs also in future studies involving RSO of these large joints.

Both PSS and PIS significantly improved at all time points except for PSS at 10 months and for PIS at 10 and 11 months which were not statistically significant compared to baseline, but these scores were still improved compared with baseline. A caregiver placebo effect may have played a role in improvement of CBPI as this effect has been shown to occur approximately 57% of the time for pet owners evaluating their dogs with lameness from osteoarthritis.34 In addition to this a lack to control group makes this measure less ideal compared to force plate gait analysis to determine outcome. However, it would be implausible to expect a placebo effect to persist for the 1-year duration of the study. In addition, the CBPI has been shown to allow reliable quantification of the owners assessment of the severity and impact of clinically relevant chronic pain-related behaviors with the dog in its normal environment.28,29 The QoL item (poor, fair, good, very good, excellent) is a stand-alone item and is used initially as a criterion validity assessment in the validation of the severity and interference scores.35 It takes very large changes in pain scores to elicit a change in the QoL category, which could be a potential reason why we did not see any significant improvement in this category.35 In future studies, QoL as an outcome measure should be better approached with a global assessment of change over time (ie, much worse, worse, same, better, much better).

Goniometry is an economic and simple measurement of joint angles used to objectively assess joint function.42 Mean elbow extension improved by 7 degrees at 6-month and by 10 degrees at 9-month follow-up time point in the treated elbow in the HD-group. However, mean elbow extension also increased in the untreated leg by 7 degrees at 9 months in the HD group and by 8 degrees at 6 months in the MD group. Therefore, our results indicate that there was no significant difference in this outcome measure between treated and untreated elbows.

The force-plate gait analysis is an established objective gold standard for quantification of leg function and pain in dogs with appendicular joint OA.29 It is considered to provide an accurate and unbiased assessment. However, without a placebo treatment group, we are unable to know if other external factors influenced the dogs in a way that may have resulted in improved leg function. A caregiver placebo effect as mentioned above does not exist for appropriately acquired force plate gait analysis. In addition, in a randomized, blinded, placebo-controlled crossover study where every dog received tramadol or carprofen or placebo during the study period, the authors found no change in PVF over a 10-day period in the placebo group.33 Additionally, in our study the untreated opposite leg served as a source of comparison data. The improvement noted in PVF in our study is larger than what has been previously reported.29,32,33

One of the limitations of this pilot study was a small sample size. Another limitation was the lack of a placebo or control group; however, OA is a progressive disease. The lack of any therapy for osteoarthritis would not have been acceptable for an ethical committee for running a control group for up to 1 year. While using client-owned dogs is a strength of the study, it is also a limitation. Studies of naturally occurring OA in dogs are associated with potential confounding factors, such as the potential for owner errors in study compliance and variations in the home environment. However, this is the environment in which the agent will be used and assessed by veterinarians and owners. Dogs were allowed to continue previous medical management (NSAIDs or other analgesics) during the study. It is possible that use of these medications could have biased our results. Ideally, dogs would have all been taken off of medical management and undergone a washout period before enrollment. The authors elected to allow dogs to be continued on any previous medications for multiple reasons: to avoid increasing pain should the IA injection fail to control pain, to provide pain control in the untreated leg, to allow the study to be clinically relevant, and for the study to be reflective of the general canine population with OA. Future studies might include more stringent exclusion criteria. We focused on the elbow joint for consistency; it would be interesting to know the effects of this treatment on other arthritic joints.

The safe use of any radioisotope requires documented training by veterinarians and support staff. There is a recommended licensing, treatment and post-treatment caretaker instruction process published by the US Nuclear Regulatory Commission for the safe use of 117mSn in the US.43 Unlike I-131 and Tc 99m radiation quarantine is not indicated for 117mSn as it is not excreted in any appreciable amount. Instead, 117mSn is retained within the joint and is eventually cleared by the lymphatics to the liver as microparticles of inert (nonradioactive) tin.23,25,26 However, there are gamma emissions that must be measured at 1 meter post treatment to determine the amount of interaction with a patient by household members. All household members are to monitor and follow their interactions within 3 feet (from treated joint(s) to center of torso) prescribed by written instructions for 2 weeks. For dogs in which there is an extended close association (sleeping in the same bed, sitting beneath an occupied office chair or in ones lap > 4 hrs daily) there could be a longer period of abstaining from these behaviors for up to 46 weeks following 117mSn radiosynoviorthesis.43,44 All patients can return to normal activities and interactions with anyone beyond 3 feet immediately post treatment.43,44

Clinical response to RSO is usually expected to have some lag phase that can last from weeks to months.20 In humans, the effect in the knee is seen as soon as 4 weeks.20 In the current study, improvement was noted in dogs at 1-month evaluation, similar to humans. In humans, the full therapeutic impact of RSO can take 46 months and duration of response depends on already existing joint damage.20 Similarly in our study full therapeutic effect as shown by significantly improved objective measurements such as PVF (and improvement in BW-D% approaching significance) was achieved at 3 months post treatment. Advanced-stage OA and pre-existing joint damage are negative outcome predictors of RSO in humans.45 Thus, the best responders would be patients with limited joint damage or the patients with large amounts of inflammation/effusion rather than advanced degenerative changes. Our study population included dogs with mild to moderate (grade 1 to 2) degree of OA and, as in human studies, a good clinical response was noted. Future studies in dogs with advanced OA are indicated to evaluate the effects of IA 117mSn in those cases.

In conclusion, IA injection of 117mSn improved CBPI scores and increased weight-bearing associated with elbow OA, providing preliminary evidence that 17mSn is beneficial in the management of elbow OA in dogs. This localized therapy with protracted results can be considered as an adjunct to other nonsurgical or surgical treatments or as a stand-alone therapy for elbow OA and might be useful for patients that cannot tolerate traditional OA medications such as NSAIDs. Although 17mSn appeared to be effective for the treatment of elbow OA, this pilot study has inherent limitations; therefore, future studies with larger numbers of dogs and with placebo group are needed.

The study protocol was approved by Institutional Animal Care and Use Committee (Protocol #16-008) and the Radiation Safety Office of the Louisiana State University (site A) and Medical Director Board and Radiation Safety Committee of Gulf Coast Veterinary Specialists (site B). All dogs were client-owned and written consent was obtained before study enrollment. This study adhered to veterinary care best practice guidelines.

The authors thank the LSU and GCVS force-plate teams and Sarah Keeton, PhD for her invaluable assistance in managing all data records.

Dr Andrews reports grants from Exubrion Therapeutics, during the conduct of the study. Dr Lattimer reports grants from Exubrion Therapeutics, during the conduct of the study. Dr Lattimer, however, had a career long interest in therapeutics of this type and has participated in privately and publicly funded work that employs radiopharmaceuticals and devices. None of this work has been done in the last several years except that associated with the parent project to this work. The study was funded by Exubrion Therapeutics, Buford, GA, USA. Drs. Aulakh, Hudson, and Fabiani are advisory board members for Exubrion Therapeutics and receive a small honorarium for consultation. All authors declare no other conflicts of interest related to this report.

1. Krotscheck U, Bottcher P. Surgical diseases of the elbow. In: Veterinary Surgery: Small Animal. Vol. 1. 2nd ed. St. Louis, MS: Elsevier; 2018.

2. Coppieters E, Gielen I, Verhoeven G, et al. Erosion of the medial compartment of the canine elbow: occurrence, diagnosis and currently available treatment options. Vet Comp Orthop Traumatol. 2015;28:918. doi:10.3415/VCOT-13-12-0147

3. Sanderson RO, Beata C, Flipo RM, et al. Systematic review of the management of canine osteoarthritis. Vet Rec. 2009;164:418424. doi:10.1136/vr.164.14.418

4. Innes JF, Clayton J, Lascelles BD. Review of the safety and efficacy of long-term NSAID use in the treatment of canine osteoarthritis. Vet Rec. 2010;166:226230. doi:10.1136/vr.c97

5. Burton NJ, Owen MR, Kirk LS, et al. Conservative versus arthroscopic management for medial coronoid process disease in dogs: a prospective gait evaluation. Vet Surg. 2011;40:972980. doi:10.1111/j.1532-950X.2011.00900.x

6. Dempsey LM, Maddox TW, Comerford EJ, et al. A comparison of owner-assessed long-term outcome of arthroscopic intervention versus conservative managemento f dogs with medial coronoid process disease. Vet Comp Orthop Traumatol. 2019;32:19. doi:10.1055/s-0038-1676293

7. Dejardin L, Guillou R. Total elbow replacement in dogs. In: Johnston S, Tobias K, editors. Veterinary Surgery: Small Animal. Vol. 1. 2nd ed. St. Louis, MS: Elsevier;2018:885896

8. Conzemius MG, Aper RL, Corti LB. Short-term outcome after total elbow arthroplasty in dogs with severe, naturally occurring osteoarthritis. Vet Surg. 2003;32:545552. doi:10.1111/j.1532-950X.2003.00545.x

9. Franklin SP, Cook JL. Prospective trial of autologous conditioned plasma versus hyaluronan plus corticosteroid for elbow osteoarthritis in dogs. Can Vet J. 2013;54:881884.

10. Guercio A, Di Marco P, Casella S, et al. Production of canine mesenchymal stem cells from adipose tissue and their application in dogs with chronic osteoarthritis of the humeroradial joints. Cell Biol Int. 2012;36:189194. doi:10.1042/CBI20110304

11. Wanstrath AW, Hettlich BF, Su L, et al. Evaluation of a single intra-articular injection of autologous protein solution for treatment of osteoarthritis in a canine population. Vet Surg. 2016;45:764774. doi:10.1111/vsu.12512

12. Sherwood JM, Roush JK, Armbrust LJ, et al. Prospective evaluation of intra-articular dextrose prolotherapy for treatment of osteoarthritis in dogs. J Am Anim Hosp Assoc. 2017;53:135142. doi:10.5326/JAAHA-MS-6508

13. Quinn R, Preston C. Arthroscopic assessment of osteochondrosis of the medial humeral condyle treated with debridement and sliding humeral osteotomy. Vet Surg. 2014;43:814818. doi:10.1111/j.1532-950X.2014.12260.x

14. Sellam J, Berenbaum F. The role of synovitis in pathophysiology and clinical symptoms of osteoarthritis. Nat Rev Rheumatol. 2010;6:625635. doi:10.1038/nrrheum.2010.159

15. de Lange-brokaar BJ, Ioan-Facsinay A, van Osch GJ, et al. Synovial inflammation, immune cells and their cytokines in osteoarthritis: a review. Osteoarthritis Cartilage. 2012;20:14841499. doi:10.1016/j.joca.2012.08.027

16. McDougall JJ. Arthritis and pain. Neurogenic origin of joint pain. Arthritis Res Ther. 2006;8:220. doi:10.1186/ar2069

17. Kresnik E, Mikosch P, Gallowitsch HJ, et al. Clinical outcome of radiosynoviorthesis: a meta-analysis including 2190 treated joints. Nucl Med Commun. 2002;23:683688. doi:10.1097/00006231-200207000-00013

18. Kapatkin AS, Nordquist B, Garcia TC, et al. Effect of single dose radiation therapy on weight-bearing lameness in dogs with elbow osteoarthritis. Vet Comp Orthop Traumatol. 2016;29:338343. doi:10.3415/VCOT-15-11-0183

19. Ishii K, Inaba Y, Mochida Y, et al. Good long-term outcome of synovectomy in advanced stages of the rheumatoid elbow. Acta Orthop. 2012;83:374378. doi:10.3109/17453674.2012.702391

20. Chojnowski MM, Felis-Giemza A, Kobylecka M. Radionuclide synovectomy - essentials for rheumatologists. Reumatologia. 2016;3:108116. doi:10.5114/reum.2016.61210

21. Szentesi M, Nagy Z, Gher P, et al. A prospective observational study on the long-term results of. Eur J Nucl Med Mol Imaging. 2019;46:16331641. doi:10.1007/s00259-019-04350-3

22. Zuderman L, Liepe K, Zphel K, et al. Radiosynoviorthesis (RSO): influencing factors and therapy monitoring. Ann Nucl Med. 2008;22:735741. doi:10.1007/s12149-008-0167-7

23. Lattimer JC, Selting KA, Lunceford JM, et al. Intraarticular injection of a Tin-117 m radiosynoviorthesis agent in normal canine elbows causes no adverse effects. Vet Radiol Ultrasound. 2019;60:567574. doi:10.1111/vru.12757

24. Polyak A, Nagy LN, Drotar E, et al. Lu-177-labeled zirconia particles for radiation synovectomy. Cancer Biother Radiopharm. 2015;30:433438. doi:10.1089/cbr.2015.1881

25. Doerr C, Stevenson NR, Gonzales G. Homogeneous Sn-117m col- loid radiosynovectomy results in rat models of joint disease [abstract]. J Nucl Med. 2015;1243.

26. Doerr C, Bendele A, Simon J. Validation of the use of homoge- neous Sn-117m colloid radiosynoviorthesis in a GLP osteoarthritis rat model [abstract]. J Nucl Med. 2016;323.

27. Ondreka N, Tellhelm B. Explanation of grading according to IEWG and discussion of cases, Proceedings, 31th annual meeting of the International Elbow Working Group (IEWG), Verona, Italy; 2017. Available from: http://www.vet-iewg.org/wp-content/uploads/2017/03/IEWG-proceedings2016.pdf. Accessed May 5, 2021.

28. Brown DC, Boston RC, Coyne JC, et al. Ability of the canine brief pain inventory to detect response to treatment in dogs with osteoarthritis. J Am Vet Med Assoc. 2008;233:12781283. doi:10.2460/javma.233.8.1278

29. Brown DC, Boston RC, Farrar JT. Comparison of force plate gait analysis and owner assessment of pain using the Canine Brief Pain Inventory in dogs with osteoarthritis. J Vet Intern Med. 2013;27:2230. doi:10.1111/jvim.12004

30. Roush JK, Cross AR, Renberg WC, et al. Evaluation of the effects of dietary supplementation with fish oil omega-3 fatty acids on weight bearing in dogs with osteoarthritis. J Am Vet Med Assoc. 2010;236:6773. doi:10.2460/javma.236.1.67

31. Mirza MH, Bommala P, Richbourg HA, Rademacher N, Kearney MT, Lopez MJ. Gait changes vary among horses with naturally occurring osteoarthritis following intra-articular administration of autologous platelet-rich plasma. Front Veterin Sci. 2016;3. doi:10.3389/fvets.2016.00029

32. Vijarnsorn M, Kwananocha I, Kashemsant N, et al. The effectiveness of marine based fatty acid compound (PCSO-524) and firocoxib in the treatment of canine osteoarthritis. BMC Vet Res. 2019;15:349. doi:10.1186/s12917-019-2110-7

33. Budsberg SC, Torres BT, Kleine SA, et al. Lack of effectiveness of tramadol hydrochloride for the treatment of pain and joint dysfunction in dogs with chronic osteoarthritis. J Am Vet Med Assoc. 2018;252:427432. doi:10.2460/javma.252.4.427

34. Conzemius MG, Evans RB. Caregiver placebo effect for dogs with lameness from osteoarthritis. J Am Vet Med Assoc. 2012;241:13141319. doi:10.2460/javma.241.10.1314

35. Brown DC. The canine brief pain inventory; 2021. Available from: http://www.caninebpi.com. Accessed May 5, 2021.

36. Jaegger G, Marcellin-Little DJ, Levine D. Reliability of goniometry in labrador retrievers. Am J Vet Res. 2002;63:979986. doi:10.2460/ajvr.2002.63.979

37. Kampen WU, Voth M, Pinkert J, et al. Therapeutic status of radiosynoviorthesis of the knee with yttrium [90Y] colloid in rheumatoid arthritis and related indications. Rheumatology (Oxford). 2007;46:1624. doi:10.1093/rheumatology/kel352

38. Karavida N, Notopoulos A. Radiation Synovectomy: an effective alternative treatment for inflamed small joints. Hippokratia. 2010;14:2227.

39. Klett R, Lange U, Haas H, et al. Radiosynoviorthesis of medium-sized joints with rhenium-186-sulphide colloid: a review of the literature. Rheumatology (Oxford). 2007;46:15311537. doi:10.1093/rheumatology/kem155

40. Schneider P, Farahati J, Reiners C. Radiosynovectomy in rheumatology, orthopedics, and hemophilia. J Nucl Med. 2005;46(Suppl 1):48S54S.

41. Knut L. Radiosynovectomy in the therapeutic management of arthritis. World J Nucl Med. 2015;14:1015. doi:10.4103/1450-1147.150509

42. Lascelles BD, Dong YH, Marcellin-Little DJ, et al. Relationship of orthopedic examination, goniometric measurements, and radiographic signs of degenerative joint disease in cats. BMC Vet Res. 2012;8:10. doi:10.1186/1746-6148-8-10

43. Procedure for use of Synovetin OA [Note: licensee to modify to match specific facility operations]; 2021. Available from: https://www.nrc.gov/docs/ML2028/ML20282A514.pdf. Accessed May 5, 2021.

44. Wendt RE, Selting KA, Lattimer JC, et al. Radiation safety considerations in the treatment of canine skeletal conditions using 153Sm, 90Y, and 117mSn. Health Phys. 2020;118:702710. doi:10.1097/HP.0000000000001222

45. Liepe K. Efficacy of radiosynovectomy in rheumatoid arthritis. Rheumatol Int. 2012;32:32193224. doi:10.1007/s00296-011-2143-0

Read more here:
Clinical evaluation of intra-articular injection of Tin-117m | VMRR - Dove Medical Press

Novel Strategies for Disrupting Cancer-Cell Functions with Mitochondri | IJN – Dove Medical Press

Introduction

Mitochondria are multifunctional organelles found in most eukaryotic cells that form a comprehensive intracellular network controlled by a proper balance among fusion, fission, biogenesis, and mitophagy.1,2 These organelles are acknowledged for storing and harvesting energy, released by oxidative phosphorylation. Mitochondria are maternally inherited organelles, and most of their proteins are nuclear-encoded. However, these organelles retain a small DNA genome of about 16 kb mitochondrial DNA (mtDNA), which encodes rRNAs and tRNAs and proteins required for respiration. Eukaryotic cells generally contain hundreds of mitochondria with their mtDNA either free of mutations (wild type), mutated mtDNA, or a mixed population known as heteroplasmy.3

These organelles are significant junctions for intracellular interactions with other organelles. They interact with nuclei, the endoplasmic reticulum (ER), and peroxisomes through membrane contact, vesicle transport, and signal transduction to regulate biosynthesis, energy metabolism, immunoresponse, and cell turnover. However, when this normal communication among mitochondria and other organelles fails or when mitochondria are dysfunctional, it most often induces different diseases and especially tumorigenesis.4 Mitochondrial diseases are well known to be devastating, and can affect many organs like muscles, the heart, and the nervous system. These diseases can either be of maternal inheritance or by nuclear inheritance of loss-of-function mutations in some essential mitochondrial genes.5

Most cancers retain mitochondrial functions, including respiration, and even some tumors show enhanced oxidative phosphorylation.6 The energy-harvesting functions of mitochondria are at least as important for cancer progression as ATP generation.7 Cancer cells survive easily during hypoxic milieus by recycling NADH to NAD+ through plasma-membrane electron transport and lactate dehydrogenase to continue glycolytic ATP synthesis.810 The precise role of mitochondria during different phases of cancer has been recently reviewed. This review discusses the altered functions of mitochondria during cancer, changes in mitochondrial dynamics, and targeting mitochondria with specific mitochondriophilic biomolecules at multiple sites during cancer progression. In addition, therapeutic strategies, including the use of novel NPs (NPs) conjugated with mitochondriophilic biomolecules, to combat cancer progression are discussed.

The fundamental role of mitochondria as eukaryotic cell organelles was verified over a century ago.11 During a healthy state, these organelles regulate some vital cellular functions through the tricarboxylic acid cycle (TCA), oxidative phosphorylation, fatty-acid oxidation, and calcium homeostasis. Mitochondria also regulate heme biosynthesis, ketogenesis, urea cycle, gluconeogenesis, and ironsulfur cluster formation.12 These organelles possess their own DNA (mtDNA), which controls some important functions and can get mutated or partially deleted. Mitochondria are enclosed by a lipid-bilayer double-membrane system inner mitochondrial membrane (IMM) and outer mitochondrial membrane (OMM) which are separated by intermembrane space. Much of the inner space of the mitochondrial matrix is occupied by cristae, which are formed by extensive IMM folds. Each mitochondrial component plays specific roles that controls many of the overall cellular activities.13

There are several proteins and enzymes that regulate mitochondrial function, fission, fusion, interaction, and cross talk with other organelles. Mitochondrial fission is promoted by mitochondrial fission 1 protein (FIS1) and mitochondrial fission factor (MFF) present in OMM. Mitochondrial fission controls important functions like autophagy, apoptosis, and cell death.14 On the other hand, mitochondrial fusion is achieved by the outer-membrane fusion proteins, Mfn1 and Mfn2 and the inner-membrane fusion protein OPAC1.15 Mitochondrial fusion controls mitochondrial membrane potential (MMP), cell growth, and electron-transport chain (ETC) functions.16

For the normal functioning of a cell, proper crosstalk between mitochondria and other organelles is very important. Any impairment in this connection may lead to alteration of the cellular environment, which can activate certain oncogenes and mitochondrial genome mutation.4 Precise control exists between the nucleus and mitochondria for the stability of these organelles. Any cross-talk dysfunction between these two organelles can lead to DNA damage in both, abnormal activation of growth factors, Ca2+ overload, and metabolic disorders, which are prominent hallmarks of cancer.17,18

An active and strong interaction exists between the ER and mitochondria for the coordination of important cellular biological functions like Ca2+ signaling, ER stress response, regulation of apoptosis, phospholipid biosynthesis, and translocation from the ER to mitochondria. In addition, proper interaction between mitochondria and peroxisomes is very important for reactive oxygen species (ROS) and lipid balance.

In addition to the regulation of biosynthetic precursor balance, energy production, and cytosolic Ca2+ levels, mitochondria can modulate redox status and ROS generation and initiate apoptosis through the activation of mtPTP.19 Mitochondria are the major sources of ROS (ie, hydroxyl radicals, hydrogen peroxide, and superoxide anions), and these reflect the imbalance between antioxidant defense and ROS production. The most pronounced ROS-depended damage includes vascular tonus impairment and platelet adhesion and alterations in gene transcription and metabolism.20 This usually occurs due to hydrogen peroxide, which besides acting as intracellular messenger, controls autophagy, senescence, and apoptosis.20 These processes are closely related to one another, the relationship appears rather complex, and the boundaries are difficult to delineate.

In some circumstances, autophagy can lead to cell death while apoptosis is inhibited, so acting as a backup mechanism for death progression.21 During some failure conditions, to activate autophagy as a cell-survival mechanism during nutrient starvation, it leads to cell death by apoptosis with the involvement of BAX/BAK proteins. These are BCL2-family proteins that are required for caspase activation or mitochondrial outer-membrane permeabilization,22 which is the point of no return in different forms of apoptotic cell death, as it initiates proapoptotic, enzyme-mediated proteolytic cascades and damages mitochondrial functions.23 The cross-regulation among autophagy, senescence, and apoptosis is a complex phenomenon and still far from being understood. The role played by mitochondria in the onset of these process is briefly discussed in many sections of this article.

Mitochondria may play a significant role in the development of cancer phenotypes through at least five mechanisms. First, it has been commonly demonstrated that DNA mutations affect mitochondria and lead to many diseases, mainly due to alterations in ETC subunits.24 Second, ROS are mainly produced from mitochondria (mtROS), which mediates oxidative stress (OS) and is the principal cause of cancer generation and progression.25 mtROS can be generated either in the ETC or during the TCA cycle.26 Enhanced levels of ROS are usually found in cancer cells, due to altered antioxidant potential.27 Third, the mitochondria have a direct role in cell-death regulation, including but not limited to necrosis and apoptosis.28 For the induction of apoptosis, BCL2 proteins interact with mitochondria through binding with voltage-dependent anion channels (VDACs) to enhance the release of cytochrome c (cyt c).29 Mitochondria also control necroptosis, which is a regulated form of necrosis that requires mitochondrial permeability transition and mtROS.30 Fourth, metabolic reprogramming also affects gene mutations encoding enzymes of the TCA cycle, which can promote cancer transformation.31 Fifth, telomerase reverse transcriptase shuttles from the nucleus to mitochondria during enhanced oxidative stress. It is used to preserve mitochondrial functions, decrease oxidative stress, and protect mtDNA and nuclear DNA from oxidative damage to avoid apoptosis.32

Though cancer cells are highly diverse, all display some stereotypical traits or hallmarks, and mitochondria play an important role in such hallmarks.33 Mitochondria play a significant role in initiation of cancer, which can be due to dysregulated signaling, mtDNA mutations, oxidative stress, metabolism, bioenergetics, fission and fusion dynamics, or biogenesis and turnover. The distorted bioenergetics within cancer cells help them meet the required energy demands by ATP generation through the ETC.

During acute myeloid leukemia (AML), altered mitochondrial metabolism occurs, due to mutations in isocitrate dehydrogenase (IDH). An isoform of IDH, IDH3 catalyses the formation of -ketoglutarate from isocitrate in the TCA cycle. In parallel, IDH1 and IDH2 catalyse the same reaction, but outside the TCA cycle.34 Aberrant mitochondrial metabolism during AML has opened the possibility of using several drug nanoformulations to rectify mutations. Various studies on in vivo and in vitro AML models have demonstrated the benefits of using mitochondria-targeted mitocans in combination therapies. In this regard, arsenic trioxide has been found to be a potential drug at the clinical level for acute promyelocytic leukemia patients. The use of arsenic trioxide has raised hopes of discovery in more aberrant mitochondriatargeted drug nanoformulations as a therapeutic strategy in treating AML.

The transformed mitochondrial metabolism supports the rapidly dividing cancer cells by providing building blocks. Mitochondria show good flexibility in supporting cancer-cell survival during adverse conditions, such as starvation and chemotherapy.9 Therefore, understanding the mechanisms of mitochondrial function during normal and cancerous states will be crucial to develop next-generation cancer therapeutics. Some altered mitochondrial functions during cancerous state are outlined in the following sections.

Recent experimental data on mitochondria have overturned the belief that cancer cells quench their bioenergetic and anabolic requirements predominantly through aerobic glycolysis. It is now well acknowledged that mitochondrial metabolism plays a crucial role in cancer development and progression. These organelles play an important role in different steps of oncogenesis and response to treatment.35 This is further supported by the findings that different cancer cells depend primarily on oxidative phosphorylation for promotion of their tumorigenic potential.6,36 These observations are supported further by analysis of glioma cells, which are rescued by pyruvate and lactate, oxidative substrates produced during low-glucose conditions.37 In parallel, it has been observed that in MCF7 cells, oxidative metabolism produces 80% of ATP and increased glucose consumption is not necessarily linked with increased glycolysis.38 Furthermore, it has been found that some drug-resistant tumor cells are subjected to mitochondrial oxidative phosphorylation for their survival. The treatment of these cells with ETC complex I inhibitors prolongs survival and tumor burden in murine xenograft models.39

Mitochondria are indispensable for tumor cells, as they provide the major share of energy and process metabolic intermediates. The TCA cycle provides some major metabolic intermediates and building blocks for anabolism. Krebs cycle constitutes an epicenter in cellular metabolism, as numerous substrates can feed into it. As such altered TCA-cycle regulation and its continued feedback with dysregulated oxidative phosphorylation is crucial for the progression of cancer.

Several types of human cancers show that TCA cycle enzymes are often dysregulated and frequently mutated. Some of the most vulnerable enzymes are isocitrate dehydrogenase, aconitate hydratase, succinate dehydrogenase (SDH), fumarate hydratase (FH), and the -ketodehydrogenase complex.40,41 In addition, some metabolites of the TCA cycle control mitochondrial chromatin modifications and post-translational modification in proteins. The role of Krebs cycle rewiring during hepatocellular carcinoma has been summarized by Todisco et al, as they found dysregulation of glutamine metabolism, citratepyruvate, and malateaspartate shuttles. A link has also been observed between the transcription factor NFBHIF1 and TCA cycle reprogramming.42

Significant alterations have been observed in the abundance of some enzymes linked with aerobic glycolysis and Krebs cycle in gliomata of IDH1-mutant types.43 Enzymes involved in the metabolism of lactate, glutamate, and -ketoglutarate are also significantly enhanced in such mutant gliomata. In addition, increased expression of SLC4AG, a bicarbonate transporter has been observed in such gliomata. This suggests a mechanisms that preventing the glycolysis mediated intracellular acidification is active in such cells. This special type of metabolic rewiring preserves the activity of TCA cycle in IDH1-mutant glioma types.43

Cancer cells display metabolic aberrations accompanied by accumulation of ROS, which is the main cause of biomolecular damage, and if it exceeds the limit leads to cell death.44 The ETC releases electrons that are captured by O2 to generate O2, which leads to the formation of ROS.45 These entities lead to DNA damage and bind with intracellular and surface receptors and signaling molecules. All these changes lead to angiogenesis, proliferation, and apoptosis, significant aspects of cancer progression.46,47 The extensive DNA damage by ROS can promote carcinogenesis and the malignant transformation of normal cells. Excessive production of ROS also leads to Cyt. c release and can trigger programmed cell death.48 Enhanced levels of ROS pose a severe threat to mitochondria and even cell viability.

Normal cells exhibits continued mitochondrial fission and fusion cycles to maintain proper function. Fission- and fusion-machinery proteins also regulate intrinsic apoptotic pathways.49 In cancer cells, the genes responsible for mitochondrial dynamics regulation are amplified and inhibition of DRP1, a fission promoting GTPase known to induce apoptosis.50 DRP1 knockout in pancreatic cancer cells has been witnessed with diminished oxygen consumption and minimal ATP production, which results in reduced growth.51 In comparison to normal cells, lung adenocarcinoma has been reported to express lower levels of Mfn2 and higher levels of DRP1. Different phases of the cell cycle are also controlled by DRP1 dysregulation, which helps to maintain cell proliferation. DRP1 also inhibits p53 and promotes progression of the cell cycle.52 DRP1 expression has been found to be in phase with cell-cycle gene expression in ovarian cancer cells, as 55% of these genes regulate mitotic transition.53 Forced inhibition of DRP1 in these cells causes replication stress and delayed G2M transition. This replication stress leads to hyperfused mitochondrial structures and improper cyclin E expression during the G2 phase.54 In addition to this, silencing of DRP1 in breast cancer cells leads to suppressed metastatic abilities.55 Furthermore, inhibition of upregulated expression of DRP1 in hypoxic glioblastoma U251 cells attenuates hypoxia-induced mitochondrial migration and fission. All these findings support the view that DRP1 can be a potential therapeutic target in cancer cells.56 In addition, proteasomal degradation of Mfn2 induced by chemotherapy leads to mitochondrial fragmentation, which results in apoptotic cell death.57,58

In addition to mitochondrial aberrations in different cancers, high levels of mtDNA mutations have been reported in several cases.59 The different mtDNA mutations in diverse cancers include deletion, inversion, point mutation, and variation in copy number. These mutations potentially arise from the clonal expansion of cells containing mtDNA mutations. mtDNA mutations have been reported in a large percentage of lung cancer, colorectal cancer, head and neck cancer, pancreatic cancer, urinary bladder cancer, ovarian carcinoma, gastric cancer, breast cancer, and several other tumors.6066 Whether the enhanced frequency of mutated mtDNA in cancer cells is an outcome of their uncontrolled division or whether mtDNA mutations provide a selective advantage to these transformed cells that contributes to cancer initiation and progression remains an important open question.67

Some recent discoveries have shown intergenomic cross talk between mitochondria and the nucleus and the role of mtDNA variation in disturbing this signaling and thus indirectly targeting nuclear genes involved in tumerogenic and invasive phenotypes. Therefore, mitochondrial dysregulation is currently regarded as an important hallmark of carcinogenesis and a promising target for antitumor therapy.68 Moreover, the advancement of mtDNA editing tools is expected to improve strategies to characterize, track, and repair oncogenic mitochondria, which will further boost the understanding of mitochondrial epigenetics in cancer and therapeutic strategies.

Heme (protoporphyrin IX), an iron-containing molecule, is synthesized by human cells at the basal level.69 Heme plays a significant role in mitochondrial respiratory-chain complexes and different enzymes and proteins involved in oxygen metabolism like cytochromes, peroxidase, and catalase. Different types of cancers have been reported with elevated heme levels, and this elevation may contribute to the maintenance and proliferation of cancer.70 Oxygen consumption and heme biosynthesis are significantly intensified in lung cancer cells. In addition, protein levels in heme synthesis and uptake are increased in lung cancer. It has been found that the inhibition of heme and mitochondrial functions suppresses the cancer-cell proliferation and migration.70,71 Furthermore, some epidemiological studies have suggested that increased heme intake via red meat is associated with greater risks of breast, lung, pancreatic, oesophageal, and colorectal cancer. A study based on almost 500,000 individuals revealed that the consumption of processed meat leads to a 16% increased risk of lung cancer. Important sites of altered mitochondrial metabolism in cancer as potential targets for therapy are shown in Figure 1.

Figure 1 Some important locations of mitochondria that can be potential targets of anticancer-drug nanoformulations. (A) Mitochondria in normal and in cancer cells. (B) Highly metabolically active or hypoxic cancer cells generate superoxide (O2), which is immediately dismutated to H2O2. (C) in cancer cells, the TCA cycle produces reducing equivalents to fuel the ETC (green arrows), and also generates intermediates necessary for cell proliferation (red arrows). The most important anaplerotic reaction produces oxaloacetate directly from pyruvate (purple arrow). (D) Mitochondrial DNA (mtDNA) variations, including single-nucleotide polymorphisms (SNPs), maternally inherited haplotypes, and deletions, have been studied for their associations with cancer.

Novel anticancer drugs have been synthesized that can selectively disrupt cancerous mitochondria at different function targets by inhibiting glycolysis, disrupting the ETC and oxidative phosphorylation and depolarizing membrane potential. Here, we elucidate different locations of mitochondria in cancerous cells that can be novel targets to hit these types of cells.

Appropriate functioning of the ETC is very important to support oxidative phosphorylation and ATP synthesis, essential for tumorigenesis. Several ETC inhibitors like tamoxifen, -tocopheryl succinate, metformin, and 3-bromopyruvate have been used to disrupt the proper functioning of ETC respiratory complexes. These inhibitors lead to the induction of enhanced ROS generation and ultimately kill some cancerous cells.72 Proper use of these drugs specific to mitochondria of cancerous cells is a novel approach of drug targeting and requires deeper investigations for future cancer therapy.

Some novel mitochondria-targeted therapeutic agents like MitoTam, a derivative of tamoxifen, have been found to inhibit ETC complex I and lead to increased ROS synthesis. This drug has been used in breast cancer cells to induce their death.73 In parallel, another mitochondria-specific drug MitoVes, an analogue of vitamin E succinate inhibits ETC complex II and minimizes tumor growth by triggering apoptotic cell death in colorectal, breast, and lung cancers.74 In addition, several signaling pathways and ETC complex I have been targeted by ME44, which induces cell death by interfering with mitochondrial permeability in colorectal cancer.75 Mitochondria were further targeted by ME143 and ME344, which significantly inhibit oxidation of NADH by complex I, thus preventing electron flux through other oxidative phosphorylation complexes. ROS are generated by ME344-mediated inhibition of complex I, thus leading to BAX translocation to the OMM. This translocation leads to mitochondrial permeability transition, which results in the discharge of proapoptotic molecules.76

As the TCA cycle is the bioenergetic hub of metabolism and redox-state balance, it also serves as an important location of biosynthesis of different compounds. This hub is considered a novel location for different therapeutic strategies for the prevention of cancer. It involves mutations of isocitrate dehydrogenase genes, which have been reported in cancers like AML and glioblastoma.41,77 Novel therapeutic agents against these mutated gene products are now being engineered for the treatment of AML and other cancers.78 Some mutations have also been reported in FH and SDH in association with certain cancers, and any loss of these enzymes increases the vulnerability of a cancerous cell to a therapeutic agent.79 In addition to TCA cycle enzymes, oncogenes like HIF, MYC, RAS, and P53 are known to regulate the metabolic phenotype of tumor cells.80 As such, these additional pathways are now being explored as new therapeutic targets against cancer cells.81

Many cancer cells use glutamine as a fuel to supply essential nutrients and precursors for their constant growth. Inhibition of glutaminolysis can be an innovative therapeutic strategy for the treatment of various cancers. Some glutamine analogues (azaserine and 6-diazo-5-oxo-l-norleucine, azotomycin) have been tried as a treatment strategy, but this therapeutic protocol was not continued, as these analogues induced severe toxicity.82 These analogues can be tried again if transported specifically to cancer cells through mitochondria-targeted NPs.

Mitochondrial dynamics include morphology, distribution, fusion, and fission, which regulate different biological activities within the cell, including energy production. Most cancers show a prominent hallmark of increased fission compared to its fusion ratio.83 Some studies have targeted DRP1 with mitochondrial division inhibitor 1, a mitochondrial fission protein inhibitor, to reduce the tumorigenic activities of cancer stem cells.84 In parallel, an effective therapeutic strategy has been devised by using miR125a to inhibit Mfn2, which augments the mitochondrial fission in pancreatic tumor cells.85 The cell cycle is regulated by LATS2, which senses DNA-damage response. Overexpression of this gene activates mitochondrial fission and promotes mitochondrial stress in lung cancer cells, leading to their apoptosis. Targeting of LATS2 and its associated signaling can be an efficient therapeutic approach.86 The regulation of mitochondrial morphology through mitofusins and DRP1 is also regulated by E3 ubiquitin ligase (MARCH5). This protein is associated with breast cancer, and could serve as a potential therapeutic target.87

Cancer therapy can also be shortlisted by focusing on mitochondrial membrane transport mechanisms and associated proteins. This includes translocase of inner mitochondrial membrane 50 (TIMM50), involved in ERKP90RSK signaling-pathway regulation. It prevents E-cadherin expression, which promotes cancer proliferation in NSCLC cells, so can be an efficient therapeutic target in such cells.88 Furthermore, mitochondria-mediated apoptosis is also regulated by VDAC1, which is found at the OMM. Specific targeting of this complex may serve as a novel therapeutic approach for cancer treatment.89 Some important examples of mitochondria-specific antitumor drugs (mitocans) and treatment strategies with these are listed in Table 1.

Table 1 Mitochondrial function target sites for different mitocans and their possible treatment effects

A number of mitochondria-specific targeting ligands have been discovered that have tremendously improved therapeutic efficacy and greatly reduced the side effects of conjugated drugs. The direct targeting of these moieties to mitochondria has resulted in rapid response to the attached drugs.109 The most widely used mitochondria-targeting ligands are triphenylphosphonium (TPP), dequalinium (DQA), short peptide, rhodamine 19, and rhodamine 123, pyridinium, guanidine, (E)-4-(1H-indol-3-ylvinyl)-N-methylpyridinium iodide (F16), and 2,3-dimethylbenzothiazolium iodide. The direct conjugation of these mitochondria-specific moieties with anticancer drugs, sensors, and antioxidants by different bonds and spacers has resulted in enhanced cytotoxicity, sensing activity, and antioxidizing activity, respectively.110 Transformed and cancer-cell mitochondria display amplified transmembrane potential compared to normal cells.111 This difference has been utilized to develop mitochondria-targeting moieties that preferentially accumulate within cancer-cell mitochondria. Most mitochondria-targeting moieties are delocalized lipophilic cations, and their chemical structure is shown in Figure 2. They are also elaborated upon below in the following sections.

Figure 2 Chemical structure of some important mitochondria-targeted lipophilic cations.

TPP is a delocalized cationic lipid that readily penetrates through the mitochondrial membrane because of highly negative membrane potential. TPP is a well-known mitochondria-orienting moiety with cationic phosphorus bonded with three hydrophobic phenyl groups.112 This compound has been used significantly by conjugating with anticancer drugs like doxorubicin, porphyrin, coumarin, and chlorambucil to enhance mitochondria targeting within cancer cells.113 Accumulation of TPP is directly proportional to the negative charge of the mitochondrial membrane, and for every 60 mV negative membrane potential, TPP accumulation is increased by one order of magnitude. It has been reported that MMP is 180 mV, which can facilitate up to 1,000-fold buildup of TPP inside mitochondria.114 TPP has also been conjugated with chlorambucil (DNA-damaging anticancer agent) and used against breast cancer cell lines, resulting in an almost 12-fold reduction in IC50 compared to free drug.115 In a parallel study, vitamin E succinate has been conjugated with TPP, and this conjugate (MitoVES) presented enhanced mitochondrial accumulation.74

1,1-Decamethylene-bis-(4-aminoquinaldinium chloride) also named dequalinium (DQA) is a well-known lipophilic dication composed of two quinolinium moieties bonded with each other through an alkyl chain of ten carbons. This compound displays antiproliferative potential against different in vitro cancer cell lines and also shows in vivo antitumor properties.116 In aqueous medium, DQA molecules (single-chain bola-amphiphile) self-assemble and form vesicles known as DQAsomes.117 These vesicles are used to deliver pDNA within the mitochondria without any off-target leakage.118 In another study, DQA-conjugated, peptide-conjugated, and F16-conjugated anticancer drugs were used against different cancers.119

Mitochondria-penetrating peptides (MPPs) have repeating lipophilic and cationic residues, eg, (L-cyclohexyl alanine-D-arginine)3 (Figure 2). These peptides show mitochondrial buildup with low toxicity against human tumor cells.120 Doxorubicin has been conjugated with MPP via succinate linkage. Another examples of mitochondria-specific peptides is SzetoSchiller (SS) peptides. These tetrapeptides denote a special class of novel chemical entities that precisely target mitochondrial cardiolipin, improve the plasticity of mitochondria, and recondition bioenergetics. They are water-miscible tetrapeptides composed of Tyr-dimethyltyrosine (Dmt)-Arg-Phe-Lys residues. These peptides get selectively built up within the IMM and scavenge ROS. Further, these peptides block the opening of mitochondrial permeability transition pores, thus stopping the release of cytochrome c (cyt c).121 Different types of SS peptides have been engineered (SS1S31), and SS01 (Tyr-D-Arg-Phe-Lys-NH2) is shown in Figure 2.

The smart character of SS peptides lies in their mutual lipophilicity and positive charge, which is essential for easy passage through the cell membrane and mitochondrial membranes. To target mitochondria more specifically, a key strategy is to ensure alternate basic and aromatic amino residues. This approach has been used to design SS31 (D-Arg-Dmt-Lys-Phe-NH2), an efficient ROS scavenger through inhibiting lipid peroxidation. The safety and efficacy of SS31 led to a phase II clinical trial on microvascular and ischemiareperfusion injuries, in patients with acute myocardial infarction. This trial also involved the treatment of hypertension-mediated renal microvascular dysfunction and kidney injuries. This drug has also been used for the treatment of diabetic macular edema and heart failure.122

In addition, an amphipathic molecule, -helical D-(KLAKLAK)2, has been used for targeting the IMM, as this drug has improved anticancer potency.123 Keeping the chemistry of these drugs in mind in terms of their alternate hydrophobic and cationic nature, it has attracted to design similar MPPs. This led to the design of P11LRR, an arginine-modified amphiphilic peptide that comprises polyproline scaffolds and has a helical structure. It has been reported that accumulation of P11LRR within mitochondria is basically driven by its transmembrane potential. Its mitochondria-targeting impact is further enhanced by the amphipathic -helical structure, as this is crucial for the import of some peptide sequences up to mitochondria.124

Guanidinium and bigaunidinium moieties possess delocalized positive charges, and have been conjugated with hydrophobic porphyrins as photosensitizers and phototoxic agents to enhance mitochondrial accumulation. Guanidine and biguanidines have been reported to possess enhanced lipophilicity. These amphiphilic porphyrins have been bonded with different moieties to enhanced mitochondria targeting. These conjugates have been found to possess high membrane potential across the IMM and have been used for the treatment of cancer.125 Cellular uptake of these conjugates and their subcellular localization studies have revealed that guanidine-porphyrins are readily engulfed by cells and get accumulated in mitochondria more quickly than bigaunidine moieties. These conjugates possess enhanced mitochondria targeting and improved phototoxicity against certain cancer cells. The guanidine-porphyrin conjugates represent 1.8 fold enhanced phototoxicity than biguanidineporphyrins.126 The presence of guanidinium shows a proton-sponge effect within lysosomes and promotes lysosomal membrane rupture and escape capacity, even when conjugated with porphyrins. Metformin is a good example of biguanide, which acts as an antihyperglycemic agent and suppresses mitochondrial respiration, as it inhibits respiratory complex I.127

(E)-4-(1H-Indol-3-ylvinyl)-N-methylpyridinium iodide (F16) is a delocalized cation that accumulates within the mitochondrial matrix. The accumulation of this cation within this organelle lies in its higher MMP (m) capability. This accumulation also causes depolarization of the membrane, disrupting the integrity of mitochondria, and opens mitochondrial permeability transition pores. These events lead to cytochrome c (cyt c) release, cell arrest, and ultimately cell death.128 The antiproliferative potential of F16 has been reported in a variety of human breast cancer cell lines and mouse mammary tumors.

Unlike other apoptosis inducers, F16 acts in mitochondria at the junction of the apoptotic and necrotic pathways. This compound results in the induction of permeability transition and changes the functional integrity essential for cell survival. It has been observed that cell death in F16-treated overexpressing BCL2 clones is prevented under conditions of higher concentration of ATP maintenance to neutralize superoxide anions. This indicates that overexpressing BCL2 cells show necrotic death that coincides with F16-mediated mitochondrial dysregulation.129

Rhodamine has a mitochondria-targeting nature due to its lipophilic and cationic properties. These properties are the basis of crossing the double mitochondrial membrane ands accumulation within the negatively charged mitochondrial matrix.130,131 Rhodamine is also efficient at mitochondria targeting and damaging the ETC when bound to mitochondria. Both rhodamine 19 and rhodamine 123 have potential in targeting mitochondria.132 The mitochondria-targeting capacity of rhodamine 19 has been confirmed by substituting TPP. In brief, rhodamine 19 is a potential mitochondria-targeting cationic uncoupler, and shows its protonophorous uncoupling potential and maintains equilibration across the mitochondrial membranes in a Nernstian style. Some examples of important mitochondria-targeting moieties liganded with different drugs through specific bonds or spacers and their respective responses are listed in Table 2.

Table 2 Mitochondria-targeting moieties conjugated with various drugs through a specific bond or spacer, provoking different reactions and mediating important changes

In clinical practice, the use of single-unit nanoformulations in therapeutics and diagnostics (theranostics) is a novel approach to drug delivery.145 Theranostic NPs exhibit several advantages over the conventional systemic administration of native drugs. These include overcoming the problems of limited solubility, inactivation, biodegradation, and minimal off-target toxicity. Other benefits include extended circulation time, higher concentration at tumor site, multiple synergistic drugs, diagnostic system delivery,146 controlled drug release at tumor sites through stimulus-sensitive delivery systems, eg, pH, temperature, enzyme-sensitive nanoformulation, overcoming multidrug resistance and enhanced therapeutic efficacy. The approach of this drug-delivery system even up to the organelle level (third-level drug targeting) with the aid of different nanoformulations has revolutionized the therapeutic approach to different diseases, including cancer.

Mitochondria-related diseases can be best addressed by the novel strategy of using nanoformulations, which can also prove to be a valuable tool to overcome the current limitations of treating mitochondrial diseases. These nanoformulations can be powerful targeted drug-delivery systems to mitochondria.147 Moreover, they can drastically improve the pharmacokinetic and biodistribution properties of various therapeutic drugs. The uptake of NPs loaded with chemotherapeutic agents by mitochondria stimulates ROS generation and Cyt. c release, sequentially activates the downregulation of caspase 3/9 precursors, and ultimately induces mitochondrial permeability. These responses result in mitochondrial edema and cause substantial damage. Moreover, NPs dysregulate membrane potential and promote mitochondrial death pathways, inducing the elevation of apoptotic events within cancer cells.148

Delivery systems based on NPs must be meticulously designed with proper size, shape, charge, lipophilic surface, and specific density to achieve center-point targeting within mitochondrial locations. NPs need to have spatiotemporal control over the release of their drug payloads at different mitochondrial compartments.149 NP size impacts drastically on cellular uptake by influencing adhesion strength with cellular receptors. Optimal cellular uptake with ligand-coated NPs has been found to be met at almost 50 nm diameter.150 Similarly, the highest uptake of spherical mesoporous silica NPs by HeLa cells is at 50 nm.151 In addition, targeted AuNPs have been reported to possess the highest cellular uptake by SKBR3 cells at 4050 nm in size.152 Currently, NPs/nanoformulations are conjugated with different mitochondria-specific compounds to achieve best organelle targeting. Some common examples of NPs used against mitochondria of different cancer cell lines are presented in Figure 3.

Figure 3 (A) Schematic representation of mitochondria-targeted nanoformulations loaded with hydrophilic and hydrophobic drugs. These NPs can also be loaded with Mitochondria-targeted genes. (B) Approaches for drug-loaded NP entry within a target cell. (C) of Mito-Porter approach for targeting of cancer-cell mitochondria. (D) Membrane fusion of Mito-Porter with OMM and IMM and the delivery of mitochondria-specific drugs and genes.

Liposomes are spherical vesicles composed of one or more concentric lipid bilayers and are routinely used as drug-delivery vehicles. The physicochemical properties of these vesicles differ considerably on size, composition, surface charge, and even method of preparation.153 New modifications of conventional liposomes to achieve efficient mitochondria targeting are ongoing, as these entities need to be cheaper, atoxic, and biodegradable. This has led to the formation of TPP-modified liposomes coloaded with a photothermal near-infrared (NIR) imaging agent, IR780 iodide, and a photosensitizer known as chlorin e6. These novel liposomes show enhanced toxicity to HeLa cells and some tumor vessels in vitro compared to untargeted ones. In addition, this technique has led to easy and controlled release of drugs and imaging agents to achieve antitumor angiogenesis and photothermal therapy.154 In a parallel strategy, stearyl residues have been conjugated with TPP and incorporated as STPP within lipid bilayers.155 These STPP-modified liposomes were further loaded with ceramide, which showed significantly reduced tumor volume in BALB/c mice.

Liposome-based drug formulations face some aggregation and instability issues in blood. This complication has been resolved by using hybrid cerasomes based on the SiOSi framework and liposomes.156 The cerasomes were conjugated with TPP using 3-aminopropyl triethoxysilane, which acts as a linker. These TPP-modified cerasomes were loaded with doxorubicin (TPPCERDox) through self-assembly process and formed phospholipid bilayer vesicles covering the cerasomes. These possessed extraordinary stability, biocompatibility, sustained drug release, and efficient drug accumulation within mitochondria.157

Recently, a novel liposome (Mito-Porter) has been designed with phosphatidic acid or sphingomyelin nd its surface modified with octaarginine (R8) and GALA, a membrane fusogenic peptide. This special type of liposome can introduce specific cargoes into mitochondria using the advantage of membrane fusion. The presence of highly dense R8 enables the liposomes to achieve micropinocytosis-mediated cell-membrane internalization. The presence of GALA helps the liposomes escape endosome formation. Mito-Porter helps to fuse successfully with both the OMM and IMM158,159 (Figure 3).

Mito-Porters have also been designed for targeting nucleic acids specific to the mitochondrial genome. The presence of phosphatidic acid or sphingomyelin in this formulation facilitates enhanced mitochondrial membrane binding and special cargoes are released within the mitochondrial compartment. For intracellular trafficking of Mito-Porter, R8 plays a crucial role, as its higher density leads to internalization by micropinocytosis and its lower-density vehicles being taken up by clathrin-mediated endocytosis and degraded by lysosomes.158,160

Mito-Porters have also been used to transport fluorescent dyes like propidium iodide for staining nuclear DNA.161 Advancement in the same study led to the discovery of a dual-function Mito-Porter system that penetrates the endosomal and mitochondrial membranes by phase-wise membrane fusion.162 A study was based on comparison of the effective dose for the two types of nanocarriers, and the results showed that the dual-function Mito-Porter was 15-fold higher in efficiency than conventional Mito-Porter for mitochondrial delivery.163

Furthermore, instead of R8, mitochondrial signal targeting signal peptide (MTS) with sequence NH2-MVSGSSGLAAARLLSRTFLLQQNGIRHGSYC was used to form MTS-Mito-Porter; however, this system showed labile aggregation, eventhough it was highly efficient for mitochondrial delivery compared to R8-Mito-Porter.164 In further research, S2 peptides modified with stearyl-Dmt-D-Arg-FK-Dmt-DArg-FK-NH2 were used to decorate the dual-function Mito-Porter, which provoked lower toxicity than the DF-R8-Mito-Porter.165 The mechanism of Mito-Porter uptake by cells and its fusion with mitochondria for the delivery of loaded drug is illustrated in Figure 3.

DQAsomes are well known mitochondriotropic bola-lipidbased vesicles composed of dequalinium (DQA;1,1-decamethylene-bis-[4-aminoquinaldinium chloride]), a dicationic amphiphilic molecule. These vesicles were designed for the transportation of drugs and DNA specific for mitochondria.166 Studies have now demonstrated that DQAsomes induce necrotic and apoptotic activities, as these nanovehicles induce mitochondrial dysregulation. DQAsomes cause mitochondrial membranepotential reduction, excess ROS production, ATP depletion, activation of the protein kinasesignaling cascade, and induction of apoptosis by mitochondria-dependent pathways.167

A novel formulation of curcumin encapsulated by DQAsomes has been prepared with average hydrodynamic diameter about 185 nm, drug-loading capacity up to 61%, and encapsulation capacity up to 90%. These DQAsomes possessed enhanced antioxidant activity compared to free curcumin. These vesicles are potential mitochondria-targeting vehicles, thus representing a promising formulation and improved stability for mitochondria-targeting strategies.168

Some specifically modified DQAsomes have been engineered to deliver plasmid DNA to mitochondria as DQAplexes, a hybrid of DNA and DQAsomes.169 (Figure 3). The application of DQAsomes has been extended further to deliver mitochondria-specific chemotherapeutic drugs. This includes the use of the anticancer drug paclitaxel, which induces apoptosis and ultimately cell death.170 This technique has revolutionized mitochondrial gene-therapy protocols, as the preparation of DQAsomeDNA complexes is quite efficient and simple.169 Plasmid DNA is first coupled with mitochondrial homing sequences for mitochondrial delivery only.171 It has been reported that after harvested mitochondrial contact with DQAplexes, DNA gets released quickly and escapes endosomes.172

Polymeric NPs are formed from poly(glycolic acid), polylactic acid, polycaprolactone, or polylactic-co-glycolic acid (PLGA). These NPs are efficient biocompatible and biodegradable polymers and promising drug carriers.173 They can encapsulate both hydrophilic and hydrophobic drugs.173 A special type of polymeric NP prepared from polycaprolactone modified with PEG and TPP and self-assembled into micelles with a diameter 3860 nm showed CoQ10-loading efficiency of almost 9.5%. These micelles were efficiently loaded and accumulated in mitochondria.

In another study, TPP-modified PLGA-PEG and PLGA-COOH NPs were prepared and their size, potential, and stability optimized. Those with diameter <100 nm and potential >22 mV were efficiently taken up by mitochondria. For clinical application, they were loaded with four drugs: 2,4-dinitrophenol (mitochondrial decoupler), curcumin (amyloid- protein inhibitor for Alzheimers disease), -tocopheryl succinate (tumor targeting drug), and lodamine (mitochondrial glycolysis inhibitor).174 These NPs improved the therapeutic activity of 2,4-dinitrophenol and decreased the amyloid-mediated cytotoxicity.175

In other research, thioketal linker-modified camptothecin (Cpt) was conjugated with PEGylated TPP to form (TL-Cpt-PEG1K-TPP) and blended with DSPEPEG-NH2. This led to the synthesis of photodynamic and chemosensitive dual-function NPs loaded with the photosensitizer molecule as zinc phthalocyanine (ZnPc). These nanoformulations were irradiated by 633 nm laser to produce ROS by thioketal linker rupture, thus releasing Cpt. This led to increased antitumor efficiency against lung cancer. This demonstrates that TL-Cpt-PEG1K-TPP guided the development of mitochondria-targeting in malignant cells with sixfold the cytotoxic activity of free ZnPc and Cpt in NCI-H460 cells.176

Another study used chitosan NPs functionalized with TPP and loaded with Dox. These NPs showed increased antitumor efficiency in A549 and HeLa cells.177 In parallel, PEG-TPP was linked with a disulfide bond. This polymer self-assembled and led to the formation of a hydrophobic TPP core and a hydrophilic PEG shell. Dox was loaded within these NPs and endocytosed by specific cells. Within the cells, glutathione broke the disulfide bond between mPEG and TPP, so removing the mPEG shell, exposing TPP, and driving Dox directly to mitochondria. These results further demonstrated that Dox-encapsulated mPEG-TPP NPs possessed enhanced mitochondria-targeting efficacy and improved therapeutic activity compared to other nonbioreducible NPs.178

The new investigational drugs for the treatment of an increasing number of hematological cancers still have a poor record. Healthcare professionals and researchers are working intensively to find an effective therapy against chronic lymphocytic leukemia.179 Currently, personalized and targeted therapies with active compounds in nanoformulations capable of center-point targeting of cancer cells are the most favorable trends in oncology.180 To date, among the different studies on NPs, dendrimers have demonstrated strong potential in pharmacological applications, and look to become a milestone achievement in oncology and nanomedicine.181,182

Dendrimers are synthetic, hyperbranched macromolecules possessing three components, ie, a central core, repeated branches, and a surface with a controlled number of available groups to load multiple functionalities. The core and branched space is used for biomolecular entrapment, and surface functionality is used to integrate different moieties. These special properties brand dendrimers as multipurpose pharmaceutical nanocarriers.183 They have potential in biomedical applications, and are used as drug carriers184 and gene-transfection vectors,185 as well as in magnetic resonance imaging (MRI) detection.186 The nanometric size of these NPs facilitates their specific and effective interaction with cellular components like proteins, nucleic acids, membranes, and organelles.187 Dendrimers with a generation number greater than five and higher positive charges due to lipophilic cationic molecules like TPP and rhodamine can be engineered. These NPs have the potential for endosomal escape and can deliver chemotherapeutic drugs directly to mitochondria.

Some of the most widely used dendrimers include polypropyleneimine (PPI) and polyamidoamine (PAMAM). These dendrimers are toxic, owing to their positively charged surfaces.188 Proper surface modification is the best way to minimize their toxicity. PPI dendrimers have been modified with maltose and maltotriose sugar residues, and these semi-modified open-shell (OS) PPI dendrimers (PPI-G4-OS) are lethal to selected cancer cells like CEM-SS, MEC1, and U87.189 In comparison to this, their fully modified dense-shell (DS) counterparts (PPI-G4-DS) show relatively weaker or no such effects. Furthermore, neutral DS and cationic OS PPI glycodendrimers have been utilized as stabilization and transfection agents for different particles.190 Third-generation cationic PPI glycodendrimers with open maltotriose shells (PPI-Mal-IIIG3) have been used for the transfection of AuNP conjugated with turbo green fluorescent protein (mitoTGFP) against selective mitochondria targeting of JIMT1 cancer cells. This facilitation of AuNPs by PPI dendrimers led to mitochondrial rupture, triggering apoptosis.191

PAMAM dendrimers are significantly used as a platform for the delivery of genomic materials and drugs.192 PAMAM-based G(5)-D-Ac-TPP dendrimers have been designed for mitochondria targeting in drug delivery.193 For monitoring intracellular localization, these NPs are labeled with a fluorescent dye, and less cytotoxicity has been reported with these nanocarriers. A parallel strategy has been used to deliver the luciferase gene and EGFP within the COS7 and HeLa cells by utilizing TPP-conjugated PAMAM dendrimers (G5-TPP).194 Under the transfection condition, these dendrimers have been reported to be atoxic. The G5-TPP dendrimer platform demonstrates efficient DNA packing and unpacking, endosomal escape, and efficient Mitochondria-targeting genome and drug delivery.

Multiwalled carbon nanotubes (MWCNTs) have been used as anticancer delivery vehicles by surface functionalization with mitochondria-specific ligands. A novel mitochondria-targeted peptide sequence (MTS) with a primary structure of KMSVLTPLLLRGLTGSARRLPVPRAKC has been tagged on MWCNT surfaces to attain efficient mitochondria-specific drug delivery. With the help of confocal microscopy, these nanocarriers have been found to accumulate extensively in HeLa cells and macrophage mitochondria. Mitochondria targeting of these NPs has been further confirmed by transmission electron microscopy (TEM). Further, these NPs have not been reported to possess any significant toxicity, so are potential candidates as effective mitochondria-targeted drug-delivery systems.195 In this vista, mitochondrial-targeting has also been achieved by cationic rhodamine- 110 (MWCNT-) and fluorescein (MWCNT-Fluo) used as an untargeted control.196 MWCNT- has also been used to entrap a platinum prodrug (PtBz), which presented enhanced potency and efficient mitochondrial localization.

Inorganic NPs cover a broad range of substances, including elemental metals, metal oxides, and metal salts. Inorganic NPs have been utilized as mitochondria-targeting agents, as these form uniform and smaller NPs. Among these, hydroxyapatite (HAp; Ca10(PO4)6(OH)2), displays outstanding drug-loading capacity and biocompatibility. It has been reported that HApNPs enter tumor-cell mitochondria and induce apoptosis by disturbing MMP, causing leakage of cytochrome c (cyt c).197 Rod-shaped HApNPs have been engineered with about 50 nm length and almost 10 nm width, and are engulfed by caveolate-mediated endocytosis by normal bronchial epithelial cells (16HBE) and lung cancer cells (A549). Interestingly, it has been further reported that A549 lung cancer cells engulf more NPs, causing sustained rise in Ca2+ concentration compared to 16HBE normal cells. This property of specific cell and mitochondria targeting causes increased Ca2+ concentration, resulted in almost 40% cancer-growth inhibition even without a drug, in lung cancer in nude mice.198 Anticancer efficacy was furthered with Dox-loaded HApNPs and coating with hyaluronic acid (HA). This nanoformulation specifically targets CD44-overexpressing cancer cells and overcomes the burst drug release. It has been found that Dox-loaded HAp-HA NPs exhibit almost four- to sevenfold the cytochrome c (cyt c) release of free Dox under similar conditions.199

Metallic NPs are emerging as innovative drug carriers and contrast agents for the treatment of different cancers. Metallic NPs are routinely used as site-specific targeting, drug delivery, and imaging of different tumor cells.200 Metal and metal oxide NPs can be precisely synthesized and modified with different functional groups. The novel functionalization of these metallic NPs helps in conjugating them with various mitochondria-specific moieties for use in specific cancer treatment. Some common metallic NPs are explained in the following sections to understand their significance for mitochondria targeting and cancer management.

In addition to other metallic NPs, gold NPs (AuNPs) have been demonstrated to accumulate within mitochondria and trigger apoptosis after internalization by cells.201 AuNPs have been conjugated with GFP and tagged at the amino terminus with a mitochondrial localization sequence of the IMM protein COX8. To overcome the aggregation of AuNPs, these nanoformulations were altered with cationic maltotrioseamended polypropyleneimine dendrimers to coat mitTGFP-AuNPs. However, for proper transfection, this nanoformulation (mitoTGFP-AuNPs) required a cationic glycodendrimer (PPI-Mal-III G3) for traversing the plasma membrane. These NPs quite successfully escaped early endosome formation, efficiently ruptured the OMM, and finally got localized within the IMM. This resulted in cytochrome c (cyt c) release that triggered apoptosis.202 In a similar fashion, multilayered polypeptides were used to surround the AuNPs. The first layer used was a CALNN-based peptide to avoid the aggregation of AuNPs. The second layer was tetrameric streptavidin, a linker to join biotinylated molecules. The outermost layer was a biotinylated peptide (KLA:(KLAKLA)2), which possessed both the mitochondriotropic agent and cytotoxic peptide to kill the cancer cells. These KLA-tagged AuNPs possessed thousands of times the antitumor activity of free KLA peptide. KLA peptide is well recognized for its efficiency in cell entry and mitochondrial specificity.203

TiO2NPs have stronger catalytic activity and have been widely used for different applications.204 These raise some concerns about adverse health effects, as they are smaller particles with larger surface area.205 Significant associations have been found between metabolic stress, inflammatory response, and ROS production and treatment with TiO2NPs in brains of mice.206

TiO2NPs can concentrate in the brain after crossing the BBB, thereby resulting in infiltration of inflammatory cells and apoptosis of hippocampus cells. This leads to a decrease in cognitive brain functioning.207 ROS generation damages the cell membrane, which further facilitates the entry of TiO2NPs, activating signaling pathways involved in oxidative stress. To check oxidative stress, expression ofNRF2 is very important. The association between oxidative stress and p38, JNK, and MAPK cascade is well established.206 In addition to this, TiO2NPs induce apoptosis, alter the immune system, and works as a secondary messenger for some intracellular signaling cascades. TiO2NP-mediated enhanced ROS production may also be related to p38NRF2 signaling pathways during brain injury.208

Silver NPs (AgNPs) have been widely used in chemical, antimicrobial, household, and medical applications.209 AgNP composition, size, shape, charge, and solubility affect their ability to bind with biological sites. The cytotoxicity of AgNPs is mainly related to cell-membrane destruction, which leads to mitochondrial destruction.210 These NPs usually induce oxidative stress, which is the major reason for their toxicity.211 AgNPs also deplete the antioxidant defense system, leading to enhanced ROS accumulation, which initiates the inflammatory response, and the destruction of mitochondria.212,213 The perturbation of mitochondria also leads to cytochrome c (cyt c) release and apoptosis as the final outcome. AgNPs also exhibit toxicity toward mammalian and HEPG2 cells by reducing MMP, DNA damage, and mediating apoptosis.214 In addition, this perturbation also leads to changes in the mitochondrial respiratory chain, dynamics, biogenesis, and autophagy control.215

ZnONPs are used in biomedical imaging and, fungicides and as anticancer drugs and antimicrobial agents.216 The toxicity of these NPs has been mainly related to the production of ROS, which leads to oxidative stress, inflammation, and DNA and protein modifications. The oxidative stress also leads to lipid peroxidation and apoptosis through the p38 and p53 pathways.217 The ROS production also leads to the activation of MAPK pathway, which regulates different cellular pathways.218

In one study, ZnONPs at 1420 g/mL exposed to HEPG2 cells for 12 hours induced apoptosis-mediated reduced cell viability. The cell-viability decline was due to oxidative stressmediated DNA damage and decreased MMP. Furthermore, these NPs increased the ratio of BAX:Bcl2, which led to the induction of apoptotic pathways. ZnONPs also activated p38 and JNK pathways and induced the phosphorylation of p53 Ser15 residues.219

Various investigations support the role of ZnONPs in mitochondria-mediated toxicity induction in experimental animal studies and in vitro models.220 These NPs trigger excessive ROS production in zebrafish embryos by reducing MMP and inducing mitochondria-mediated apoptosis.221 Further, they decrease mitochondrial density by disrupting biogenesis, inhibit the PGC1 pathway, and interfere with mtDNA number control. PGC1 plays a significant role in mitochondrial biogenesis regulation by interaction with downstream targets like TFAM, which helps in transcription of some genes. This factor also plays an important role in controlling mitochondrial oxidative stress by the activation of manganese superoxide dismutase.222

FeONPs have been used for cell labeling, gene delivery, and drug targeting and as hyperthermia-therapy agents. These NPs are also good contrast agents in magnetic resonance imaging.223 FeONPs induce such cellular responses as cell activation, ROS production, and cell death.224 In addition, FeONPs cause mitochondrial damage, though these NPs are not targeted for this organelle.225 Mitochondria are the principal source of ROS generation, and prolonged action initiates oxidative stress, which leads to activation of transcription factors and some inflammation-responsible genes like AP1 and NFKB.

Magnetic composite NPs for dual modal photothermal therapy and photodynamic therapy have been used to enhanced cancer therapeutic effect by mitochondria targeting. These composite NPs have the capacity to generate heat and ROS simultaneously upon NIR-laser irradiation. After surface modification of targeting ligands, they have been selectively delivered to mitochondria to amplify the cancer-cell apoptosis promoted by hyperthermia and cytotoxic ROS.226

Lung cancer cells have been reported to increase their ROS production after exposure to FeONPs. This increased production is blocked by N-acetyl cysteine (NAC), which results in significantly decreased cell death. In addition, this exposure also leads to decreased conversion of LC3-I to LC3-II within cancer cells pretreated with f-NAC. Therefore, FeONPs likely induce ROS production and autophagy-mediated cell death. These lethal consequences are likely due to mitochondrial damage caused by FeONPs, as MMP is significantly reduced as well.227

FeONPs have been probed with P13/Akt, and it was observed that they activated the classical AMPKmTORAkt signaling cascades in lung cancer cells. The involvement of AMPK phosphorylation during autophagic cell death has been fully confirmed by pretreating the cells with the AMPK-phosphorylation inhibitor compound C.228 However, the direct role of FeONPs on AMPK- and mTOR-mediated autophagy and cell death with the help of certain inhibitors is still under observation. It has been observed that FeONPs possess autophagic potential by activating the classical pathway for autophagy induction.229 Some more examples of drug-loaded nanocarriers targeting mitochondria with the aid of varied targeting moieties are briefly listed in Table 3.

Table 3 Drug-loaded nanocarriers tagged with various mitochondriophilic ligands, inducing different mitochondrial functional irregularities

Using native drugs poses a number of challenges before reaching the final target of action. Healthcare researchers are working hard to design the drugs that can be specifically transported to the site of action while minimizing unwanted buildup in untargeted normal tissue. NPs can have different routes of administration like respiratory tract, skin, and parenteral administration to reach the actual target.247 Properties that can give rise to unexpected toxicities should be equally noted.248 In the blood, some drug nanoformulations can lead to the formation of protein corona while in contact with plasma proteins. The protein corona may consist of dozens to hundreds of proteins that can alter the physicochemical properties of NPs like morphology, size, aggregation, and -potential.249

The toxicity potential of cationic NPs like polystyrene and AuNPs can lead to clotting and hemolysis, whereas the toxicity potential of anionic NPs is considerably less.250 NP use leads to some basal toxicities, due to disruption of host homeostasis that leads to ROS production.251 Enhanced ROS can promote genome damage and micronuclei formation. AgNPs of 15 nm and amorphous TiO2 NPs of 30 nm in size induce the highest ROS generation. The possible engulfment of quantum dots and AgNPs by macrophages can lead to the expression of inflammatory mediators like IL1, TNF, MIP2, irrespective of their size.252 The chronic inflammation by ROS producing NPs can lead to the development of pulmonary diseases, atherosclerosis, or even cancer. Other NPs can affect calcium homeostasis, thus affecting cellular metabolism, signal transduction, and gene expression. Dissociated ions from metallic NPs can even prove to be more toxic, so NPs of biodegradable polymers can be beneficial to use.253,254 Single- or multiwalled CNTs induce the aggregation of platelets, while their building-block C60 fullerenes do not. All NPs tend to accumulate in the liver, and the mechanism of their elimination from the body needs to be investigated.247

NPs have been extensively studied in theranostic clinical applications, and several formulations have been approved by the US Food and Drug Administration and European Medicines Agency for clinical applications in patients with cancer.255 The formulation of cancer nanomedicines is mainly based on liposomes (eg, Doxil, Vyxeos, and Onivyde), polymeric micelles (eg, NK105, Genexol, and NC6004), albumin (eg, Abraxane), or inorganic NPs (eg, NBTXR3 and NanoTherm). Although most current cancer nanomedicines are administered intravenously for systemic delivery to tumors, some nanomedicine formulations (eg, NanoTherm and NBTXR3) have been designed for intratumoral administration.256 A brief overview of some major approaches of nanomedicine aiming to modulate the TCA cycle, ETC, anaplerosis, mtROS, and mitochondria-driven apoptosis in cancer cells is presented in Table 4. The table also highlights clinical phase stages and the clinical identifier numbers of molecular targets and the drugs used against these targets.

Table 4 Clinical perspectives (phases and trials) of some Mitochondria-targeted therapeutic strategies for cancer management

The strategy of direct therapeutic action by targeting mitochondria will dramatically decrease the side effects of a particular drug at aspecific locations, and is the ultimate goal of future therapeutics. Nanomedicine faces tremendous challenges due to the diverse nature of biological systems. The advantage of engineering multidimensional features within NPs for specific targeting to diseased cells and enhanced accumulation in particular organelles has drastically revolutionized therapeutic strategies, where mitochondrial dysfunction plays a central role.

NPs like liposomes, micelles, CNTs, and dendrimers tagged with specific mitochondria-targeting moieties have demonstrated their existence as novel delivery means. However, more comprehensive research is necessary to properly understand the safety aspects of drug nanoformulations when used in human subjects. For successful mitochondrial targeting, the characteristics of these theranostic NPs should be highly efficient to achieve their goals. Some novel characteristics include tumor-cell and tissue specificity, long circulation time in blood, and large accumulation within cancer-cell mitochondria.

Some types of currently used mitochondria-targeting nanoformulations suffer from certain drawbacks. For example, delocalized lipophilic cations accumulate efficiently in mitochondria because of negative mitochondrial membrane potential; however, they mediate intrinsic toxicity, which limits their clinical applications. In addition, other targeting ligands like peptides have bulky structures, solubility issues, poor membrane permeability, and very low stability in serum. To overcome these limitations, in-depth research is necessary to engineer such targeting ligands properly to make them clinically more useful as drug-loaded mitochondria-targeting agents.

It is a very challenging task to engineer nanoformulations that can perfectly target mitochondrial abnormalities in tumor cells without toxicity to nearby normal cells. To solve this challenge, different physicochemical factors of nanoformulations have been considered, which include shape, size, charge, membrane potential, tumor-cell specificity, andcombinations thereof.

The endosomal escape ability of theranostic nanoformulations is of utmost importance in enhancing their mitochondria-targeting abilities. For the production of effective mitochondria-targeting NPs, these nanoformulations should be equipped with endosomolytic features. Furthermore, as NIR photosensitizers enable the imaging of NIR fluorescence, photothermal signals, and photoacoustic signals, the corresponding diagnostic materials should be considered for other imaging tools like CT, PET, MRI, and SPECT.

Despite the success of these novel nanoformulations in in vitro studies, thorough and logical preclinical and clinical studies are obligatory to achieve their potential use in clinical settings. At present, there is a big gap in understanding the safety aspects unique to specific nanoformulations when used in varied systems. These of nanoformulations need to be properly addressed when targeting mitochondria of diseased cells only. Enormous efforts are required for the development of targeted nanoformulations. It is extremely difficult to use nanoformulations unless full understanding and characterization of them are achieved.

The direct mitochondria-targeting approach within cancer cells is a current focused to enhance therapeutic strategies, and has gained momentum in the last decade. The goal is to design nanoformulations that can show minimum off-target and side effects. Mitochondria of cancer cells have unique features, which are novel targets of different theranostic NPs as a therapeutic strategy. These novel targets include oxidative phosphorylation site, TCA cycle, glutamine metabolism, and mitochondrial dynamics and trafficking. The direct conjugation of anticancer drugs with mitochondria-targeting ligands (eg, TPP, DQA, and MPP) has been able to solve some complications like use of larger doses and drug resistance. This problem has been solved to some extent by the use of nanoformulations (eg, liposomes, Mito-Porter, and CNTs), but still there are so many other challenges like toxicity complications and center-point targeting that need to be sorted out. Despite the primary success of these nanoformulations, systematic preclinical and clinical investigations are obligatory before their actual use in clinical settings. At present, there is a lack of thorough understanding regarding safety concerns, which limits their use as nanomedicine. The safety aspects of these nanoformulations need to be properly addressed through appropriate safeguards. The prerequisite of thorough understanding of the mitochondrial role in cancer progression, employment of proper regulatory procedures, and advancements in nanoformulation technology will definitely boost cancer treatment in the near future.

We are thankful to all the researchers who have contributed immensely to the field of cancer biology by using mitochondria-specific drug nanoformulations as a strategy in cancer therapy.

The researchers would like to thank the Deanship of Scientific Research, Qassim University for funding the publication of this project.

The authors declare no conflicts of interest.

1. Chan DC. Fusion and fission: interlinked processes critical for mitochondrial health. Annu Rev Genet. 2012;46:265287. doi:10.1146/annurev-genet-110410-132529

2. Hoitzing H, Johnston IG, Jones NS. What is the function of mitochondrial networks? A theoretical assessment of hypotheses and proposal for future research. Bioessays. 2015;37(6):687700. doi:10.1002/bies.201400188

3. Rai PK, Russell OM, Lightowlers RN, Turnbull DM. Potential compounds for the treatment of mitochondrial disease. Br Med Bull. 2015;116:518. doi:10.1093/bmb/ldv046

4. Xia MF, Zhang YZ, Jin K, Lu ZT, Zeng Z, Xiong W. Communication between mitochondria and other organelles: a brandnew perspective on mitochondria in cancer. Cell Biosci. 2019;9:27. doi:10.1186/s13578-019-0289-8

5. Gorman GS, Chinnery PF, DiMauro S, et al. Mitochondrial diseases. Nat Rev Dis Primers. 2016;2(1):122. doi:10.1038/nrdp.2016.80

6. Solaini G, Sgarbi G, Baracca A. Oxidative phosphorylation in cancer cells. Biochim Biophys Acta. 2011;1807(6):534542. doi:10.1016/j.bbabio.2010.09.003

Read more from the original source:
Novel Strategies for Disrupting Cancer-Cell Functions with Mitochondri | IJN - Dove Medical Press

Pet of the Week: Meet Mimi & Vinnie – Live 95.9

Every Wednesday at 8:30we're joined by John Perreault, Executive Director of theBerkshire Humane Societyto discuss all the happenings at their Barker Road facility, plus talk about their Pet of the Week.

This Week's Pet(s) of the Week are Mimi and Vinnie. They're a mother and son pair of domestic shorthair cats found as strays. Mimi, an orange and brown tiger with white paws, is friendly, but Vinnie, a playful one-year-old white cat with orange markings, was born and raised outside and is a bit afraid of people.

The pair was started in a foster home to work on trust and socialization and now they are available at the shelter. Theyve made great strides, and need an indoor home with someone who can help them continue to thrive.

If you are interested in learning more about this pair, please call Berkshire Humane Societys cat department at (413) 447-7878 extension 124. They also qualify for our buddy program where the adoption fee of the second cat is half of the normal cost.

TheBerkshire Humane Society is now back open to the public for regular hours with masks required and social distancing in place.

To prepare yourself for a potential incident, always keep your vet's phone number handy, along with an after-hours clinic you can call in an emergency. The ASPCA Animal Poison Control Center also has a hotline you can call at (888) 426-4435 for advice.

Even with all of these resources, however, the best cure for food poisoning is preventing it in the first place. To give you an idea of what human foods can be dangerous, Stacker has put together a slideshow of 30 common foods to avoid. Take a look to see if there are any that surprise you.

More here:
Pet of the Week: Meet Mimi & Vinnie - Live 95.9

The Disappointment of Memorial Day Rain on the Seacoast – Seacoast Current

The good thing about the cold, miserable, wet weather on the Seacoast for the Memorial Day weekend is that the rain will help alleviate the near drought situation.

Otherwise, it's a big disappointment to many who were looking forward to spending time outdoors on the first near "pandemic free" holiday weekend.

The forecast calls for cloudy skies Saturday and rain all day Sunday into Monday. Temperatures will be cool in the 50s and into the 60s on Monday which is almost 25 degrees lower than the normal high temperatures in the Seacoast for the end of May, according to National Weather Service meteorologist Margaret Curtis.

She expected the Seacoast to get the most rain with up to an inch-and-a-half to fall through the end of Tuesday.

"There's been a little bit of rain on Memorial Day in several of the past years but the last big washout was in 2003," when over an inch of rain fell in some areas of the state, Curtis told Seacoast Current.

The rainy forecast is also a disappointment to Valerie Rochon, chief collaborator for the Chamber Collaborative of Greater Portsmouth who expects numbers to be down.

"We can do all the marketing we want and expectations we want but Mother Nature is in charge," Rochon told Seacoast Current. "It is a long holiday weekend and hopefully people will be willing to go out and about and those who are comfortable going indoors will. Those that don't and are looking for outdoor dining might be a little more challenged."

Rochon said that retailers will also be affected by the wet weather because of lower foot traffic but hotels might be okay.

"If they made a reservation and you expect to get away for the weekend whether it's raining or not you're still getting away. I think the hotels with pre-reserves will be okay but might miss out on some of the last minutes," Rochon said.

York's Wild Kingdom opened for the season without social distancing, capacity limits or mask mandates in place since all were lifted by the state of Maine. The rain may keep some of the animals indoors, according to the park's Facebook page.

The good thing about the rain is that it will help with the southern part of New Hampshire's in "abnormally dry" drought condition, according to Curtis. Rainfall is running 1.55 inches below normal for the month before Saturday and year-to-date nearly five inches below normal.

"Anything we can do in terms of extra precipitation is really going to help," Curtis said, adding that conditions are not quite as dry as they were at the end of 2020.

"It will be good to keep to keep those wells filled and grass greened up for summer," Curtis said.

Conditions prompted the city of Dover to residents to conserve water and to water outdoors only when necessary "to ensure an adequate and sustainable supply of drinking water throughout the summer."

Contact reporter Dan Alexander at Dan.Alexander@townsquaremedia.com or via Twitter @DanAlexanderNH

To prepare yourself for a potential incident, always keep your vet's phone number handy, along with an after-hours clinic you can call in an emergency. The ASPCA Animal Poison Control Center also has a hotline you can call at (888) 426-4435 for advice.

Even with all of these resources, however, the best cure for food poisoning is preventing it in the first place. To give you an idea of what human foods can be dangerous, Stacker has put together a slideshow of 30 common foods to avoid. Take a look to see if there are any that surprise you.

Read the original here:
The Disappointment of Memorial Day Rain on the Seacoast - Seacoast Current

Zeus Has Lots Of Love And Puppy Kisses To Give To You – mix931fm.com

Ifyou're looking for a full time companion that will be your best friend for life, then you need to stop what you're doing and meet our Pet Of The Week.

Zeus is a nine month of German Shepherd mix. He is young impressionable, trainable and most of all, loyal to his owner. Zeus is currently available for adoption at the Humane Societys Pets Fur People in Tyler. Executive Director Gayle Helms believes he would thrive as a member of an active family and loves other dogs and taking rides in the car. For being only nine months old, Zeus is a big fella weighing about seventy pounds. He's pretty smart, he's already been house trained. He has been neutered, is current on starting vaccinations including rabies and has been microchipped for identification purposes. Zeus will go home with a starter kit of food, a collar and leash and a certificate for half price on basic obedience training from Tyler Obedience Training Club.

For additional information on adopting Zeus call 903.597.2471 or check the Humane Societys Pets Fur People website. Due to concerns over COVID-19, pet adoptions are currently being handled by appointments only. Check out the animals that are available for adoption. Adoption hours are Tuesday through Saturday 10 a.m. until 5 p.m. - closed for lunch 1 - 2 p.m. The Humane Societys Pets Fur People is the oldest brick and mortar no kill shelter in East Texas. Pets Fur People offers dog boarding and routine vaccinations, except for rabies, to the public for dogs and cats. Follow them on Facebook, Twitter and Instagram. Please be a responsible pet owner - spay or neuter your pets. Donations are appreciated.

To prepare yourself for a potential incident, always keep your vet's phone number handy, along with an after-hours clinic you can call in an emergency. The ASPCA Animal Poison Control Center also has a hotline you can call at (888) 426-4435 for advice.

Even with all of these resources, however, the best cure for food poisoning is preventing it in the first place. To give you an idea of what human foods can be dangerous, Stacker has put together a slideshow of 30 common foods to avoid. Take a look to see if there are any that surprise you.

Go here to read the rest:
Zeus Has Lots Of Love And Puppy Kisses To Give To You - mix931fm.com

Canine Stem Cell Therapy Market Highlights On Evolution 2026 The Courier – The Courier

Global Canine Stem Cell Therapy Market: Overview

The global canine stem cell therapy market has seen vast developments in the past few years in terms of the technology available for obtaining, preserving, and using stem cells. The costs of canine stem cell therapy have also seen a notable decline over the years and stem cells are becoming a preferred mode of treating a number of ailments affecting canines. Moreover, studies showing the excellent level of safety granted by allogeneic stem cell therapy are also rising in numbers, leading to increased confidence among pet owners as well as veterinarians regarding canine stem cell therapy.

Global Canine Stem Cell Therapy Market: Trends and Opportunities

Some of the key factors working in favor of the global canine stem cell therapy market are the rising prevalence of chronic diseases in dogs, increase in spending on R&D activities, surge in investment by government bodies, and expenditure on companion animals across the world. Technological advances in diagnostic practices, awareness about the treatment of chronic diseases, and high emphasis on prevention and wellness by veterinarians is expected to propel demand for canine stem cell therapy measures across the globe in the next few years.

Request Brochure of Report https://www.transparencymarketresearch.com/sample/sample.php?flag=B&rep_id=49605

However, the relatively high costs of these therapies, which could sound unaffordable for masses in emerging economies with low disposable incomes, could limit the growth of the market to a certain degree over the reports forecast period. Moreover, in a number of countries across the globe, a large number of veterinary clinics lack advanced infrastructure and facilities. This necessitates referral to specialty veterinary hospitals that have expert veterinarians. Trained veterinarians often charge high costs for advanced therapies such as stem cell therapy. The non-availability of comprehensive pet health insurances makes the scenario grave for a large number of pet owners across the globe.

Global Canine Stem Cell Therapy Market: Segmentation

The report segments the global canine stem cell therapy market based on criteria such as product type, application, end user, and geography. Based on product type, the market has been examined for allogeneic stem cells and autologous stem cells. Of these, the segment of allogeneic stem cells, referring to stem cells that are collected from a healthy, matching donor and not from the patients own body, is the most preferred owing to low cost and the ease of harvesting and using.

Request for Custom Research https://www.transparencymarketresearch.com/sample/sample.php?flag=CR&rep_id=49605

In terms of application, the market has been examined for canine ailments such as lameness, arthritis, tendonitis, elbow dysplasia, and atopic dermatitis. Of these, the segment of osteoarthritis accounts for a dominant share in the overall revenue of the global market owing to the high prevalence of the condition in aged dogs. A high population of dogs suffer from the condition as they age but few are treated. This makes the segment highly opportunistic and lucrative for companies operating in the canine stem cell therapy market. Based on end user, the report segments the global canine stem cell therapy market into veterinary clinics, veterinary hospitals, and veterinary research institutes.

Global Canine Stem Cell Therapy Market: Geographical and Competitive Dynamics

From a geographical standpoint, the report covers the market for canine stem cell therapy in regions such as North America, Asia Pacific, Europe, Latin America, and Middle East and Africa. Presently, the markets in Europe and North America are among the leading contributors of revenue opportunities to the global market owing to the high numbers of pets, high disposable incomes of pet owners, and easy availability of advanced therapies for pets. The high numbers of specialized veterinarians and veterinary clinics in these regions also contribute to the promising growth opportunities held by the canine stem cell therapy market in these regions.

Pre Book Canine Stem Cell Therapy Market Report at https://www.transparencymarketresearch.com/checkout.php?rep_id=49605&ltype=S

Some of the leading companies operating in the market are VetStem Biopharma, Inc., Regeneus Ltd, Aratana Therapeutics, Inc., VETherapy Corporation, Animal Cell Therapies, Inc., Magellan Stem Cells, and Medrego.

About Us

Transparency Market Research is a global market intelligence company providing global business information reports and services. Our exclusive blend of quantitative forecasting and trends analysis provides forward-looking insight for several decision makers. Our experienced team of analysts, researchers, and consultants use proprietary data sources and various tools and techniques to gather and analyze information.

Our data repository is continuously updated and revised by a team of research experts so that it always reflects latest trends and information. With a broad research and analysis capability, Transparency Market Research employs rigorous primary and secondary research techniques in developing distinctive data sets and research material for business reports.

Contact

Transparency Market Research,

90 State Street, Suite 700,

Albany, NY 12207

Tel: +1-518-618-1030

USA Canada Toll Free: 866-552-3453

Website: https://www.transparencymarketresearch.com/

See original here:
Canine Stem Cell Therapy Market Highlights On Evolution 2026 The Courier - The Courier

Back to Top