Peptides can be beneficial for your general wellness. They exist naturally within your body, but they can also be administered through regenerative treatments.
What are these compounds, and how can they be used in regenerative medicine?
Peptides Are Strings of Amino Acids
Peptides are made of amino acids, the chemical building blocks for proteins. Your body makes and uses many different peptides for different purposes.
Some peptides generate beneficial tissues and compounds, like collagen or creatine. Others work through medications to combat certain health conditions, such as diabetes.
Peptides can boost your health and well-being in many ways when used in regenerative treatments.
Creatine Peptides for Muscle Growth
Creatine peptides may boost muscle growth and strength over time. These muscle-building peptides can be used in treatments that aim to alleviate musculoskeletal pain.
When your muscle fibers break down and are not repaired properly, you can experience pain, discomfort, and loss of mobility. Peptides can reinforce the structure and strength of your muscles to help you regain comfort and mobility.
Collagen Peptides for Skin and Hair Rejuvenation
Many supplements contain collagen peptides, which are believed to enhance the skin barrier. Collagen is a skin fiber that keeps your skin firm, elastic, and resistant to impact. As you get older, your body produces less collagen, and your skin starts to age.
With collagen peptides, your body can repair and reinforce your skin barrier to give you a more youthful appearance. They can also slow the skin aging process by giving your body the building blocks to make more collagen.
Collagen peptides can also enhance your hair health. If you struggle with hair loss and balding, collagen peptides could make a noticeable difference. Collagen fibers add strength and structure to your hair for enhanced growth.
Peptides for Joint Recovery
Joint health is important for mobility, comfort, and quality of life. Certain peptides may aid in joint recovery and regeneration to ease the painful symptoms of some joint problems.
When you lose cushioning around your joints due to tissue degeneration, you might experience pain and stiffness in these areas. Certain peptides may help rebuild these tissues to make movement and functioning easier and more comfortable.
Combined with stem cell therapy, peptides could reduce inflammation around your joints to give you a better quality of life.
Regenerative Medicine: Peptides for Healing and Relief
Regenerative medicine uses the power of peptides and other compounds to potentially manage symptoms and relieve pain. If you struggle with chronic health problems, this could be a game changer for your daily functioning and comfort levels.
Regenerative medicine, also known as stem cell therapy, is an alternative medicine that seeks to replace damaged tissue and/or organs. Usually, this damage is a result of disease, congenital issues, or trauma. Regenerative therapies are distinct from clinical strategies. Typically, clinical strategies primarily focus on treating the symptoms of an issue. Regenerative therapies, on the other hand, seek to address the issue itself. Here we will discuss Regenerative Medicine for ankle pain.
In recent years and based on research, stem cell therapy has become a more often explored option either in conjunction with traditional medicine or if options have been exhausted. It can be used to help manage and potentially provide a healing cascade for joint pain associated with certain injuries and illnesses.
What Are Stem Cells?
Stem cells are raw materials in the body. They’re the cells from which other specialized cells are generated. Stem cells will divide to form more cells, which are called daughter cells. Daughter cells transform into either new stem cells or specialized cells that perform a more specific function. Some of these specialized cells include:
Heart muscle cells
Mesenchymal stem cells are fascinating because no other cell in the human body has the ability to generate completely new cell types.
What Is Stem Cell Therapy?
Stem cell therapy uses stem cells to help repair injured, dysfunctional, or diseased tissue. Using stem cells in medicine can help support your body’s ability to heal and regenerate itself while reducing pain.
Sometimes, ankle pain can happen without an injury, as in the case of rheumatoid arthritis, gout, osteoarthritis, and lupus.
Stem Cell Therapy for Ankle Pain
Since stem cell therapy has dual functions (i.e., the healing function and the pain relief function), stem cell therapy can manage ankle pain that is or isn’t associated with injuries.
Patients’ response to therapy may vary on when they see potential improvements, but generally they may experience some pain relief after around three weeks post-treatment. This improvement will gradually continue over the course of months or years.
Benefits of Regenerative Medicine
Depending on the degree of injury, stem cells have the ability to help regenerate the injured or diseased tissues. For patients who want to avoid invasive surgeries or pain medications to address their musculoskeletal injury, stem cell therapy may be an option to explore. This post was written by a medical professional at Stemedix Inc. At Stemedix we provide access to Regenerative Medicine for Orthopedic also known as Orthopedic Stem cell Therapy. Regenerative medicine has the natural potential to help improve symptoms sometimes lost from the progression of many conditions. If you want to learn more about Regenerative Medicine for ankle pain, contact us today at Stemedix.
Alzheimer’s disease (AD) is the most common cause of dementia, accounting for an estimated 50%-70% of dementia cases worldwide. Characterized by memory loss and cognitive impairment, AD is progressive, debilitating, and fatal. In addition, it’s estimated that new cases of AD around the globe are occurring at a staggering rate of 20 per minute with an established effective treatment yet to be discovered.
To date, research has demonstrated an advanced understanding of AD’s development and devastating – and eventually fatal – outcomes, but has only been able to identify drugs that intervene too late in the progression of the condition.
Considering that stem cells have a detailed and documented record of their ability of self-renewal, proliferation, differentiation, and transformation into different types of central nervous system neurons and glial cells and that they have been successful in AD animal models, it is believed that stem cells have the potential to treat patients with AD.
In reviewing the progress of stem cells as a potential therapeutic treatment for AD, Liu et al. call for new treatments, including the removal of toxic deposits and the ability to replace lost neurons to be developed and as a way to stimulate neural precursors, prevent nerve death, and enhance structural neural plasticity. The authors also review the pathophysiology of AD and the application prospect of related stem cells based on specific cell types.
Liu et al. point out that, although AD models using animal research have been demonstrated to be successful, animal research is difficult to translate into human trials, and, to date, none have been able to replicate the complex environment observed in the human brain. Considering this, the authors conclude that it is challenging, at best, to characterize the beneficial effects of stem cells in AD based solely on previously conducted animal models.
As a result of this review, the authors also conclude that while stem cells used in AD and animal models have achieved certain results, there are still several factors that require consideration. Among these factors is the fact that this type of stem cell therapy requires neurosurgical procedure and immunosuppression which contributes to ongoing concerns related to controlling the proliferation and differentiation of stem cells, the targeting of molecular markers, and the development of cell delivery systems.
The authors acknowledge that progression in the study of stem cells in AD applications should be made more efficient because of recent technological advances in stem cells, specifically using hydrogels, nano-technology, and light therapies to produce more efficient delivery of treatment.
While these advances should help, Liu et al. also point out that a number of obstacles, including uncertainty about the amyloid hypothesis, differing objectives related to preventing progression vs symptomatic treatment, and demonstrating the relationship between stem cell treatment and complete AD cure, still need to be addressed.
Considering the findings of this review, the authors conclude that stem cell therapy for AD carries enormous promise, but the successful application will most likely be dependent upon consistent early diagnosis of the condition in order to prevent further brain cell deterioration and will likely be combined with an administration of existing medication as a way to most effectively treat and/or prevent AD.
Currently, it’s estimated that nearly 1.5 million Americans are living with type 1 diabetes (T1D), a number that is expected to increase to over 2 million by the year 2040. In the U.S. alone, healthcare costs and lost wages directly related to T1D currently exceed $16 billion per year.
While the most common treatment for T1D continues to be regular injections of insulin and is effective in improving hyperglycemia, the treatment has proven ineffective in removing autoimmunity and regenerating lost islets. Additionally, islet transplantation, a recent and experimental treatment option for T1D, has demonstrated its own set of issues, primarily poor immunosuppression and a limited supply of human islets.
The rapid progression and recent advances in stem cell therapy, including mesenchymal stem cell (MSC) therapy, have created interest in using stem cells to help manage the symptoms of T1D. In this review, Hai Wu reviewed the properties of MSCs and highlighted the progress of using MSCs in the potential treatment of T1D.
Diabetes clinics have demonstrated progress using depleting antibodies as a way to treat T1D, but continue to find remission to typically last for only a short period of time. Additionally, treatment with these antibodies has shown not to discriminate between different types of T cells, meaning even T cells involved in maintaining normal immune function are depleted; this phenomenon has been shown to contribute to other serious health complications.
In addition to the immunomodulatory effects demonstrated by MSCs, they have also shown the ability to recruit and increase the immunosuppressive cells of host immunity. Recent results from clinical trials have shown that just a single treatment with MSCs provided a lasting reversal of autoimmunity and improved glycemic control in subjects with T1D.
While these results demonstrate the potential of MSCs for a wide range of autoimmune diseases, Wu points out that the small sample size of these studies necessitates further clinical trials before considering approval for use in clinical applications.
Studies of human islets and human islet transplantation have been limited because of a shortage of pancreas donors. Although unable to be definitively demonstrated, and considering their ability to differentiate into other cell types, there is a hypothesis that MSCs can transdifferentiate to insulin-producing cells. While not yet fully understood, this hypothesis is further supported by the observation of crosstalk between MSCs and the pancreas in diabetic animals.
Other in vivo studies examining this relationship has produced mixed results. For example, Chen et al. (2004) were unsuccessful in attempts to transdifferentiate MSCs into insulin-producing cells in vitro. On the other hand, several studies, including those by Timper et al. (2006) and Chao et al. (2008) demonstrate the formation of islet-like clusters from in vitro cultured MSCs and the possibility of using MSCs as a source of human islets in vitro.
Despite these promising findings, the author highlights that most of these studies failed to generate sufficient amounts of islets required for human transplantation and long-term stability. However, Wu notes recent advances in tissue engineering, including biocompatible scaffolds, might better support in vitro generation of islets from MSCs.
The author concludes that MSCs can be isolated from multiple tissues, are easily expanded and genetically modified in vitro, and are well-tolerated in both animal and human studies – making them a good candidate for future cell therapy. On the other hand, stem cell therapy alone might not be enough to reverse the autoimmunity of T1D, and co-administration of immunosuppressive drugs may be necessary to prevent autoimmunity.
MSCs have shown great promise in the field of regenerative medicine. While stem cells used as a potential treatment for T1D appear generally safe, the author calls for future in-depth mechanistic studies to overcome the identified scientific and manufacturing hurdles and to better learn how cell therapy can be used to treat – and eventually cure – T1D.
Chronic pain can develop anywhere in the body. It can develop from conditions like arthritis, result from a traumatic injury, or serve as an ongoing symptom of diseases such as cancer or neuropathic pain from diabetes. Often, patients suffering from chronic pain feel their only options for relief are ongoing medications to mask their symptoms or surgery, like a knee replacement to treat chronic knee pain. However, regenerative medicine, also known as stem cell therapy, offers a new option for chronic pain patients to explore that may be especially beneficial for those hoping to avoid surgery. Here we will break down why you should choose regenerative medicine over surgery.
Stem Cell Treatments Have Lower Risks than Surgery
You may want to avoid surgery for many reasons, and the risks of anesthesia and the potential for complications with large incisions are essential factors to consider. Stem cell therapy does not require general anesthesia, and since the process only requires injections, not incisions, there are no surgical wounds or scars.
If you’ve had an adverse reaction to anesthesia or possess risk factors for experiencing a negative response, such as age or a coexisting condition, stem cell therapy offers a non-surgical alternative to finding relief.
Stem Cell Treatments Require Minimal Downtime
Suppose that you lead an active, busy lifestyle. In that case, you probably don’t have time for an extended recovery period, especially when that recovery time keeps you from essential activities like driving or walking.
While most surgeries to alleviate chronic pain require extensive downtime, patients who choose stem cell treatments typically return to work or daily activities within a few days. Although stem cells do take time to heal damaged tissues, many patients begin to experience pain relief within two to three weeks.
Surgery Doesn’t Guarantee Pain Relief
When your chronic pain leads you to the point where you’re willing to undergo surgery, you want to know that the preparation, procedure, downtime, and expense will alleviate your pain. Unfortunately, however, that’s not always the case.
A 2018 study showed that 20% of those who undergo a total knee replacement still live with chronic knee pain. In addition, another study revealed that up to 58% of patients who undergo hip replacement surgery continue to endure persistent pain.
Stem Cell Treatments Are Effective and Non-Invasive
It can be hard to believe that stem cell injections can potentially offer similar, if not better, results than surgery. However, research following patients for two years after their stem cell treatments found all participant groups, regardless of age or BMI, experienced significant pain improvement. Patients who feel surgery is their only option to alleviate chronic pain should ask their doctor about the benefits of pursuing stem cell therapy. If surgery is unavoidable, stem cell therapy can also help post-surgery to help improve healing time and reduce pain. If you would like to choose regenerative medicine over surgery contact Stemedix today!
Mesenchymal stem cells (MSCs) have demonstrated the ability to differentiate into a number of different cells; they also demonstrate immunomodulatory properties that have great potential for use as a stem cell-based therapeutic treatment option and for the treatment of autoimmune diseases – including rheumatoid arthritis (RA).
RA is a chronic and debilitating inflammatory disorder that not only affects the joints, muscles, and tendons, but also damages a number of other body systems, including the eyes, skin, lungs, heart, and blood vessels. It is estimated that roughly 1.5 million Americans are afflicted by RA. While the exact cause of RA is not yet fully understood, the condition is one of over 80 known autoimmune diseases occurring as a result of the immune system mistakenly attacking the body’s own healthy tissue.
Current treatment of RA primarily involves the use of steroids and antirheumatic drugs used primarily to manage associated symptoms of the condition, rather than treat the condition itself. These drugs are also commonly associated with a number of unwanted side effects with users often developing resistance to the medication after prolonged use.
Considering the relative ineffectiveness of drugs designed to treat RA and RA-associated symptoms, scientists have turned to investigate the use of MSC-based therapy as a potential treatment for RA.
As part of this investigation, Sarsenova et al. examined both conventional and modern RA treatment approaches, including MSC-based therapy, by examining the connection between these stem cells and the innate and adaptive immune systems. This review also evaluates recent preclinical and clinical approaches to enhancing the immunoregulatory properties of MSCs.
Through a number of in vitro studies, researchers have realized that MSCs have the ability to inhibit the proliferation of effector memory T cells which, in turn, prevents the proliferation of inflammatory cytokine production. Additionally, these studies have also demonstrated that MSCs are able to modulate functions of the innate immune system by inducting the inflammatory process and activating the adaptive immune system.
Preclinical studies have demonstrated the ability of MSCs to suppress inflammation both through interactions with cells of the immune system and through paracrine mechanisms. This has been demonstrated to be very important as cells of the innate immune system have been shown to have an important role in both the development and progression of RA.
While a number of clinical studies evaluating the effectiveness of MSC-based therapies for the treatment of RA were still ongoing at the time of publication, the nine completed studies primarily demonstrated that using MSCs for the treatment of RA is safe, well tolerated in both the short and long-term, and provides clinical improvements in RA patients.
Despite the many positive and promising outcomes observed through these clinical trials, the authors of this review also point out some limitations associated with the treatment of RA with MSCs. These limitations include many of the referenced studies lacking a placebo control, low enrollment in some studies, and a lack of optimal protocol (for both MSC sourcing and route of administration) for RA treatment with MSCs.
Considering these limitations, Sarsenova et al. point out the need for more well-defined and effective therapeutic windows for the treatment of RA with MSCs, including MSC priming to promote an anti-inflammatory phenotype, in a future study as a way to better understand the perceived benefits of a stem-cell therapy for the treatment of RA and other autoimmune diseases.
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