Living with a spinal cord injury can bring persistent pain, muscle tension, and challenges in daily activities. At Stemedix, we specialize in stem cell therapy for spinal cord injury, offering individualized treatment plans designed to help you manage these symptoms and support your body’s natural repair processes. Our approach uses stem cells for the treatment of spinal cord injury to target inflammation, improve nerve function, and promote neural cell activity. While this therapy does not reverse the injury, it can provide meaningful improvements in circulation, motor control, and muscle strength.
By leveraging stem cell treatment for spinal cord injury, our team helps you explore alternative regenerative options tailored to your specific condition. From reviewing your medical records to developing a personalized therapy plan, we make sure that you receive focused care and support throughout your regenerative medicine journey in Saint Petersburg, FL.
Spinal Cord Injury and Its Link to Chronic Pain
A spinal cord injury can have long-lasting effects on your body, impacting movement, sensation, and daily activities. Chronic pain often becomes a persistent challenge for those living with SCI, affecting quality of life.
What Happens in a Spinal Cord Injury
A spinal cord injury (SCI) disrupts communication between the brain and the body. The spinal cord serves as a critical network that transmits signals controlling movement, sensation, and organ function. When this pathway is damaged, signals may be blocked or misdirected. Patients often experience numbness, weakness, or loss of coordination depending on the injury location. Traumatic events such as motor vehicle accidents, falls, or acts of violence are common causes of SCI.
Types of Spinal Cord Injuries (Complete vs. Incomplete)
Complete injuries cause total loss of sensation and function below the injury site, while incomplete injuries leave some signals intact. For example, a complete cervical injury may result in paralysis of both arms and legs, affecting your ability to perform basic tasks. In contrast, an incomplete thoracic injury may allow partial movement or sensation, letting patients retain some independence in daily activities. Injury classification also influences potential treatment outcomes and how rehabilitation and therapies, including stem cell approaches, may support recovery.
Why Chronic Pain Develops After SCI
Chronic pain develops because damaged nerves send abnormal signals to the brain. After an injury, nerve fibers may misfire, creating ongoing pain sensations even in the absence of an external trigger. In addition, muscle spasms, stiffness, and localized inflammation can worsen discomfort. Individuals with SCI report chronic neuropathic or musculoskeletal pain, underscoring the need for supportive interventions to manage symptoms and improve daily function.
Stem Cell Therapy for Spinal Cord Injury: An Overview
Stem cells for the treatment of spinal cord injury are an option that targets the damaged areas of the spinal cord to improve function and reduce chronic pain. This therapy is designed for patients who already have a confirmed spinal cord injury diagnosis and are exploring regenerative approaches to support recovery.
What Stem Cell Treatment for Spinal Cord Injury Means
Stem cell therapy for spinal cord injury uses regenerative cells to support repair processes in damaged tissue. These cells work by modulating inflammation, helping damaged nerve tissue survive, and supporting the activity of neural cells. Introducing regenerative cells into injured areas may reduce muscle spasms, improve motor function, and promote better communication between the brain and body.
Types of Cells Studied for SCI (Mesenchymal Stem Cells and Neural Cells)
Two cell types often studied in stem cells for the treatment of spinal cord injury are mesenchymal stem cells (MSCs) and neural cells.
Mesenchymal stem cells (MSCs) release growth factors that regulate inflammation and support tissue repair. In patients with spinal cord injury, MSCs have been observed to reduce swelling around damaged nerves and support partial recovery of muscle function. Clinical observations suggest that MSC therapy can lead to measurable improvements in the motor function of patients, depending on the location and severity of the injury.
Neural cells contribute to nerve pathway repair and enhance communication between the spinal cord and brain. By supporting damaged neurons and promoting nerve signaling, neural cells may improve voluntary movement and reduce chronic pain. Early studies indicate that introducing neural cells in injured spinal regions can aid in reestablishing motor and sensory pathways in cases of incomplete injuries.
How Stem Cells May Help Manage Chronic Pain in SCI Patients
Chronic pain after a spinal cord injury affects multiple aspects of your daily life, from mobility to sleep and overall comfort. Stem cell therapy for spinal cord injury offers potential pathways to address these challenges by targeting the underlying cellular processes involved in pain and tissue repair.
Reducing Inflammation and Muscle Spasms
Stem cells may help calm inflammation that contributes to pain and spasticity. Mesenchymal stem cells (MSCs) used in stem cell treatment for spinal cord injury release signaling molecules called cytokines that influence immune activity around damaged nerves. These molecules can lower nerve hyperactivity and ease continuous muscle tension. Patients receiving MSC therapy often report noticeable reductions in spasticity and localized inflammation within weeks of treatment, contributing to less discomfort during movement and rest.
Supporting Nerve Repair and Neural Cell Activity
Stem cells may aid in nerve protection and regeneration. Both MSCs and neural cells in stem cell therapy for spinal cord injury can support damaged neurons, helping them survive and re-establish connections. Improved neuronal connectivity can restore signal transmission between the brain and affected regions of the body. Even partial recovery of nerve function can lead to measurable improvements in motor control and a reduction in neuropathic pain.
Improving Circulation and Motor Function
Stem cells may promote better blood flow to injured tissues. Enhanced circulation helps deliver oxygen and nutrients to areas affected by spinal cord injury, which may decrease discomfort and support voluntary movement. Patients with incomplete injuries often experience improved coordination and mobility after receiving stem cell treatment for spinal cord injury, with some reporting measurable gains in range of motion and functional independence.
Enhancing Muscle Strength and Daily Function
Stem cell treatment may help reduce muscle wasting and weakness. Strengthening muscles that have weakened due to spinal cord injury can decrease the risk of secondary pain caused by compensatory movements. Patients receiving stem cell therapy for spinal cord injury have reported increased control over previously weakened muscles, less stiffness, and greater ease in performing daily tasks such as standing, reaching, or transferring from a wheelchair.
The Patient Experience at Stemedix in Saint Petersburg, FL
Every patient’s journey through regenerative medicine is unique, and the experience at Stemedix is designed to provide clarity and support at every step. From initial contact to treatment completion, the focus is on helping you navigate your spinal cord injury care smoothly.
Treatment for Patients With a Confirmed Diagnosis
We provide regenerative treatments only for patients with confirmed spinal cord injury diagnoses. We do not perform diagnostic tests or imaging; instead, we build therapy plans using the medical records you provide. This approach allows us to concentrate on developing a stem cell therapy plan for spinal cord injury that aligns with your specific condition and history. By focusing on patients who already have a diagnosis, the treatment is tailored to address ongoing symptoms such as chronic pain, muscle tension, and reduced motor function.
Review of Medical Records and Candidacy Process
Patients provide recent scans, MRIs, and lab reports to determine treatment suitability. If your records are older than a year or incomplete, we can coordinate the collection of updated documentation through a simple medical release form. This process allows our physicians to evaluate the information and determine if a personalized stem cell treatment for spinal cord injury plan may benefit your condition. Early patient data indicate that having accurate, current records improves the precision of therapy planning, which may support better management of chronic pain and muscle function.
Personalized Care and Concierge Services
We offer a full-service experience tailored to patient comfort. Your care coordinator arranges travel from the airport, provides mobility aids like wheelchairs, walkers, or shower chairs, and provides accommodations during your stay. This level of support allows you to focus on your treatment without additional logistical concerns. Patients undergoing stem cell therapy for spinal cord injury at Stemedix report that having these services available contributes to a smoother experience and greater adherence to therapy schedules.
Is Stem Cell Therapy Right for You?
Deciding on stem cell therapy for spinal cord injury involves careful consideration of your medical history and current condition. Knowing what the treatment involves and how it may support symptom management can help you take the next step in your care journey.
Who May Qualify for Treatment
Candidates generally have a confirmed spinal cord injury diagnosis and ongoing symptoms. Patients with chronic pain, muscle stiffness, or reduced mobility due to spinal cord injury may explore stem cell treatment for spinal cord injury as a potential option. Medical records, including MRI reports, blood work, and prior imaging, are reviewed to determine suitability. If these records are older than a year, new evaluations may be requested to provide accurate insight.
Carefully selected patients receiving stem cell therapy for spinal cord injury may experience improvements in muscle function, circulation, and a reduction in chronic pain, highlighting the role of targeted regenerative therapy in managing long-term symptoms.
The Role of Care Coordinators in Your Journey
Our Care coordinators guide patients through every step of the process. They assist in gathering and reviewing medical documentation, explain each aspect of the treatment plan, and coordinate travel, accommodations, and equipment if needed. Their role also includes addressing questions about the therapy process, treatment frequency, and expected outcomes.
Coordinators help schedule appointments and communicate with the physician team to tailor the plan to your specific condition. This structured approach helps maintain clarity and support throughout the therapy process.
Begin Your Regenerative Medicine Journey With Stemedix
Take the next step in managing your spinal cord injury with personalized care. Stemedix offers tailored treatments for spinal cord injury in Saint Petersburg, FL, designed around your medical history and current needs. You can speak directly with our care team to discuss your condition, review your medical records, and explore treatment options. Call us today at (727) 456-8968 or email yourjourney@stemedix.com to start your personalized therapy plan.
If you or someone you care about has been diagnosed with a spinal cord injury, you understand how life-altering the challenges can be. At Stemedix, we work with patients who have already received a confirmed diagnosis and are seeking alternative ways to support their recovery goals. While no treatment guarantees a cure, regenerative medicine offers the potential to support healing and reduce the impact of symptoms through biologically active therapies.
Stem cell therapy for spinal cord injury is one such approach that may help promote cellular repair, reduce inflammation, and encourage nerve support. You won’t find exaggerated claims or comparisons here, just realistic, patient-focused information backed by experience. We customize each treatment plan using the documentation you provide, and we support you throughout your journey. This article will walk you through the basics of spinal cord injury, explain how stem cells for the treatment of spinal cord injury are used, and outline what to expect with our process.
What is Spinal Cord Injury?
A spinal cord injury (SCI) is damage to the spinal cord that disrupts communication between the brain and the body. When this pathway is damaged, the body’s ability to send and receive signals becomes impaired. That can mean a loss of movement, sensation, or automatic functions like bladder and bowel control. Most spinal cord injuries happen because of sudden trauma. Studies show that the most common causes of SCI were automobile crashes (31.5%) and falls (25.3%), followed by gunshot wounds (10.4%), motorcycle crashes (6.8%), diving incidents (4.7%), and medical/surgical complications (4.3%).
The spinal cord does not regenerate the way some tissues in the body do. This makes the injury permanent in many cases. The outcome depends on where the injury occurred and how much of the nerve pathway is still intact.
Types and Locations of Spinal Cord Injuries
Spinal cord injury (SCI) is classified by severity, complete or incomplete, and by the spinal region affected. A complete injury results in loss of all movement and sensation below the injury site, while incomplete injuries allow some function. The spinal region involved guides recovery and therapy goals.
Cervical nerve injuries (C1–C8) impact the neck, arms, hands, and breathing, with higher levels possibly requiring ventilation support. Thoracic injuries (T1–T12) affect chest and abdominal muscles, impacting balance and trunk control. Lumbar and sacral injuries (L1–S5) influence leg movement and bladder function, with outcomes varying based on injury extent and completeness.
Common Symptoms and Challenges After SCI
Patients with SCI may experience paralysis, sensory loss, chronic pain, and complications in daily functions. Spinal cord injury affects more than movement. Many patients deal with muscle spasticity, pressure injuries due to immobility, frequent urinary tract infections, and problems with body temperature control. Autonomic dysreflexia, a sudden increase in blood pressure triggered by stimuli below the injury level, is a serious risk in those with injuries at or above T6. Emotional and psychological responses, including anxiety and depression, are also common and require support.
At Stemedix, we recognize that each spinal cord injury is unique. We tailor every treatment plan based on the medical records and information you provide, not generalized assumptions. If you’re exploring stem cells for the treatment of spinal cord injury, our team is ready to walk you through options that align with your health history and functional goals.
What is Regenerative Medicine?
Regenerative medicine supports the body’s repair mechanisms by introducing biologically active materials. This field focuses on helping your body respond to damage by using living cells and biological components. Instead of masking symptoms, regenerative treatments aim to influence the cellular environment that surrounds the injured tissue. In many cases, this includes the use of stem cells and growth factors.
For individuals with a spinal cord injury, regenerative medicine introduces new options that may encourage healing responses the body struggles to activate on its own. While this type of therapy doesn’t replace rehabilitation, it may work alongside your current efforts to promote tissue stability and reduce secondary complications.
Stem Cell Therapy as a Treatment Option for SCI
Stem cell therapy for spinal cord injury is being explored to support recovery and symptom relief. Researchers are investigating how stem cells may influence the biological environment of an injured spinal cord. You won’t find a generalized approach here. Stem cell treatment for spinal cord injury is tailored to each case based on the location of injury, severity, and medical history.
The focus is not on reversing the damage or offering a cure. Instead, stem cells for the treatment of spinal cord injury may help by releasing chemical signals that support the health of nearby nerve cells, protect against further breakdown, and potentially stimulate limited repair processes. Some patients have reported improvements in muscle control, sensation, or bladder regulation, though outcomes vary and remain under study.
How Stem Cells Work to Support Healing
Stem cells can develop into specialized cell types and secrete proteins that support tissue repair. These cells have two key roles in regenerative medicine. First, they can adapt to different cell types, such as those found in the nervous system. Second, and equally important, they release helpful proteins, like cytokines and growth factors, that create a healing-friendly environment. This may reduce chronic inflammation and improve communication between nerve cells that remain intact.
In spinal cord injury cases, these cells may influence glial scar formation, improve blood flow to the damaged region, and protect vulnerable cells from oxidative stress. For example, studies have shown that transplanted mesenchymal stem cells can release brain-derived neurotrophic factor (BDNF), which plays a role in supporting neural survival.
At Stemedix, we offer regenerative therapy based on the existing diagnosis and medical documentation provided by each patient. Our approach respects the experimental nature of this therapy while offering guidance and structure throughout the process.
Potential Benefits of Stem Cell Therapy for Spinal Cord Injury
Exploring the potential benefits of stem cell therapy gives you a chance to learn how regenerative medicine may support certain aspects of your spinal cord injury recovery. While results vary for each individual, many patients report improvements in pain, movement, and physical function over time.
Pain Reduction and Muscle Relaxation
Many patients report decreased neuropathic pain and reduced muscle tension following therapy. Neuropathic pain is one of the most common and challenging symptoms following spinal cord injury. You may experience burning, tingling, or shooting sensations due to misfiring nerves. For some individuals receiving stem cell therapy for spinal cord injury, these symptoms become less intense or more manageable. This could be related to how certain types of stem cells interact with immune cells and inflammatory pathways.
Studies have suggested that mesenchymal stem cells (MSCs), for example, can release bioactive molecules that influence the environment surrounding injured nerves and even interact with neural cells in spine and brain conditions. In some cases, patients also describe less spasticity or tightness in the muscles, which can reduce discomfort during sleep or daily movement.
Improved Circulation and Motor Function
Stem cell treatment for spinal cord injury may support vascular health and contribute to smoother movement. Reduced blood flow after a spinal cord injury can limit your body’s ability to heal or respond to therapy. You might notice cold extremities, swelling, or slower wound healing. Stem cell therapy may support microvascular repair by promoting angiogenesis, the formation of new blood vessels in damaged tissues. This improved circulation helps deliver oxygen and nutrients more efficiently to the affected areas. Some individuals receiving stem cell therapy report smoother joint movement, greater control over posture, and better balance during transfer or mobility tasks.
Increased Muscle Strength and Abilities
Muscle engagement and strength may increase as nerve signals improve. After a spinal cord injury, the connection between your brain and muscles may be disrupted or weakened. Over time, this can lead to muscle wasting or limited control. For individuals receiving stem cell treatment for spinal cord injury, some report noticeable changes in muscle tone, voluntary movement, or strength, especially in the lower limbs or core. These observations tend to occur in cases where some nerve pathways remain intact.
For example, a patient with an incomplete thoracic injury might regain the ability to perform assisted standing exercises or show improvements in hip stability. While not every case leads to increased muscle output, any gains in strength can contribute to mobility training, sitting tolerance, and daily activities.
Patient Experience and Reported Outcomes
Individuals receiving therapy frequently describe improvements in mobility, energy levels, and daily activity. Each patient arrives with unique goals. Some hope to walk again. Others want to reduce fatigue or rely less on medications. After therapy, individuals often share changes that impact their quality of life, such as being able to transfer with less assistance, participate in treatment longer, or sleep more comfortably.
At Stemedix, we focus on your specific history, symptoms, and expectations before building a treatment plan. These outcomes help us communicate realistic possibilities, while always making it clear that regenerative medicine is still considered experimental.
How Stemedix Approaches Stem Cell Therapy for SCI
Every individual with a spinal cord injury has a different medical background and a different journey. That’s why your treatment experience with Stemedix begins with your history, not just your condition.
Customized Treatment Based on Patient History
Stemedix develops treatment plans based on medical records submitted by the patient. If you’ve already received a spinal cord injury diagnosis, our team starts by reviewing the medical documents you send us. This includes imaging studies, physician assessments, and any other relevant details about your injury. By focusing on those who have already completed a diagnostic evaluation, we’re able to provide a more appropriate regenerative therapy experience.
We do not perform physical exams or order MRIs. If your current records are outdated, we can help gather updated information on your behalf once you sign a simple medical release form. This makes sure that our team has the most accurate data to tailor a regenerative approach based on your unique condition, designing therapy around what your body truly needs, not generalized assumptions.
Role of Board-Certified Physicians and Care Coordinators
Each case is reviewed by board-certified physicians experienced in regenerative medicine. When you choose to move forward, your medical information is assessed by physicians who specialize in regenerative therapies. They have experience working with spinal cord injury patients and understand how stem cell therapy may support certain biological functions involved in healing.
Patients are supported by dedicated Care Coordinators who handle logistics, scheduling, and communication. You won’t be left navigating the details alone. Once your evaluation is underway, a Care Coordinator will work closely with you to keep the process on track. This includes walking you through the next steps, answering questions, and helping schedule your treatment. Having one point of contact makes the entire journey easier to follow and less overwhelming.
Patient Support Services and Accommodations
Stemedix offers assistance with travel arrangements, transportation, and medical support equipment. Whether you’re located nearby or traveling across the country, we help remove logistical barriers. Our team can coordinate hotel stays, provide complimentary ground transportation, and arrange for wheelchair-accessible options if needed.
Whether a patient is local or traveling from another state, Stemedix helps coordinate hotels and driver services to make the process more accessible. Your focus should be on preparing for therapy, not stressing over logistics.
Getting Started with Stemedix
How to Connect with a Care Coordinator
Our Care Coordinators are ready to assist you at every step. They can answer your questions, review your medical documents, and guide you through the application process. From your initial inquiry through follow-up care, they provide consistent support to help you understand the next steps in pursuing stem cell therapy for spinal cord injury.
What to Expect During the Treatment Process
Once your case is reviewed and approved by our physicians, you will receive a customized treatment plan with a scheduled date for your therapy. Treatment is provided in a licensed medical facility under the supervision of experienced professionals. After treatment, ongoing follow-up is available to monitor your progress and provide additional support as needed.
Contact Stemedix Today
If you are interested in learning more about stem cell treatment for spinal cord injury, request an information packet today. The team at Stemedix is here to guide you on your journey to better health. Call us at (727) 456-8968 or email yourjourney@stemedix.com to know more.
Living with a spinal cord injury changes how you move, feel, and function every day. You might be searching for more support in your recovery or looking into alternatives when other treatments have plateaued. At Stemedix, we provide access to regenerative medicine options, including stem cell therapy for spinal cord injury, designed to support your body’s healing potential. Our goal is to help you maintain independence and improve your quality of life through individualized care.
Stem cells for the treatment of spinal cord injury are being explored for their ability to support damaged nerve tissues and help reduce symptoms related to mobility, pain, and function. This therapy is not a cure, but it may serve as another layer of support in your recovery process. In this article, we will discuss how spinal cord injuries affect the body and how stem cell treatment may fit into your path forward.
Defining Spinal Cord Injury: Causes and Impact
A spinal cord injury doesn’t just affect mobility—it changes how the entire body communicates, functions, and adapts. Knowing how these injuries happen and what they cause can help you better plan your care and treatment options.
Common Causes of Spinal Cord Injury
A spinal cord injury is most often caused by sudden trauma or underlying medical conditions that disrupt nerve communication within the spine. These injuries commonly follow events such as vehicle crashes, major falls, sports-related impacts, or violent encounters.
Other cases develop from non-traumatic sources. These include conditions like spinal tumors, multiple sclerosis, and certain infections that interfere with the spinal cord’s structure and function. Degenerative diseases—such as spinal stenosis or arthritis—can also contribute to gradual nerve damage over time.
A spinal cord injury disrupts messages between the brain and the rest of the body. Where the injury occurs determines what parts of the body are affected. For example, if damage happens in the cervical spine, it can interfere with both arm and leg function. A lower injury in the lumbar region, by contrast, may impact only the hips and legs.
Immediate and Long-Term Effects on the Body
A spinal cord injury can result in paralysis, loss of sensation, and autonomic system dysfunction. Right after the injury, you might notice loss of movement, reduced feeling in certain areas, or changes in bladder and bowel control. These effects often appear quickly and may be temporary or permanent, depending on the severity.
As time passes, new challenges can appear. You may notice muscle weakness from disuse, skin breakdown from reduced movement, or respiratory changes if the injury is high enough to affect breathing muscles. Pressure injuries, also called pressure sores, and recurrent infections such as urinary tract infections are common secondary complications that require careful management. These long-term impacts highlight the importance of continuous support and well-structured care plans.
Classification of Spinal Cord Injuries by Severity and Location
Knowing where and how a spinal cord injury occurs helps you and your care team decide on the right approach to managing your recovery. The level and type of injury directly impact physical abilities, personal care needs, and long-term health planning.
Complete vs. Partial Injury Overview
A complete spinal cord injury causes total loss of motor and sensory function, while a partial injury retains some level of nerve signal transmission. If you’ve been diagnosed with a complete spinal cord injury, it means there’s no communication between the brain and the body below the injury site. This disconnect leads to full paralysis and loss of sensation below that point.
In contrast, partial, also called incomplete injuries, allow some signals to continue traveling along the spinal cord. You may notice that you still have some sensation, or you may be able to move certain muscles. These residual functions vary greatly between individuals. This classification matters because it plays a role in setting realistic goals for therapy and rehabilitation.
Differences Between Cervical, Thoracic, and Lumbar Injuries
The location of a spinal cord injury determines which parts of the body are affected. Cervical injuries often result in quadriplegia, thoracic injuries affect trunk and leg function, and lumbar injuries primarily impair lower limb control and bowel or bladder management.
Cervical injuries, those in the neck region, are often the most severe. They can impact movement and feeling in all four limbs, including breathing, swallowing, and arm function. These types are the most likely to require long-term assistive devices or full-time care.
Thoracic injuries occur in the middle section of the spine. While they typically spare arm movement, they may limit balance, torso strength, and control over abdominal muscles. It may be harder to sit upright or regulate body temperature below the injury level.
Lumbar injuries involve the lower spine and tend to affect the legs and lower body systems. Many people with lumbar-level injuries retain upper body function, but mobility challenges and changes in bladder or bowel function often follow. This type of injury may still allow for independent movement with the use of braces, walkers, or wheelchairs.
At Stemedix, we review all available medical records to understand your specific injury type and level before recommending any regenerative treatment option. This allows us to align our approach with your needs and current capabilities.
Stem Cell Therapy Explained: Purpose and Methods
Stem cell therapy for spinal cord injury involves introducing regenerative cells to promote repair and protect surviving tissue. These cells are introduced into areas near the injury site, where they may influence several healing processes. One of the primary actions is the regulation of the immune response, which helps reduce further damage caused by ongoing inflammation. In addition, stem cells may release biological signals that support the health of existing nerve cells and encourage the development of new connections within the nervous system.
Types of Stem Cells Used in Therapy
Stem cells for the treatment of spinal cord injury may sometimes include mesenchymal stem cells (MSCs), neural stem cells, and induced pluripotent stem cells (iPSCs). Each type works differently, but MSCs are the most frequently used in current therapeutic models. These cells are typically harvested from bone marrow or adipose (fat) tissue. They’re known for their ability to regulate inflammation and release molecules that promote healing.
Neural stem cells, on the other hand, are more specialized and are under investigation for their ability to integrate into damaged neural circuits. Induced pluripotent stem cells, adult cells reprogrammed into a more flexible, embryonic-like state, are still largely in the research phase. Although they offer broader potential, their use requires rigorous safety protocols to manage risks like tumor formation.
At Stemedix, we focus on therapies that use stem cells for the treatment of spinal cord injury with strong safety records and established handling procedures. Our team works closely with patients and referring physicians to coordinate care that is both informed by current science and centered on individual medical history.
Biological Actions of Stem Cells in Nerve Repair
Stem cells offer more than just cellular replacement—they create conditions in the body that support repair and healing. When applied to spinal cord injury, their effects can influence both immune activity and tissue regeneration.
Influence on Inflammation and Immune Response
Stem cells help regulate immune responses and reduce secondary damage from inflammation. After a spinal cord injury, inflammation can lead to further damage beyond the initial trauma. Immune cells flood the site, often destroying nearby healthy tissue in the process. This secondary damage can be just as limiting as the original injury.
Stem cells interact with this process by releasing bioactive molecules like cytokines and growth factors. These signals tell immune cells to calm their response and shift toward tissue support instead of attack.
This immune-modulating activity helps preserve nerve cells that might otherwise deteriorate. You’re not just adding cells—you’re also working with your body’s existing systems to limit further harm and stabilize the injury site.
Role in Regenerating Damaged Neural Tissue
Stem cell treatment for spinal cord injury may support the formation of new neural connections and repair mechanisms. Spinal cord damage disrupts the flow of signals between your brain and body.
To support repair, stem cells may promote three biological processes: axonal growth, remyelination, and cellular restoration. Axonal growth refers to the extension of nerve fibers that transmit signals. Without axons, communication between nerves stops.
Remyelination involves restoring the protective sheath around nerves, which allows electrical impulses to travel efficiently. In cases of spinal cord injury, this sheath often breaks down, leading to slower or blocked signals.
Studies show that certain types of stem cells, including induced pluripotent stem cells (iPSCs) and MSCs, can release growth factors that encourage axons to regrow and remyelinate existing nerves. These biological effects don’t occur all at once. They build over time as the cells interact with damaged tissue, guiding regeneration step by step.
At Stemedix, we focus on regenerative strategies that support your body’s efforts to recover. Stem cell therapy for spinal cord injury is structured to work with your body, using natural signaling processes to support healing at the cellular level.
Observed Outcomes from Stem Cell Treatments
Many individuals exploring regenerative options want to know what to expect from stem cell therapy. While results can differ, this section outlines some of the most reported effects based on real patient experiences and clinical data.
Enhancements in Mobility and Sensory Recovery
Some patients receiving stem cell treatment for spinal cord injury report improved strength, coordination, and sensation. These outcomes are often influenced by the level and completeness of the injury. For example, individuals with incomplete spinal cord injuries—where the spinal cord is damaged but not fully severed—have demonstrated positive changes in limb control, trunk stability, and tactile feedback following therapy.
Certain patients experienced measurable improvements in motor scores and sensory function within months after receiving stem cell injections. These functional changes, although not universal, suggest that the cells may support the body’s effort to reconnect or reinforce neural pathways.
The timing of intervention also plays a role. People who began stem cell treatment in the sub-acute phase (weeks after injury) have shown different patterns of recovery compared to those in chronic stages. It’s important to consider that early intervention may help maximize the biological environment for healing, but research is still ongoing to determine the full scope of response across timelines.
Reduction of Discomfort and Muscle-Related Symptoms
Stem cells have been observed to reduce spasticity and neuropathic pain associated with spinal cord injury. Spasticity, which causes involuntary muscle contractions, and nerve-related pain are among the most persistent challenges following spinal trauma. These symptoms can disrupt sleep, limit mobility, and interfere with rehabilitation.
Some patients who received mesenchymal stem cell (MSC) therapy reported decreased muscle stiffness and better pain control. Stem cell infusions modulated the immune response and contributed to reduced inflammation around damaged spinal segments. This shift may help explain why pain and tightness sometimes improve after treatment.
Relief from these symptoms can create opportunities for more active daily routines and improved engagement in physical therapy. While stem cell therapy is not a replacement for traditional pain management or rehabilitation, it may complement those approaches in supportive ways.
At Stemedix, we’ve seen that outcomes vary depending on the person’s overall health, injury characteristics, and treatment timing. Our role is to offer access to care designed around your condition while helping you understand how regenerative therapy might fit into your goals for living with a spinal cord injury.
The Treatment Process at Stemedix: Patient-Centered Approach
Every individual with a spinal cord injury presents a unique medical profile. At Stemedix, based in Saint Petersburg, FL, we align the treatment process with your personal health history and therapy goals to support your experience from evaluation through follow-up.
Importance of Diagnostic Information From Referring Physicians
Stemedix requires patients to provide medical imaging and records from their diagnosing physicians to determine eligibility for stem cell therapy. We rely on your existing records—such as MRIs, CT scans, and clinical summaries—to fully understand the scope of your spinal cord injury. This information gives us a starting point to evaluate whether stem cell therapy may be appropriate for your situation.
A detailed medical history helps our team determine the location and severity of your injury while also providing insight into how your body has responded to previous interventions. Accurate documentation from your physician allows us to move forward responsibly and reduce avoidable risks during the treatment process.
Tailoring Treatments to Individual Medical Histories
Each stem cell treatment for spinal cord injury is customized according to the patient’s health condition, injury level, and treatment goals. We look at a range of personal factors before planning treatment. These include the type of spinal cord injury you’ve experienced—whether complete or incomplete—as well as how long it has been since the initial trauma. Conditions like diabetes, autoimmune disorders, or chronic infections, as well as the medications you’re currently using, are all taken into account.
Administration Protocols and Safety Measures
Stemedix uses sterile, clinically guided protocols for administering stem cells. Each procedure is conducted in a controlled medical setting under the direction of trained clinicians. We use laboratory-tested biologics and sterile techniques to lower the risk of complications. All patients are closely observed before, during, and after the procedure.
Throughout treatment, we document patient responses, both for clinical records and to support communication with your existing care team. This consistent monitoring helps track progress and contributes to adjusting your care as needed over time. According to clinical studies, stem cell therapy has been associated with neurological improvements in some individuals with chronic spinal cord injuries, especially when introduced within a defined therapeutic window.
Patient Support Beyond Therapy
Recovery involves more than medical treatment alone. At Stemedix, we understand the physical and logistical challenges you may face when dealing with a spinal cord injury. That’s why we help coordinate accessible transportation and lodging for patients traveling from out of town, easing the burden of planning and focusing attention on your care.
To support your comfort during therapy, we provide access to mobility aids like wheelchairs and walkers, along with personal assistance when needed. Our team creates an accessible environment that allows you to move through treatment with as much comfort and independence as possible.
Start Your Recovery Journey with Stemedix Today
If you’re exploring advanced treatment options for spinal cord injury, our team at Stemedix is here to guide you every step of the way. We offer patient-focused care, treatment coordination, and support services designed around your individual needs. To learn more or speak with a care coordinator, call us at(727) 456-8968 or email yourjourney@stemedix.com.
Multiple sclerosis (MS) is a chronic disease that affects the central nervous system, disrupting the way the brain and spinal cord communicate with the rest of the body. Over the years, researchers have developed many treatments that have transformed the outlook for patients with relapsing-remitting MS (RRMS), the most common form of the disease. Unfortunately, these advances have not been as effective for people with progressive MS (PMS), a form of the condition where symptoms steadily worsen over time without clear periods of recovery.
For patients with PMS, there is still an urgent need for new therapies that do more than slow the disease. Treatments must protect the brain and spinal cord, calm harmful immune responses, and even help repair damage that has already been done. Researchers are exploring innovative ways to meet this challenge, and one of the most exciting possibilities lies in the use of neural stem cells.
In this review, Genchi et al. present the results of STEMS, a prospective, therapeutic exploratory, non-randomized, open-label, single-dose-finding phase 1 clinical trial.
Understanding Neural Stem Cells
Neural stem cells are special cells found in the brain and spinal cord. They can divide and create new cells, and they have the unique ability to develop into different types of brain cells, including neurons, astrocytes, and oligodendrocytes. These cells not only replace damaged tissue but also support the surrounding environment, release helpful molecules, and guide repair processes.
Early research once assumed that stem cell therapy worked only by replacing lost cells. Now, scientists know the story is much more complex. Neural stem cells can remain in an immature state and still have powerful effects. They can interact with the body’s own cells, regulate immune activity, and send out signals that protect nerves from further harm. This “bystander effect” is now seen as one of the most important ways stem cells may help patients with PMS.
The STEMS Clinical Trial
The STEMS trial was the first phase 1 study to test the safety of transplanting human fetal neural precursor cells (hfNPCs) into patients with progressive MS. The cells were delivered directly into the fluid surrounding the spinal cord, a method known as intrathecal injection.
The main goal was safety—primarily, if the treatment could be given without causing serious harm. At the same time, the authors explored whether the cells might show early signs of benefit, such as protecting brain volume or improving certain cognitive functions.
Safety Outcomes of the Trial
The results of this study were encouraging. Over a two-year follow-up period, the authors found no severe side effects directly linked to the transplanted cells were observed. Most side effects were mild or moderate, such as headaches or temporary discomfort.
One patient experienced a relapse of MS symptoms, but this was not thought to be caused by the stem cell therapy. Some patients developed new spots of inflammation on MRI scans, but these were considered part of the natural disease process rather than a direct result of the treatment. Importantly, no evidence suggested that the therapy caused dangerous or uncontrolled growth of cells in the nervous system.
Potential Benefits of Neural Stem Cell Therapy
Although the trial was small and not designed to prove effectiveness, Genchi et al. noticed several promising trends.
Slowing Brain Volume Loss
Brain shrinkage, also known as atrophy, is a hallmark of progressive MS and is strongly linked to worsening disability. In the trial, patients who received higher doses of stem cells showed a slower rate of brain and gray matter shrinkage over two years. This suggests the therapy may have a protective effect on the nervous system.
Cognitive Improvements
Another surprising finding was improvement in a test of processing speed, a measure of how quickly someone can understand and respond to information. While practice effects may have played a role, the fact that patients with worse baseline scores improved the most hints at a real therapeutic effect.
Biological Signals of Repair
Spinal fluid samples taken from patients showed higher levels of certain molecules linked to nerve protection, immune regulation, and tissue repair. For example, increases in growth factors such as GDNF and VEGF-C suggested that the transplanted cells were encouraging the nervous system to heal itself. Other changes hinted at reduced inflammation, which is critical in slowing progression of MS.
The Complex Picture of Inflammation
Not all findings were straightforward. Some patients developed new inflammatory spots on brain scans, even though they did not experience relapses. The authors could not find a clear link between the number of transplanted cells and the amount of new inflammation, but they caution that more work is needed to understand this pattern.
Interestingly, some molecules that are usually considered pro-inflammatory also play roles in nerve repair and stem cell activity. For instance, increases in IL-15 and GM-CSF could be seen as either harmful or helpful depending on context. This highlights how complex the immune system is in MS and why therapies must be carefully studied in larger groups of patients.
Limitations of the Study
While the findings are promising, it is important to keep in mind the limitations. The trial included only a small number of patients and did not have a control group for comparison. The follow-up period of two years may not be long enough to understand the full effects of stem cell therapy, especially since progressive MS changes slowly.
Measures of disability, such as the Expanded Disability Status Scale (EDSS), showed little change. However, this scale is not very sensitive in patients who already have significant disability, and the inclusion criteria may have created bias. Tests of hand function suggested mild worsening, though this was expected given the disease stage.
Significance for Progressive MS
Despite these challenges, the STEMS trial marks an important step forward. For the first time, the authors demonstrated neural stem cells to be safe and well-tolerated when transplanted into patients with PMS. Early signals suggest they may protect the brain, slow shrinkage, and create a more supportive environment for repair.
Progressive MS is notoriously difficult to treat because it involves ongoing nerve loss and scarring, not just inflammation. By targeting multiple processes at once—immunomodulation, neuroprotection, and regeneration—stem cells may offer something no current therapy can.
Looking Ahead: Next Steps in Research
According to the authors, the next step is larger clinical trials that test the therapy in more patients and include control groups for comparison. Researchers will also need to refine dosing, understand how long the transplanted cells survive, and determine whether benefits can be sustained over many years.
Future studies may explore combining stem cell therapy with existing MS treatments to maximize effectiveness. Scientists also hope to learn whether neural stem cells can not only protect the brain but also restore lost function, offering real improvements in quality of life.
A Cautious but Hopeful Outlook
For now, patients with progressive MS should view neural stem cell therapy as an experimental but hopeful avenue. While it is too early to say whether it will become a standard treatment, the early signs suggest that it has the potential to slow progression and improve aspects of brain health.
The STEMS trial demonstrates the importance of moving beyond symptom management and exploring treatments that directly target the mechanisms of neurodegeneration. Neural stem cells could represent a powerful new tool in the fight against progressive MS, but much more research is needed.
Source: Genchi A, Brambilla E, Sangalli F, Radaelli M, Bacigaluppi M, Furlan R, Andolfo A, Drago D, Magagnotti C, Scotti GM, Greco R, Vezzulli P, Ottoboni L, Bonopane M, Capilupo D, Ruffini F, Belotti D, Cabiati B, Cesana S, Matera G, Leocani L, Martinelli V, Moiola L, Vago L, Panina-Bordignon P, Falini A, Ciceri F, Uglietti A, Sormani MP, Comi G, Battaglia MA, Rocca MA, Storelli L, Pagani E, Gaipa G, Martino G. Neural stem cell transplantation in patients with progressive multiple sclerosis: an open-label, phase 1 study. Nat Med. 2023 Jan;29(1):75-85. doi: 10.1038/s41591-022-02097-3. Epub 2023 Jan 9. PMID: 36624312; PMCID: PMC9873560.
Degenerative disc disease (DDD) is one of the most common causes of chronic low back pain. It happens when the spinal discs, which act like cushions between the bones of the spine, begin to wear down over time. This process is often part of normal aging, but it can also be influenced by genetics, lifestyle, injuries, and overall health.
As the discs degenerate, they lose their ability to absorb shock. This can lead to pain, stiffness, and in some cases, additional spinal conditions such as herniated discs, spinal stenosis, or instability between vertebrae. People living with DDD often experience pain that limits daily activities, disrupts sleep, and decreases overall quality of life.
Conventional treatments for DDD usually begin with conservative approaches, such as physical therapy, nonsteroidal anti-inflammatory drugs (NSAIDs), chiropractic care, or acupuncture. For patients whose pain does not improve, surgery may be considered. Surgical options include procedures like spinal fusion or disc replacement. While these approaches can offer short-term relief, they often do not stop the progression of degeneration, and some patients continue to experience pain in the long run.
Because of these challenges, researchers have been looking into new ways to slow or even reverse the disc degeneration process. One of the most promising areas of research involves the use of stem cells—specifically mesenchymal stem cells (MSCs).
As part of this study, Xie et al. evaluate the clinical efficacy and safety of MSC transplantation in patients with DDD.
Why Stem Cells Are Being Studied for DDD
Stem cells are special cells that can develop into many different cell types in the body. Mesenchymal stem cells, or MSCs, are found in bone marrow, adipose tissue, and other areas. They have unique properties that make them attractive for treating degenerative conditions.
MSCs can reduce inflammation, support tissue repair, and even help create new structural material for damaged tissues. In the case of DDD, researchers believe that MSCs could help regenerate spinal discs by:
Reducing inflammation inside the disc
Stimulating the production of new, healthy disc tissue
Improving hydration of the disc, which helps maintain its cushioning ability
Animal studies have shown encouraging results, suggesting that MSC therapy could help preserve disc structure and function. Some early human studies have also suggested potential benefits. However, until recently, clinical evidence was limited and sometimes inconsistent.
To better understand whether MSCs are effective for DDD, the authors of this study performed a meta-analysis—an analysis that combines results from multiple studies to look at the bigger picture.
What the Meta-Analysis Looked At
This study by Xie et al. reviewed randomized controlled trials (RCTs), which are considered one of the most reliable types of clinical research. The researchers looked at trials that compared MSC treatment to standard care or control groups in patients with degenerative disc disease.
They evaluated two main outcomes:
Pain reduction, measured with the Visual Analog Scale (VAS). This tool asks patients to rate their pain on a scale from 0 (no pain) to 10 (worst possible pain).
Functional improvement, measured with the Oswestry Disability Index (ODI). This questionnaire looks at how back pain affects everyday activities like sitting, walking, sleeping, lifting, and social life.
They also reviewed safety outcomes, including whether MSC treatments led to more adverse events compared to control groups.
By combining results from multiple studies, the meta-analysis aimed to answer two important questions:
Does MSC therapy improve pain and function for patients with DDD?
Is MSC therapy safe?
How MSC Therapy Affects Pain
The results of the pooled analysis showed that MSC therapy was associated with significant reductions in pain scores. Patients who received MSC treatment reported lower VAS scores compared to those who did not.
When the authors looked at different time points, they found that MSC therapy reduced pain at 3 months, 6 months, 12 months, and even beyond 24 months. This suggests that the benefits are not just short-term but may continue over time.
Another way the authors measured results was by looking at how many patients achieved “clinically meaningful” pain relief. This means the improvement was large enough to make a real difference in daily life, not just a small statistical change. They found that a higher percentage of MSC-treated patients reached these meaningful improvements compared to control patients.
According to Xie et al., this demonstrates that MSC therapy doesn’t just lower average pain scores on paper—it helps more patients experience relief they can feel.
How MSC Therapy Affects Function
Pain relief is important, but for people with DDD, regaining function is just as critical. The meta-analysis showed that MSC therapy also improved ODI scores, meaning patients could perform daily activities with less difficulty.
The improvements were especially noticeable in longer-term follow-up, at 24 months or more. While shorter-term results (3, 6, and 12 months) showed trends toward improvement, the most significant functional gains appeared over time. This suggests that MSC therapy may take time to have its full effect, as the cells work to repair and stabilize the damaged disc environment.
Like with pain, more patients in the MSC groups achieved meaningful improvements in function compared to those receiving other treatments.
Safety of MSC Therapy
Safety is always a concern with new therapies. MSCs are generally considered low-risk because they do not trigger strong immune responses. In the studies included in this analysis, most patients tolerated MSC therapy well.
The most commonly reported side effects were back pain, joint pain, or muscle spasms—symptoms that were not significantly different between MSC and control groups. However, there was a small but statistically significant increase in treatment-related side effects in the MSC groups. Importantly, serious adverse events were rare and not significantly different between groups.
This means that while MSC therapy appears relatively safe, careful monitoring is still important, and more research is needed to fully understand potential risks.
Clinical Implications for Patients
The results of this meta-analysis suggest that mesenchymal stem cell therapy could offer meaningful benefits for people living with degenerative disc disease. Patients who received MSCs reported:
Reduced back pain over both short- and long-term follow-up
Improved ability to perform daily activities
Relief that was more likely to reach clinically important levels
At the same time, the therapy appeared generally safe, with no major differences in serious adverse events compared to standard treatments.
According to the authors, this makes MSC therapy a promising option for patients who have not found relief through conservative measures and want to avoid or delay surgery. However, it is important to remember that MSC treatment for DDD is still being studied. More large, high-quality clinical trials are needed to answer key questions, such as:
What is the best source of MSCs (bone marrow, fat tissue, or others)?
How many cells are needed for optimal results?
How often should treatments be repeated?
Which patients are most likely to benefit?
Until these questions are answered, MSC therapy should be considered experimental, though the evidence so far is encouraging.
Limitations of the Research
While the meta-analysis strengthens the case for MSC therapy, there are some limitations to keep in mind. The number of studies and patients included was relatively small. Some studies showed inconsistent results, and not all measured outcomes the same way.
In addition, the quality of MSC preparations can vary depending on how cells are collected, processed, and stored. Differences in patient age, health status, and stage of disc degeneration may also affect results.
These factors mean that while the findings are promising, they should be interpreted cautiously until more research is available.
The Future of MSC Therapy for DDD
Research on stem cells and regenerative medicine is moving quickly. MSC therapy represents one of the most exciting frontiers in treating degenerative disc disease because it targets the underlying cause of the condition rather than just managing symptoms.
If ongoing studies continue to show positive results, MSC therapy could become a standard treatment option in the future. It has the potential to provide long-lasting pain relief, restore function, and possibly even slow or reverse the disc degeneration process.
For now, patients interested in stem cell therapy should consult with a qualified healthcare provider to learn whether they may be a candidate for clinical trials or specialized regenerative medicine programs.
As research continues, the authors believe that MSC therapy may become an important option for patients with chronic back pain caused by disc degeneration, helping them move beyond symptom management toward true disc repair and long-term relief.
Source: Xie B, Chen S, Xu Y, Han W, Hu R, Chen M, He R, Ding S. Clinical Efficacy and Safety of Human Mesenchymal Stem Cell Therapy for Degenerative Disc Disease: A Systematic Review and Meta-Analysis of Randomized Controlled Trials. Stem Cells Int. 2021 Sep 13;2021:9149315. doi: 10.1155/2021/9149315. PMID: 34557231; PMCID: PMC8455197.
Rheumatic diseases are a broad group of chronic conditions that affect the joints, muscles, bones, ligaments, and sometimes internal organs. They are usually the result of a malfunctioning immune system that attacks healthy tissues. This leads to inflammation, pain, stiffness, and, in some cases, permanent organ damage. Common conditions in this group include rheumatoid arthritis (RA), systemic lupus erythematosus (SLE), systemic sclerosis (SSc), osteoarthritis (OA), ankylosing spondylitis (AS), and osteoporosis (OP).
These illnesses can significantly reduce a person’s quality of life. Many people face persistent pain, fatigue, and reduced mobility, as well as the emotional challenges of living with a lifelong condition. While current treatments such as anti-inflammatory drugs, immunosuppressants, and biologic medications help manage symptoms, they do not cure the disease. They also come with risks of side effects and may not provide enough relief for everyone.
As part of this review, Hetta et al. summarize the clinical progress of MSC therapy in rheumatic diseases, highlight key findings from preclinical and clinical studies, and discuss challenges and future directions.
Role of Mesenchymal Stem Cell Therapy in Rheumatic Disease Management
Stem cells are unique because they can renew themselves and develop into many different types of cells. Mesenchymal stem cells, or MSCs, are a type of adult stem cell that can be found in bone marrow, fat tissue, umbilical cord blood, and even skin.
MSCs are particularly interesting to researchers because they can transform into bone, cartilage, and adipose cells. They also release natural substances that reduce inflammation, calm the immune system, and support healing. These qualities make them an appealing option for treating autoimmune and inflammatory diseases such as rheumatic conditions.
Why MSCs May Help Rheumatic Diseases
In rheumatic diseases, the immune system mistakenly attacks the body’s own tissues. This sets off cycles of inflammation and damage. MSCs may help by calming the overactive immune response, encouraging the growth of protective immune cells, and releasing growth factors that repair damaged tissues.
Rather than only masking symptoms, MSC therapy aims to restore balance to the immune system and support long-term improvement. This is why it has attracted so much attention in both laboratory research and clinical trials.
Promising Results Across Rheumatic Diseases
According to the authors, research into mesenchymal stem cells (MSCs) has shown encouraging results across a variety of rheumatic diseases where current treatments often fall short. Specifically:
In lupus, MSCs appear to calm harmful immune cells, promote regulatory ones, and reduce kidney inflammation, with early trials showing improvement in patients resistant to standard drugs.
In rheumatoid arthritis, studies suggest MSCs can lower inflammatory signals, protect cartilage, and ease symptoms, particularly in severe cases. Ankylosing spondylitis, which mainly affects the spine, may also benefit from MSC therapy, as both animal and small human studies indicate reduced inflammation and pain.
For osteoarthritis, MSCs may help repair cartilage and ease joint pain, with clinical trials reporting improved function in the knees and hips.
Osteoporosis research shows MSCs may encourage bone-building cells and inhibit bone breakdown, with exosome-based approaches offering a potential “cell-free” treatment.
In systemic sclerosis, MSCs have been linked to reduced scarring and improved skin and organ function.
In rare muscle disorders like dermatomyositis and polymyositis, early studies suggest gains in muscle strength and healing where conventional therapies have failed.
Together, these findings highlight MSCs as a promising new approach across a wide spectrum of autoimmune and degenerative conditions, though more large-scale and long-term studies are needed.
Ongoing Challenges and Emerging Strategies in MSC Therapy
Despite encouraging progress, MSC therapy still faces challenges. Hetta et al. report that results are not consistent, and not every patient responds the same way. The source of MSCs, the number of cells given, and the method of delivery can all affect outcomes.
Another challenge highlighted by the authors is standardization. To move MSC therapy into widespread use, researchers need to agree on best practices for collecting, preparing, and administering these cells.
Future approaches may involve combining MSC therapy with existing medications, engineering MSCs to work more effectively, or using MSC-derived exosomes as a safer alternative to full cell transplantation.
Therapeutic Promise and Future Outlook for Rheumatic Diseases
Mesenchymal stem cells represent one of the most exciting possibilities for treating rheumatic diseases. Research so far shows potential benefits for conditions such as lupus, rheumatoid arthritis, osteoarthritis, osteoporosis, systemic sclerosis, ankylosing spondylitis, and inflammatory muscle diseases. Unlike traditional medications that only ease symptoms, MSCs may help restore immune balance and encourage tissue repair.
While more research is needed to understand the long-term effects and best methods, MSC therapy offers real hope to millions of people living with painful and disabling conditions. With continued progress, the authors believe that it may one day change the way these chronic diseases are treated and give patients new opportunities for healing and improved quality of life.
Source: Hetta HF, Elsaghir A, Sijercic VC, Ahmed AK, Gad SA, Zeleke MS, Alanazi FE, Ramadan YN. Clinical Progress in Mesenchymal Stem Cell Therapy: A Focus on Rheumatic Diseases. Immun Inflamm Dis. 2025 May;13(5):e70189. doi: 10.1002/iid3.70189. PMID: 40353645; PMCID: PMC12067559.
This website and its contents are not intended to treat, cure, diagnose, or prevent any disease. Stemedix, Inc. shall not be held liable for the medical claims made by patient testimonials or videos. They are not to be viewed as a guarantee for each individual. The efficacy for some products presented have not been confirmed by the Food and Drug Administration (FDA).
This website uses cookies to improve your experience while you navigate through the website. Out of these cookies, the cookies that are categorized as necessary are stored on your browser as they are essential for the working of basic functionalities of the website. We also use third-party cookies that help us analyze and understand how you use this website. These cookies will be stored in your browser only with your consent. You also have the option to opt-out of these cookies. But opting out of some of these cookies may have an effect on your browsing experience.
Necessary cookies are absolutely essential for the website to function properly. This category only includes cookies that ensures basic functionalities and security features of the website. These cookies do not store any personal information.
Any cookies that may not be particularly necessary for the website to function and is used specifically to collect user personal data via analytics, ads, other embedded contents are termed as non-necessary cookies. It is mandatory to procure user consent prior to running these cookies on your website.
Subscribe To Our Newsletter
Join our mailing list to receive the latest news and updates from our team.
You have Successfully Subscribed!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
Thanks for your interest!
Request Information Packet
We'll send your FREE information packet that outlines our entire personalized, stress-free stem cell treatment process!
St. Petersburg, Florida
