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Stem Cells. A versatile polypharmacology platform promotes cytoprotection and viability of human pluripotent and differentiated cell
Human pluripotent stem cells (hPSCs) are capable of extensive self-renewal yet remain highly sensitive to environmental perturbations in vitro, posing challenges to their therapeutic use. There is an urgent need to advance strategies that ensure safe and robust long-term growth and functional differentiation of these cells. Here, we deployed high-throughput screening strategies to identify a small-molecule cocktail that improves viability of hPSCs and their differentiated progeny. The combination of chroman 1, emricasan, polyamines, and trans-ISRIB (CEPT) enhanced cell survival of genetically stable hPSCs by simultaneously blocking several stress mechanisms that otherwise compromise cell structure and function. CEPT provided strong improvements for several key applications in stem-cell research, including routine cell passaging, cryopreservation of pluripotent and differentiated cells, embryoid body (EB) and organoid formation, single-cell cloning, and genome editing. Thus, CEPT represents a unique poly-pharmacological strategy for comprehensive cytoprotection, providing a rationale for efficient and safe utilization of hPSCs.
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What You Need To Know About Causes Of Liver Disease?
Liver disease | Hepatitis | Cirrhosis | Fatty liver disease | Liver failure | Liver fibrosis | Alcoholic liver disease | Liver regeneration | Liver stem cells | Best Treatment For Liver Disease | Stem Cell Treatment For Liver Disease | Exosome Therapy | Regenerative Medicine | Stem Cell Therapy Center For Liver | Organ Disease |
There are many different types of liver disease, each with their own unique set of causes. However, there are some commonalities among the various types of liver disease that are worth noting. Firstly, liver disease is often caused by excessive alcohol consumption. This can damage the liver cells and lead to scarring of the organ, known as cirrhosis. Obesity is another major risk factor for developing liver disease, as it can lead to fatty deposits building up in the liver and eventually causing inflammation. Viral infections such as hepatitis C are also a common cause of liver disease and can result in chronic inflammation of the organ.
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#stemcelltherapy#stemcells#regenerativemedicine#liverdisease#chronicliverdisease#advancemedicine#stemcelltreatmentforliverdisease#liverstemcells#livertransplantation#liverfunction#celltherapy#cirrhosis#fattyliver#liverfibrosis#alcoholicliverdisease#beststemcellcenterinindia#specializeg_growt_factor#supsupportive_therapy#exosometherapy#dietconsultant#physiotherapysession
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What is Sciatica?
Stem Cell Therapy for Orthopedic Disorder in India | Affordable, Safe, and Quality Treatment | Stem Cell Therapy For Orthopedic Patients | How Stem Cells Can Help Treat Orthopedic Disorder? | Stem cell therapy for Orthopedic Disorder | Stem Cell Therapy for Osteoarthritis in India |
At Stem Cell Care India, Orthopedic Disease Treatment includes a unique combination of therapies including #stem_cell_therapy, #supportive_therapy, occupational therapy, #specializeg_growt_factor, and multivitamin injection, and #physiotherapy. The duration of treatment is based on the patient’s severity and state and it ranges from 3-4 days.
Orthopedic problems are disorders linked to the musculoskeletal system. They might involve the bones, muscles, cartilage, connective tissues, or joints. Orthopedic problems might be pathological like fracture, dislocation, and tumors; degenerative like osteoarthritis, and osteoporosis, or inflammatory autoimmune disorders like rheumatoid arthritis, gout, systemic lupus erythematosus (SLE). Long-term joint pain, and muscle, or tendon pain can be exasperating. These pains lead to some of the most common musculoskeletal complications and they can be because of strains, sprains, and overuse. The pain is most common on the shoulders, back, knees, hip, and ankles. It might be a worthy idea to seek medical support when the pain takes a bit longer to subside so you can decrease the chances of it developing into a more serious issue.
Orthopedic stem cell treatment deals with anything that is concerned with muscles, ligaments, and joints via stem cells. Any disorders that affect these three portions of the body involve an orthopedic surgeon. Some of these ailments include injuries and sicknesses of the knee, dislocated shoulders, torn cartilages, or foot pain.
To know more about Osteoarthritis and its treatment at Stem Cell Care India, please visit
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#orthopedicstemcelltherapyinIndia#stemcelltherapyforosteoarthritis#orhtopedicdisease#osteoarthritistreatment#stemcells#specializeg_growt_factor#supportive_therapy#beststemcellcenterinindia#stemcelltreatment#exosometherapy#dietconsultant#physiotherapysession#beststemcellhospitalindelhi#orthopedics
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Scientists can grow cardiac tissue in a petri dish using stem cells. The cells self-organize to form microchambers, which begin to beat like a full-sized heart. Recent tissue engineering approaches have provided solutions to issues such as cardiomyocyte immaturity and inability to recapitulate adult heart values for features like contraction force, electrophysiology, or metabolism.
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What Are Stem Cells and How Do They Work?
Want to know what is stem cell therapy and how does it work? Stem cells therapy is a forthcoming and the most progressive treatment alternative; exceedingly accredited by the scientific and also the medical world because of its potential to treat or manage multiplicity of degenerative ailments, which conventionally had no potential antidote.
https://www.globalstemcellcare.com/news/learn-in-detail-what-is-stem-cell-therapy-and-how-does-it-work/
Email id- [email protected] Ph no- +91 82876 76389
#StemCells#StemCellInjection#GlobalStemCellCare#GSCC#stemcelltherapy#cellregeneration#regenerativemedicine#stemcellinjection#exosometherapy#beststemcellceneterinindia#affordableandeffectivetreatment#stemcellhospitalindelhi#Youtube
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Explore how retinal organoids 👁️ derived from human stem cells are revolutionizing the study of retinal degenerative diseases 💡. This Explore how retinal organoids 👁️ derived from human stem cells are revolutionizing the study of retinal degenerative diseases 💡. This breakthrough enables insights into disease pathways, supports drug discovery 💊, and fuels hope for regenerative therapies 🌱—bridging the gap where traditional models fall short. The future of vision science is here! 🚀
World Top Scientists Awards
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Contact us ✉️: [email protected] insights into disease pathways, supports drug discovery 💊, and fuels hope for regenerative therapies 🌱—bridging the gap where traditional models fall short. The future of vision science is here! 🚀 World Top Scientists Awards Visit Our Website 🌐: worldtopscientists.com Nominate Now📝: https://worldtopscientists.com/award-nomination/?ecategory=Awards&rcategory=Awardee Contact us ✉️: [email protected]
#Sciencefather#ResearchAwards#WorldTopScientistsAwards#RetinalOrganoids#StemCells#RDDResearch#VisionScience#Neurodegeneration#DrugDiscovery#PrecisionMedicine#RegenerativeMedicine#Ophthalmology#InVitroModels
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Why Stem Cell Therapy for Fractures Is the Future of Orthopedic Medicine
Medicine changes fast. Really fast. What seemed impossible ten years ago is now routine. But here's something that'll blow your mind: the biggest breakthrough in bone healing isn't coming from some fancy lab equipment or robotic surgery. It's coming from your own body.
Stem cell therapy for fractures isn't just another treatment option. It's a complete game-changer that's about to flip orthopedic medicine on its head. And if you're dealing with a broken bone, you need to know why this matters to you.
The Problem with Traditional Fracture Treatment
Let's be honest about traditional bone healing. It's slow, unpredictable, and sometimes just doesn't work.
Picture this: you break your leg. Your doctor puts it in a cast and says, "See you in eight weeks." Then you wait. And wait. And hope everything heals properly. Sometimes it does. Sometimes it doesn't.
Traditional treatment problems:
Slow healing times (weeks or months)
High failure rates in complex fractures
Chronic pain that never goes away
Limited mobility after healing
Repeated surgeries when things go wrong
It's like fixing a car with duct tape. Sure, it might work. But wouldn't you rather use proper parts?
What Makes Stem Cell Therapy Different?
Stem cell therapy works with your body, not against it. Instead of just hoping your bone heals, you're actively supercharging the healing process.
Think of stem cells as your body's construction crew. When you get injured, they rush to the scene and start rebuilding. But as you age, you have fewer workers available. Stem cell therapy is like calling in extra skilled workers to get the job done faster and better.
How it works:
Extract stem cells from your body
Concentrate them in a lab
Inject them directly into the fracture
Watch accelerated healing happen
Simple concept. Powerful results.
The Science Behind the Revolution
The research is mind-blowing. Studies show stem cell therapy can:
Reduce healing time by 50-70%
Improve bone density at the fracture site
Decrease pain and inflammation
Lower complication rates
Enhance long-term outcomes
Dr. Martinez, a leading orthopedic researcher, puts it this way: "We're not just treating fractures anymore. We're optimizing the entire healing process."
Why Traditional Methods Are Becoming Obsolete
Medicine evolves. Fast. What your grandfather's doctor used is nothing like what's available today. And what's available today will look primitive in ten years.
Old-school thinking:
"Just put it in a cast and wait"
"Surgery is the only option for complex breaks"
"Some bones just won't heal properly"
"Chronic pain is normal after fractures"
New-school reality:
Active healing enhancement is possible
Minimally invasive treatments work better
Every bone can heal with the right approach
Pain-free recovery is the new standard
The Economics of Better Healing
Here's something your insurance company doesn't want you to know: stem cell therapy often costs less than traditional treatment in the long run.
Traditional treatment costs:
Initial surgery: $15,000-$30,000
Physical therapy: $2,000-$5,000
Follow-up surgeries: $10,000-$20,000 each
Lost work time: $5,000-$15,000
Total: $32,000-$70,000
Stem cell therapy costs:
Complete treatment: $3,000-$8,000
Minimal follow-up needed
Faster return to work
Lower complication rates
Total: $3,000-$10,000
The math is simple. Better outcomes cost less.
Real Patients, Real Results
Maria, a 52-year-old nurse, broke her ankle in three places. Doctors said she'd need multiple surgeries and might never walk normally again. She chose stem cell therapy instead.
Eight weeks later? She was back to work. No pain. No limitations. Full recovery.
Tom, a 67-year-old retiree, had a hip fracture that wouldn't heal after six months. Traditional treatment failed. Stem cell therapy succeeded where everything else failed.
These aren't miracle stories. They're becoming the new normal.
The Technology Revolution
Stem cell therapy isn't just about the cells themselves. It's about precision medicine tailored to your specific needs.
Advanced imaging guides doctors to inject cells exactly where they're needed. Genetic testing helps predict how well you'll respond. AI analysis optimizes treatment protocols.
This isn't your grandmother's medicine. This is 21st-century healing.
Why Doctors Are Switching
Smart doctors are embracing stem cell therapy because the results speak for themselves:
Patient satisfaction rates: 85-95% Complication rates: Under 5% Healing times: 50% faster Long-term outcomes: Significantly better
Dr. Johnson, an orthopedic surgeon who switched to stem cell therapy, says: "I can't go back to the old way. My patients deserve better."
The International Advantage
While the US struggles with regulatory delays and insurance limitations, other countries are racing ahead. Mexico, in particular, has become a global leader in stem cell therapy.
Why Mexico leads:
Advanced regulations that encourage innovation
World-class facilities with international standards
Experienced doctors trained globally
Affordable prices without quality compromise
Addressing the Skeptics
Some doctors remain skeptical. They worry about safety and effectiveness. But the evidence keeps piling up.
Safety data shows:
Minimal side effects (less than 2%)
No serious complications in properly conducted treatments
Better safety profile than many traditional treatments
Effectiveness data shows:
Consistent positive outcomes across multiple studies
Superior results compared to traditional methods
Long-term benefits that last years
The Future Is Now
Stem cell therapy for fractures isn't some distant future technology. It's happening right now. Today. While you're reading this.
Current capabilities:
Complex fracture healing in weeks instead of months
Non-union fractures that finally heal
Elderly patients recovering like young adults
Athletes returning to peak performance
Future possibilities:
Instant healing through advanced cell programming
Personalized treatments based on your DNA
Prevention protocols that stop fractures before they happen
What This Means for You
If you're dealing with a fracture, you have a choice. Stick with yesterday's medicine or embrace tomorrow's healing.
Consider stem cell therapy if:
Your fracture isn't healing properly
You want faster recovery
You're an athlete needing quick return
You're older and healing slowly
You want to avoid surgery
The Global Treatment Option
For those seeking cutting-edge stem cell therapy, Mexico offers world-class treatment at accessible prices. Leading clinics provide comprehensive care with international standards.
To explore your options for advanced stem cell therapy, visit stemcellmexico or call (888) 988-0515 to speak with medical coordinators who can provide detailed information about treatment possibilities.
The Tipping Point
We're at a tipping point in orthopedic medicine. Traditional methods are giving way to revolutionary approaches that work better, cost less, and deliver superior outcomes.
The old way:
Break a bone
Hope it heals
Deal with complications
Accept limitations
The new way:
Break a bone
Optimize healing with stem cells
Accelerate recovery
Return to full function
Making the Right Choice
Your bones deserve the best possible care. The future of fracture healing is here. It's proven. It's safe. It's effective.
Don't settle for outdated treatment when breakthrough therapy is available. Don't accept slow healing when fast recovery is possible. Don't choose pain and limitations when full restoration is within reach.
The Revolution Continues
Stem cell therapy for fractures represents more than just a new treatment. It's a fundamental shift in how we think about healing. Instead of accepting what nature gives us, we're enhancing what nature can do.
This is just the beginning. The future of orthopedic medicine is being written right now. It's being written using stem cells.
#StemCellTherapy#BoneHealing#RegenerativeMedicine#OrthopedicMedicine#StemCells#BoneRepair#FractureRecovery#MedicalBreakthrough
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Insect Cell Line Providers in India: Key to Viral Vector and Vaccine Production
Insect cell lines have greatly benefited by the rise of next-gen biologics made of viral vectors and recombinant vaccines because they are now at the center of biotech innovation.
#celllinesuppliers#progenitorcells#cellline#celllineindia#stemcells#stemcellsupplier#insectcellline#insectstemcell#stemcellindia
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The Role of Stem Cells in Aging: Unlocking the Secrets of Regeneration and Longevity
Aging is a universal journey—an intricate tapestry of experiences that shapes who we are, both inside and out. While the outward signs of aging—like wrinkles or slower reflexes—are easy to see, a more profound story unfolds at the microscopic level. At the heart of this story are stem cells—our body’s master repair system.
What Are Stem Cells?
Stem cells are extraordinary. Unlike most cells in our body that have specific roles (such as muscle cells for movement or nerve cells for communication), stem cells are unspecialized but immensely powerful. They have the rare ability to multiply and transform into various types of cells, making them essential for development, maintenance, and repair.
From the moment of conception, stem cells orchestrate the building of our organs, blood, and tissues. Embryonic stem cells can become virtually any cell in the body, while adult stem cells—found in places like bone marrow, skin, and the gut—stand by throughout life to repair damage and regenerate tissue.
Stem Cells and the Aging Process
As we age, stem cells lose some of their regenerative magic. Cuts take longer to heal, muscle strength wanes, and immune responses slow. This decline in stem cell function is a major contributor to aging. But what causes this change?
One critical factor is the stem cell niche—the local environment that surrounds and supports stem cells. This niche provides signals that regulate how stem cells behave. With age, the niche itself becomes less supportive due to inflammation, reduced circulation, and the buildup of waste. As a result, stem cells divide less frequently and become less effective at healing.
Additionally, stem cells accumulate damage over time. Each time a cell divides, errors in DNA replication can occur. Combined with exposure to toxins, radiation, and metabolic stress, these errors build up, causing stem cells to lose their regenerative capacity—or in some cases, begin to malfunction.
Visible Impacts of Stem Cell Decline
The effects of diminishing stem cell activity are evident throughout the body:
Skin: Thinner, less elastic, more prone to wrinkles.
Muscles: Gradual loss of strength and mass, a condition known as sarcopenia.
Blood and immune system: Slower recovery from illness and increased susceptibility to infections.
Brain: Declining neurogenesis may contribute to memory loss and cognitive decline.
Can We Rejuvenate Stem Cells?
Yes—and that’s where things get exciting.
Scientific advances are revealing ways to revive aging stem cells or replace them altogether. Researchers are experimenting with reactivating dormant cells, editing faulty genes, and even transplanting young or engineered stem cells to treat age-related diseases like osteoarthritis, heart failure, and Alzheimer's.
Stem cell science has shifted our view of aging itself—from a one-way decline to a dynamic interplay of damage and repair. With the right interventions, it may be possible to extend not just lifespan, but healthspan—the number of years we live in good health.
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Supporting Stem Cell Health Naturally
While we await more advanced therapies, there are practical steps anyone can take to protect and support their stem cells:
Exercise regularly: Boosts circulation, reduces inflammation, and supports cellular health.
Eat a nutrient-rich diet: Vitamins, minerals, and antioxidants help repair cellular damage.
Avoid toxins: Limit exposure to pollutants, chemicals, and tobacco smoke.
Try intermittent fasting: Some studies suggest it may activate stem cell activity and enhance longevity.
Reduce chronic stress: Stress hormones can impair stem cell niches and reduce their effectiveness.
A Hopeful Future
Stem cell research has revolutionized our understanding of aging. It offers the hope that we can not only slow the march of time but actively enhance the body’s ability to regenerate. Though we still have much to learn, one thing is clear: aging is not just about breakdown, but also about renewal—and stem cells are at the center of that story.
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#StemCells#AntiAging#Regeneration#Longevity#CellularHealth#HealthyAging#ScienceOfAging#Wellness#YouthfulLiving#Dapear#ManishGoswami#Youtube
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CL1: The Biological Computer That Plays Pong with Actual Brain Cells
Greetings folks! Strap in, because this one's not science fiction — it’s science right now. What you’re about to read involves a computer that thinks using actual, living brain cells. Cortical Labs has built a system that doesn’t just simulate intelligence — it is intelligence. Meet CL1: a hybrid of silicon, stem cells, and sheer bioengineering brilliance.
TL;DR:
Cortical Labs built a biological computer using living neurons from stem cells. These neurons live on a chip, respond to stimuli, and learn to play Pong through feedback. No lines of code needed — just raw, biological learning. It’s a new chapter in computing where machines grow brains instead of running on silicon alone.
🧠 So, What Is CL1?
Imagine this: you take living neurons — derived from either human or mouse induced pluripotent stem cells (iPSCs) — and grow them on top of a microchip covered in electrodes. These electrodes can talk to the neurons using electrical pulses.
Now give that system a goal — say, playing Pong — and watch what happens. With no pre-programming, these little neuron networks start to learn, just by reacting to inputs and adjusting over time.
This isn't a simulation. These are real cells doing real-time problem solving. Welcome to the era of wetware.
⚙️ CL1's Technical Side:
Neurons: Human/mouse neurons derived from iPSCs
Interface: Multi-Electrode Array (MEA)
OS: biOS (as base biological operating system)
Feedback Loop: Electrical stimulation + live response tracking
Learning Mechanism: Hebbian plasticity ("neurons that fire together wire together")
🧬 How the Heck Does This Actually Work?
Let’s break it down — both biologically and technically:
👾 The Digital-to-Bio Feedback Loop:
CL1 is a closed-loop system:
The digital system tells the neurons what's happening (e.g., “pong ball moving left”)
Neurons fire back electrical responses
The system interprets those firings
Correct response? They get rewarded. Wrong one? They get a gentle digital slap
Over time, the neuron network self-organizes, learning the task through synaptic plasticity
🧪 The Biology Bit:
The neurons are grown from induced pluripotent stem cells (iPSCs) — adult cells reprogrammed into a stem-cell-like state
These are then developed into cortical neurons
The network grows on a multi-electrode array that can both stimulate and read from the cells
🖥 The Tech Stack:
biOS (Biological Operating System): Simulates digital environments (like Pong) and interprets neural activity in real time
Signal Processing Engine: Converts biological signals into digital responses
Environmental Control: Keeps the neuron dish alive with precise nutrient feeds, CO₂ levels, and temperature management
💡 Why This Is a Huge Freaking Deal
This isn't about playing Pong. It’s about building a new class of machines that learn like we do. That adapt. That grow. This rewires the concept of computing from algorithm-based logic to biological self-organization.
Potential future uses:
Ultra-low-power, self-learning bio-AI chips
Medical models for brain diseases, drug testing, or trauma simulation
Robotic systems that use real neurons for adaptive control
In short: this is the birth of organic computing.
🔮 Can We Upload Knowledge Yet? Like Matrix Style?
Not quite. Right now, CL1 learns via real-time feedback — it’s still trial-and-error. But researchers are exploring:
Pre-conditioning neural responses
Chemical memory injection
Patterned stimulation to train in behaviors
In the future? We might literally write instincts into neural systems like flashing a bootloader. One day, your drone might come preloaded with lizard-brain reflexes — not software, but neurons.
🧱 What Comes Next?
We’re at the beginning of something radical:
Neural prosthetics with muscle memory
Bio-computers that can evolve new solutions on their own
Robots that aren’t just “smart” — they’re alive-ish
CL1 is laying the foundation for a new kind of intelligence — not modeled after the brain, but actually made of one.
🔗 Sources:
Cortical Labs Official
Nature Article
The Verge Feature
ABC Science News
MIT Tech Review
Neuron Journal Study
#CL1#BiologicalComputing#Neurotech#CorticalLabs#LivingAI#iPSC#BrainComputerInterface#SyntheticBiology#Wetware#Futurism#BioAI#StemCells#Neuroscience#NextGenComputing#MEAtechnology#HumanNeuronAI#Biocomputing#TechFutures#PostSiliconEra#PongBrain#cyberpunk#technology
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Abstract Peripheral nerve injury (PNI) is a relevant biomedical problem, especially in wartime, given the high frequency of such injuries. Bioengineering means for rehabilitative treatment of PNI are considered the most promising, among which the effect of stem cell transplantation into the subarachnoid space on the process of plastic reconstruction of the nervous system in the context of PNI is the least studied. In this study, we investigated the effect of delayed transplantation of two types of human stromal multipotent stem cells into the cisterna magna on the restoration of the functional index of the sciatic nerve (sciatic functional index, SFI) after its transection and immediate epineural suturing in adult rats. The obtained data indicate that delayed intrathecal xenotransplantation of dermal multipotent stromal stem cells or multipotent mesenchymal stem cells, derived from the wall of umbilical artery, performed 2 weeks postinjury, leads to a significant increase in SFI after 2.5 months of observation. In the case of umbilical artery-derived stem cells’ injection, this result is significantly higher than the result of sciatic nerve suturing without the procedure of cell transplantation.
#peripheralnerveinjury#restorativeneurosurgery#stromalmultipotentstemcells#intrathecalcelltransplantation#sciaticfunctionalindex#stemcells
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Cerebral Palsy & Developmental Delay: A Parent’s Attendant Review After Stem Cell Therapy |
PRESENTING ILLNESS:
A 17 years 10 months old female with a history of Cerebral palsy, diplegia, and developmental delay. Multiple Hospital consults were taken. Medical management is going on in consultation with the Physician. Physiotherapy is going on a regular basis. Her father and mother wish her to undergo Stem cell therapy (Umbilical cord-derived Mesenchymal Stem cells ) for her problem.
Email id- [email protected] Ph no- +91 9650760803
https://www.viezec.com/diseases/neuro/cerebral-palsy-stem-cell-treatment-india/
#StemCells#CerebralPalsy#DevelopmentalDelay#MedicalBreakthrough#RegenerativeMedicine#Exosomes#ViezecMedicalTourism#CPTreatment#NeurodevelopmentalDisorders#BrainHealth#MedicalTourismIndia#StemCellResearch#AdvancedMedicine#NeuroDisorders#MotorDisorders#FutureOfMedicine#CellBasedTherapy#CPRecovery#HopeForCP#StemCellSuccess#CPAwareness#ChildDevelopmentSupport#CellRegeneration#HealingWithStemCells#Youtube
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Is stem cell therapy the same as stem cell transplant?
Wondering if stem cell therapy and stem cell transplant are the same? You're not alone! In this video, we break down the key differences between these two advanced medical approaches:
🧬 Stem Cell Therapy: Purpose: Primarily used in regenerative medicine to repair or replace damaged tissues or organs.
Stem Cells Used: Often uses mesenchymal stem cells (MSCs) derived from bone marrow, fat, or umbilical cord.
🧬 Stem Cell Transplant (also called Bone Marrow Transplant): Purpose: Replaces damaged or destroyed bone marrow with healthy stem cells, usually for blood-related conditions.
Stem Cells Used: Uses hematopoietic stem cells (HSCs) from bone marrow, peripheral blood, or umbilical cord blood.
https://www.stemcellcareindia.com/stem-cell-therapy/
#StemCellTherapy#StemCellTransplant#RegenerativeMedicine#BoneMarrowTransplant#FutureOfMedicine#StemCells#AdvancedTherapies#StemCellTreatment#StemCellCareIndia#SCCI#Youtube
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I have already started to record my activities in subtle ways but I keep loosing track of where I keep these documentation. So I’d rather keep a journal to account for all of my things including my reflective thinking and next steps forward.
I have realised keeping track of my feelings, thoughts (when I keep myself in check) the things around me run a lot more smoothly than when I’m hot and bothered about not saying something or not remembering something.
So turning to journal writing again seems like the right thing to do.
Journaling is probably the wrong term I’m using maybe “blogging” would fit my current context but I am also planning to run this along side my instagram account only because there’s a different level of technology that each app carries and either each app comes a different beauty.
I hope to stay consistent in these apps because I have a 50/50 relationship with constantly being on my phone (insta) which I’ve negatively associated in my mind. So I have to reverse the though get into good habits and start forward thinking again about being on my phone (this time with a purpose).
Demystifying science was the start and end of my website gixntjelly. I had my fun while the website lasted but I am engaged in science communication, still, but more focussed within my masters and what’s in my area of interest. So you will find science content and videos and blogs of any creative projects that I am currently working on.
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Stem Cell Therapy: Uses, Benefits, and Conditions Treated |
One unique kind of cell with two crucial characteristics is stem cells. They can produce additional cells just like themselves. That is to say, they self-renew. They may undergo a differentiation process to transform into other cells for various purposes. Nearly every tissue in the body has stem cells. They are also required for tissue upkeep and healing after damage.
Where the stem cells are determines whether they grow into specific tissues. Hemopoietic stem cells, for instance, live in the bone marrow and can generate every kind of cell needed in blood. Stem cells may also develop brain cells, heart muscle cells, bone cells, or other cells.
https://globalregenex.com/what-is-stem-cell-therapy-used-for/
Email id- [email protected] Ph no- +91 7827791242
#StemCellTherapy#RegenerativeMedicine#GlobalRegenex#CellTherapy#FutureOfMedicine#StemCells#AdvancedTreatment#JointPainRelief#SpinalCordInjury#ArthritisTreatment#NeurologicalDisorders#EyeDisorders#HeartDiseaseTreatment#ChronicPainRelief#MedicalInnovation#Youtube
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Christoph Muth – Fighting a Rare and Devastating Neurological Disorder
Christoph Muth from Duisburg, Germany, is battling a rare and medically complex multisystem neurological disorder triggered by a medication switch from Escitalopram to Duloxetine. Since then, he has been suffering from a progressive Post-Acute Withdrawal Syndrome (PAWS) with severe sensorimotor, autonomic, and central nervous system disturbances — a condition barely documented worldwide.
Medically confirmed findings include:
Small fiber neuropathy
Autonomic nervous system dysfunction
NMDA receptor antibodies (suggesting autoimmune encephalitis)
Cerebellar and cortical changes
Pronounced neuroimmunological reactions
Multiple antibody processes now active simultaneously
Despite numerous outpatient treatment attempts — including one in Switzerland and others in North Rhine-Westphalia — no lasting stabilization has been achieved. The condition continues to worsen. Further inpatient treatments are currently being prepared. Some therapeutic protocols, such as EECP, advanced infusion programs, or stem cell approaches, need to be repeated and expanded. Many of these are not covered by health insurance.
Christoph urgently needs financial support to continue these innovative approaches in neuroregeneration.
SAT.1 NRW has already reported on his case. Still, broader public awareness, medical networking, and donation support are desperately needed for Christoph and others facing ultra-rare neuroimmunological diseases.
More information and the donation campaign can be found here:
https://gofund.me/e20cae20
www.chrisbacktolife.com
#RareDisease#NeurologicalDisorder#AutoimmuneEncephalitis#PAWS#SmallFiberNeuropathy#MedicalHelp#Neuroinflammation#NMDAreceptor#MultisystemDisorder#StemCells#InfusionTherapy#EECP#DisabilityAwareness#HealthJustice#ChrisBackToLife
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