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The global market for Nerve Repair and Regeneration is projected to reach US$12.7 billion by 2025 – GlobeNewswire

By Stem Cell Treatment

September 29, 2020 02:35 ET | Source: ReportLinker

New York, Sept. 29, 2020 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Global Nerve Repair and Regeneration Devices Industry" - https://www.reportlinker.com/p05957490/?utm_source=GNW Nerves constitute the most significant cable systems in the human body, performing the crucial job of carrying messages and information to brain and also to other parts of body. Whenever such critical nerves are injured, problems arise in muscles leading to sensation loss. Major types of nerve injuries include Neuropraxia, the physiologic blocking of nerve; Axonotmesis, the anatomic disruption of axon with slight disruption of connective tissue; and Neurotmesis, the anatomic disruption of connective tissue and nerve fibers.These injuries could result in trauma or more serious neurodegenerative diseases such as Parkinson`s disease, Alzheimer`s disease, multiple system atrophy, multiple sclerosis, and amyotrophic lateral sclerosis (ALS), also known as Lou Gehrig`s disease).Alzheimer`s, Parkinson`s, Amyotrophic Lateral Sclerosis and multiple sclerosis are diseases that cause injury to the complex, delicate structures of the nervous system.Till date spinal cord injury and peripheral nerve damage are often permanent and incapacitating.

Innovative strategies are required for a shift in the paradigm and advanced treatment of these neurological injuries.But the question as to whether adult neurogenesis isrealstill remains unanswered with several contentious research studies still underway with no definitive answer to this century-long debate. Regrowth or repair of nervous tissues and cells involves generation of new neurons, glia, axons, myelin, or synapses.Gene Therapy is attracting immense research investments for its promise in promoting nerve regeneration and intraneural revascularization is being studied for its role in peripheral nerve regeneration.Newer studies are however dampening hopes by stating that adults produce no new cells in the hippocampus. Nevertheless, hopes of regeneration arecreating lucrative commercial opportunities as the pressure builds for newer and more effective treatment for neurological diseases.As the world awaits for a paradigm-shift in the treatment of neurological injury, neurostimulation and neuromodulation devices and biomaterials remains a massive multi billiondollar market worldwide. Neurostimulation and neuromodulation devices are currently available solutions to treat a variety of nerve injuries including peripheral nerve injuries. Neurostimulation and neuromodulation methods involve use of specially designed devices to transmit electrical impulses for controlling activity of the central nervous system and the brain.Internal neurostimulation and neuromodulation devices are growing in popularity for their significantly lower risk for post-surgical complications and shorter hospital stays. These include deep brain stimulation (DBS)for Parkinson`s, epilepsy and depression; spinal cord stimulation (SCS) for pain management and spasticity; gastric electrical stimulation (GES) for obesity and gastroparesis; vagus nerve stimulation (VNS) for depression and epilepsy; and sacral nerve stimulation (SNS) for constipation and urinary incontinence disorders.External neurostimulation devices, on the other hand, comprise transcutaneous vagus nerve stimulation (TVNS) for autism, depression, anxiety and age related disorders; transcutaneous electrical nerve stimulation (TENS)for chronic neuropathic pain and fibromyalgia disorders; transcranial magnetic stimulation (TMS)for depression and ADHD; and respiratory electrical stimulation (RES) for improving the respiratory function after spinal cord injury.

Read the full report: https://www.reportlinker.com/p05957490/?utm_source=GNW

I. INTRODUCTION, METHODOLOGY & REPORT SCOPE

II. EXECUTIVE SUMMARY

1. GLOBAL MARKET OVERVIEW Nerve Repair and Regeneration Market Set for a Rapid Growth Neurostimulation and Neuromodulation Devices: Largest Product Segment Biomaterials to Exhibit Rapid Growth Nerve Repair and Regeneration Market by Application US and Europe Dominate the Market, Asia-Pacific to Register the Fastest Growth

2. FOCUS ON SELECT PLAYERS Abbott Laboratories, Inc. (USA) AxoGen, Inc. (USA) Boston Scientific Corporation (USA) Integra LifeSciences Corporation (USA) LivaNova, PLC (UK) Medtronic plc (USA) NeuroPace, Inc. (USA) Nevro Corporation.(USA) Orthomed S.A.S. (France) Polyganics B.V. (The Netherlands) Stryker Corporation (U.S.) Synapse Biomedical Inc. (U.S.)

3. MARKET TRENDS & DRIVERS High Incidence of Brain Disorders and Nerve Injuries: Primary Market Driver Annual Incidence of Adult-Onset Neurologic Disorders in the US Symptomatic Epilepsy Incidence by Type (2019): Percentage Share Breakdown of Congenital, Degenerative, Infective, Neoplastic, Trauma, and Vascular Epilepsy Global Alzheimers Prevalence by Age Group Diagnosed Prevalence Cases of Parkinson?s Disease Across Select Countries Classification of Nerve Injuries Recent Developments in Spinal Cord Injury Treatment Rising Geriatric Population and Subsequent Growth in Prevalence Of Neurological Disorders Global Population Statistics for the 65+ Age Group in Million by Geographic Region for the Years 2019, 2025, 2035 and 2050 Intensified Research Activity Across Various Neural Disciplines Induces Additional Optimism Stem Cell Therapy: A Promising Avenue for Nerve Repair and Regeneration New Biomaterials Pave the Way for Innovative Neurodegeneration Therapies Role of Nerve Conduits in the Treatment of Peripheral Nerve Injury Innovative Nerve Conduits from Stryker Technological Advancements and Product Innovations - A Key Growth Driver Neurostimulation Allows Paralyzed People to Regain Leg Movement Neurostimulator to Treat Neurological Conditions Micro-Implantable Solution for Neurostimulation Parasym? Device for Neurostimulation Boston Scientific?s Spinal Cord Stimulation Improves Quality of Life Intellis? Platform Presents Smallest Implantable Neurostimulator Innovation in Deep Brain Stimulation for Parkinson?s Disease Innovations in Spinal Cord Stimulation for Pain Smart Neuromodulation: The Combination of AI and Neuromodulation Technologies New Dynamic Lead Interface Design for Neurostimulator Devices Wireless SCS Neuromodulation Therapy: An Alternative to Traditional SCS System Select Recent Approvals of Neuro-stimulation and Neuromodulation Devices Select Launches in Spinal Cord Stimulation (SCS) Market Select Launches in Deep Brain Stimulation (DBS) Market Select Neurostimulation Devices in Clinical Trials Select Neuromodulation Devices in Clinical Trials

4. GLOBAL MARKET PERSPECTIVE Table 1: World Current & Future Analysis for Nerve Repair and Regeneration Devices by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 2: World Historic Review for Nerve Repair and Regeneration Devices by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 3: World 15-Year Perspective for Nerve Repair and Regeneration Devices by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets for Years 2012, 2020 & 2027

Table 4: World Current & Future Analysis for Neurostimulation & Neuromodulation Devices by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 5: World Historic Review for Neurostimulation & Neuromodulation Devices by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 6: World 15-Year Perspective for Neurostimulation & Neuromodulation Devices by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

Table 7: World Current & Future Analysis for Biomaterials by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 8: World Historic Review for Biomaterials by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 9: World 15-Year Perspective for Biomaterials by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

Table 10: World Current & Future Analysis for Neurostimulation & Neuromodulation Surgeries by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 11: World Historic Review for Neurostimulation & Neuromodulation Surgeries by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 12: World 15-Year Perspective for Neurostimulation & Neuromodulation Surgeries by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

Table 13: World Current & Future Analysis for Neurorrhaphy by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 14: World Historic Review for Neurorrhaphy by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 15: World 15-Year Perspective for Neurorrhaphy by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

Table 16: World Current & Future Analysis for Nerve Grafting by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 17: World Historic Review for Nerve Grafting by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 18: World 15-Year Perspective for Nerve Grafting by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

Table 19: World Current & Future Analysis for Stem Cell Therapy by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 20: World Historic Review for Stem Cell Therapy by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 21: World 15-Year Perspective for Stem Cell Therapy by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

Table 22: World Current & Future Analysis for Hospitals & Clinics by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 23: World Historic Review for Hospitals & Clinics by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 24: World 15-Year Perspective for Hospitals & Clinics by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

Table 25: World Current & Future Analysis for Ambulatory Surgery Centers by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 26: World Historic Review for Ambulatory Surgery Centers by Geographic Region - USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 27: World 15-Year Perspective for Ambulatory Surgery Centers by Geographic Region - Percentage Breakdown of Value Sales for USA, Canada, Japan, China, Europe, Asia-Pacific, Latin America, Middle East and Africa for Years 2012, 2020 & 2027

III. MARKET ANALYSIS

GEOGRAPHIC MARKET ANALYSIS

UNITED STATES Table 28: USA Current & Future Analysis for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 29: USA Historic Review for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 30: USA 15-Year Perspective for Nerve Repair and Regeneration Devices by Product - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Devices and Biomaterials for the Years 2012, 2020 & 2027

Table 31: USA Current & Future Analysis for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 32: USA Historic Review for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 33: USA 15-Year Perspective for Nerve Repair and Regeneration Devices by Application - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy for the Years 2012, 2020 & 2027

Table 34: USA Current & Future Analysis for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 35: USA Historic Review for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 36: USA 15-Year Perspective for Nerve Repair and Regeneration Devices by End-Use - Percentage Breakdown of Value Sales for Hospitals & Clinics and Ambulatory Surgery Centers for the Years 2012, 2020 & 2027

CANADA Table 37: Canada Current & Future Analysis for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 38: Canada Historic Review for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 39: Canada 15-Year Perspective for Nerve Repair and Regeneration Devices by Product - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Devices and Biomaterials for the Years 2012, 2020 & 2027

Table 40: Canada Current & Future Analysis for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 41: Canada Historic Review for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 42: Canada 15-Year Perspective for Nerve Repair and Regeneration Devices by Application - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy for the Years 2012, 2020 & 2027

Table 43: Canada Current & Future Analysis for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 44: Canada Historic Review for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 45: Canada 15-Year Perspective for Nerve Repair and Regeneration Devices by End-Use - Percentage Breakdown of Value Sales for Hospitals & Clinics and Ambulatory Surgery Centers for the Years 2012, 2020 & 2027

JAPAN Table 46: Japan Current & Future Analysis for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 47: Japan Historic Review for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 48: Japan 15-Year Perspective for Nerve Repair and Regeneration Devices by Product - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Devices and Biomaterials for the Years 2012, 2020 & 2027

Table 49: Japan Current & Future Analysis for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 50: Japan Historic Review for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 51: Japan 15-Year Perspective for Nerve Repair and Regeneration Devices by Application - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy for the Years 2012, 2020 & 2027

Table 52: Japan Current & Future Analysis for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 53: Japan Historic Review for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 54: Japan 15-Year Perspective for Nerve Repair and Regeneration Devices by End-Use - Percentage Breakdown of Value Sales for Hospitals & Clinics and Ambulatory Surgery Centers for the Years 2012, 2020 & 2027

CHINA Table 55: China Current & Future Analysis for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 56: China Historic Review for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 57: China 15-Year Perspective for Nerve Repair and Regeneration Devices by Product - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Devices and Biomaterials for the Years 2012, 2020 & 2027

Table 58: China Current & Future Analysis for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 59: China Historic Review for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 60: China 15-Year Perspective for Nerve Repair and Regeneration Devices by Application - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy for the Years 2012, 2020 & 2027

Table 61: China Current & Future Analysis for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 62: China Historic Review for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 63: China 15-Year Perspective for Nerve Repair and Regeneration Devices by End-Use - Percentage Breakdown of Value Sales for Hospitals & Clinics and Ambulatory Surgery Centers for the Years 2012, 2020 & 2027

EUROPE Table 64: Europe Current & Future Analysis for Nerve Repair and Regeneration Devices by Geographic Region - France, Germany, Italy, UK, Spain, Russia and Rest of Europe Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2020 through 2027

Table 65: Europe Historic Review for Nerve Repair and Regeneration Devices by Geographic Region - France, Germany, Italy, UK, Spain, Russia and Rest of Europe Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 66: Europe 15-Year Perspective for Nerve Repair and Regeneration Devices by Geographic Region - Percentage Breakdown of Value Sales for France, Germany, Italy, UK, Spain, Russia and Rest of Europe Markets for Years 2012, 2020 & 2027

Table 67: Europe Current & Future Analysis for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 68: Europe Historic Review for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 69: Europe 15-Year Perspective for Nerve Repair and Regeneration Devices by Product - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Devices and Biomaterials for the Years 2012, 2020 & 2027

Table 70: Europe Current & Future Analysis for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 71: Europe Historic Review for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 72: Europe 15-Year Perspective for Nerve Repair and Regeneration Devices by Application - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy for the Years 2012, 2020 & 2027

Table 73: Europe Current & Future Analysis for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 74: Europe Historic Review for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 75: Europe 15-Year Perspective for Nerve Repair and Regeneration Devices by End-Use - Percentage Breakdown of Value Sales for Hospitals & Clinics and Ambulatory Surgery Centers for the Years 2012, 2020 & 2027

FRANCE Table 76: France Current & Future Analysis for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 77: France Historic Review for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 78: France 15-Year Perspective for Nerve Repair and Regeneration Devices by Product - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Devices and Biomaterials for the Years 2012, 2020 & 2027

Table 79: France Current & Future Analysis for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 80: France Historic Review for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 81: France 15-Year Perspective for Nerve Repair and Regeneration Devices by Application - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy for the Years 2012, 2020 & 2027

Table 82: France Current & Future Analysis for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 83: France Historic Review for Nerve Repair and Regeneration Devices by End-Use - Hospitals & Clinics and Ambulatory Surgery Centers Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 84: France 15-Year Perspective for Nerve Repair and Regeneration Devices by End-Use - Percentage Breakdown of Value Sales for Hospitals & Clinics and Ambulatory Surgery Centers for the Years 2012, 2020 & 2027

GERMANY Table 85: Germany Current & Future Analysis for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 86: Germany Historic Review for Nerve Repair and Regeneration Devices by Product - Neurostimulation & Neuromodulation Devices and Biomaterials Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Table 87: Germany 15-Year Perspective for Nerve Repair and Regeneration Devices by Product - Percentage Breakdown of Value Sales for Neurostimulation & Neuromodulation Devices and Biomaterials for the Years 2012, 2020 & 2027

Table 88: Germany Current & Future Analysis for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy - Independent Analysis of Annual Sales in US$ Billion for the Years 2020 through 2027

Table 89: Germany Historic Review for Nerve Repair and Regeneration Devices by Application - Neurostimulation & Neuromodulation Surgeries, Neurorrhaphy, Nerve Grafting and Stem Cell Therapy Markets - Independent Analysis of Annual Sales in US$ Billion for Years 2012 through 2019

Here is the original post:
The global market for Nerve Repair and Regeneration is projected to reach US$12.7 billion by 2025 - GlobeNewswire

Stem Cell Market By Applications, Types, New Technology Opportunity Analysis And Forecast: 2020 2028 – The Daily Chronicle

By Stem Cell Treatment

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Global Cell Freezing Media for Cell Therapy Market by Type: With FBS, Without FBS

Global Cell Freezing Media for Cell Therapy Market by Application: Human Embryonic Stem Cells, CAR-T Cell Therapy, Neural Stem Cell Therapy, Mesenchymal Stem Cell Therapy, Hematopoietic Stem Cell Transplantation, Others

Players can use the report to gain sound understanding of the growth trend of important segments of the global Cell Freezing Media for Cell Therapy market. The report offers separate analysis of product type and application segments of the global Cell Freezing Media for Cell Therapy market. Each segment is studied in great detail to provide a clear and thorough analysis of its market growth, future growth potential, growth rate, growth drivers, and other key factors. The segmental analysis offered in the report will help players to discover rewarding growth pockets of the global Cell Freezing Media for Cell Therapy market and gain a competitive advantage over their opponents.

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Cell Freezing Media for Cell Therapy Market Development Factors and Investment Analysis by Leading Manufacturers: BioLife Solutions, Thermo Fisher...

2020 Global Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) Market Competitive Research, Top Companies, Key Types, Revenue, Share, Size…

By Stem Cell Treatment

"The niche and established Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) Market 2020 Covering Prime Players, Regions, Countries, And Growth Trends Forecast To 2026 is studied in this research report. The Industry dynamics with Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) future-proofing business plans are analyzed to offer sustainable growth for our clients. The insights-driven data covering the Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) competition, product demand across different operating regions, countries, and a variety of applications are covered. Actionable insights offered by Reports Check will help achieve you in achieving exemplary growth with feasible investments. To strengthen the position in the global and domestic Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) Market revenue, size & share analysis, import-export details, production capacity, and utilization ratio is offered.

Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) Market is expected to reach XX.XX Mn USD by 2026 and it will capture lucrative opportunities with rising demand. The market dynamics, SWOT analysis, Porters Analysis, the risk assessment will create discerning growth and profit-driven strategies. Reports Checks analyst team is fine-tuned to answer all client queries and well as to deliver custom solutions based on their requirements.

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Study Period: 2015-2026

Base Year: 2019

Estimated Year With COVID-19 Impact Analysis:2020

Forecast Period Duration:2020-2026

Historical Period Duration:2015-2018

Important and Top Product Types:

CellSearch Others

By Various Applications:

Breast Cancer Diagnosis and Treatment Prostate Cancer Diagnosis and Treatment Colorectal Cancer Diagnosis and Treatment Lung Cancer Diagnosis and Treatment Other Cancers Diagnosis and Treatment

By Top Companies On Global, Regional And Country Level:

Janssen Qiagen Advanced Cell Diagnostics ApoCell Biofluidica Clearbridge Biomedics CytoTrack Celsee Fluxion Gilupi Cynvenio On-chip YZY Bio BioView Fluidigm Ikonisys AdnaGen IVDiagnostics Miltenyi Biotec ScreenCell Silicon Biosystems

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The current Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) Market landscape, detailed insights, and market drivers with restraints and trends are studied in this report. The detailed market performance during the forecast period is presented in this report. The Y-o-Y growth and CAGR is presented in this report to support the readers in making appropriate business plans. The quantitative development opportunities and innovations in Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) Industry are presented.

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All the above queries are effectively addressed by the analyst team of Reportscheck.com. Also, custom reports are available based on the client's requirements. Analyst views and opinions about the Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) industry with qualitative and quantitative inputs will lead to sound business plans. The investment feasibility check, the latest innovations, developments, raw materials, and Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) consumer demand analysis is conducted. The competitive dashboard reflects the top companies' analysis, growth rate, revenue, market share, product portfolio, and the latest developments.

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Past, present, and forecast Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) industry evaluation with complete performance monitoring of top players,.

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2020 Global Circulating Tumor Cells (CTCs) and Cancer Stem Cells (CSCs) Market Competitive Research, Top Companies, Key Types, Revenue, Share, Size...

Kyoto University project aims to supply iPS cells widely at low cost – The Japan Times

By Induced Pluripotent Stem Cells

Kyoto A project to make induced pluripotent stem cells, known as iPS cells, promptly and widely available at lower cost will get underway next year.

The My iPS Project will feature the creation of iPS cells, which can change into various types of functional cells, from the blood or other tissues of the patients themselves, to avoid rejection when a transplant is performed.

The project will be led by the CiRA Foundation at Kyoto University, which has taken over the business of stockpiling iPS cells from the university's Center for iPS Research and Application.

Headed by Shinya Yamanaka, a stem cell researcher and professor at the university who was awarded the Nobel Prize in Physiology or Medicine in 2012 for his pioneering work in iPS cell technology, the foundation was set up in September 2019 to make the business an independent operation financed by earnings and donations. It became a public interest foundation in April.

When a transplant is performed, the rejection of cells occurs if human leukocyte antigen, or HLA, from the donor is different from that of the recipient.

But with iPS cells produced from a person who has inherited the same type of HLA from his or her parents, rejection is considered rare for cells transplanted in another person with the same type of the antigen.

Using this knowledge, CiRA at Kyoto University has produced 27 kinds of iPS cells from the blood of seven healthy people and supplied them to research institutions and private companies for use in clinical studies and trials to facilitate regenerative medicine.

In 2017, research institutions such as Riken transplanted retina cells produced from the iPS cells in five patients suffering from intractable eye diseases. The first transplants of their kind in the world were followed by the transplants of nerve cells to the brain of a Parkinson's disease patient at Kyoto University and of a cardiac muscle sheet to a cardiac patient at Osaka University.

But the iPS cells stored by CiRA are of four kinds in terms of HLA type, estimated to eliminate rejection for only about 40 percent of all transplants for Japanese people. At CiRA, furthermore, iPS cells are manually cultivated by three well-trained people who are also responsible for preventing the entry of impurities and checking quality.

CiRA, therefore, can produce iPS cells only for three patients per year and transplants cost 40 million per person.

To reduce rejection, the foundation will develop technology to culture iPS cells from the blood or other tissues of the patients themselves and lower the cost of transplants. Starting in 2021, it will build a facility for automated processes from cultivation to inspection to stockpiling.

The project will be financed from the 5 billion that Tadashi Yanai, president and chairman of Fast Retailing Co., has pledged to donate to Kyoto University over 10 years.

The facility, with a total floor space of 1,500 square meters, will have many cylindrical, automated incubators as tall as human beings. It is planned to be completed in January 2025 so that its technology can be exhibited at the World Exposition to be held in Osaka in the year. To show appreciation for the donation, the facility will carry the name Yanai.

The project will realize the "ideal use" of iPS cells, Yamanaka said, declaring the aim of supplying them to 1,000 patients per year at 1 million per person.

Originally posted here:
Kyoto University project aims to supply iPS cells widely at low cost - The Japan Times

ONLINE: The Future of Medicine – Isthmus

By Induced Pluripotent Stem Cells

Watch here: https://www.youtube.com/watch?feature=youtu.be&v=VVkQU91KbEs

press release: The UW has a long history of pioneering medical advancements that have transformed the world. From performing the first bone marrow transplant in the United States to cultivating the first laboratory-derived human embryonic stem cells. Now, where will UW medical research go next?

On the next Wisconsin Medicine Livestream, meet trailblazing doctors, researchers, and medical leaders who are charting a bold course to completely alter the health care landscape. During this insightful panel discussion, well explore how gene therapy and cell replacements could hold the keys to treating inherited and acquired blindness. Youll also discover the remarkable potential in xenotransplantation where nonhuman animal source organs are transplanted into human recipients. In addition, you will learn about UW Healths journey to build a multidisciplinary program to serve the community. These, and other, fascinating developments in treatment and care are happening right now at the UW and are the future of medicine. The presentation will be moderated by Robert Golden, the dean of the University of WisconsinMadisons School of Medicine and Public Health.

Our Guests:

David Gamm, professor, Department of Ophthalmology and Visual Sciences; Emmett A. Humble Distinguished Director, McPherson Eye Research Institute; Sandra Lemke Trout Chair in Eye Research

Dr. Gamms lab is at the forefront in developing cell-based therapies to combat retinal degenerative diseases (RDDs). As the director of the McPherson Eye Research Institute and a member of the Waisman Center Stem Cell Research Program, the UW Stem Cell and Regenerative Medicine Center, and the American Society for Clinical Investigation, his efforts are directed toward basic and translational retinal stem cell research. The Gamm Lab uses induced pluripotent stem cells to create retinal tissues composed of authentic human photoreceptor cells rods and cones that can detect light and initiate visual signals in a dish. The aims of his laboratory are to investigate the cellular and molecular events that occur during human retinal development and to generate cells for use in retinal disease modeling and cell replacement therapies. In collaboration with other researchers at UWMadison and around the world, the lab is developing methods to produce and transplant photoreceptors and/or retinal pigment epithelium (RPE) in preparation for future clinical trials. At the same time, the Gamm Lab uses lab-grown photoreceptor and RPE cells to test and advance a host of other experimental treatments, including gene therapies. In so doing, the lab seeks to delay or reverse the effects of blinding disorders, such as retinitis pigmentosa and age-related macular degeneration, and to develop or codevelop effective interventions for these RDDs at all stages of disease.

Dhanansayan Shanmuganayagam, assistant professor, Department of Surgery, School of Medicine and Public Health; Department of Animal and Dairy Sciences, UWMadison; director, Biomedical, and Genomic Research Group

Dr. Shanmuganayagams research focuses on the development and utilization of pigs as homologous models to close the translational gap in human disease research, taking advantage of the overwhelming similarities between pigs and humans in terms of genetics, anatomy, physiology, and immunology. He and his colleagues created the human-sized Wisconsin Miniature Swine breed that is unique to the university. The breed exhibits greater physiological similarity to humans, particularly in vascular biology and in modeling metabolic disorders and obesity. He currently leads genetic engineering of swine at the UW. His team has created more than 15 genetic porcine models including several of pediatric genetic cancer-predisposition disorders such as neurofibromatosis type 1 (NF1). In the context of NF1, his lab is studying the role of alternative splicing of the nf1 gene on the tissue-specific function of neurofibromin and whether gene therapy to modulate the regulation of this splicing can be used as a viable treatment strategy for children with the disorder.

Dr. Shanmuganayagam is also currently leading the efforts to establish the University of Wisconsin Center for Biomedical Swine Research and Innovation (CBSRI) that will leverage the translatability of research in pig models and UWMadisons unique swine and biomedical research infrastructure, resources, and expertise to conduct innovative basic and translational research on human diseases. The central mission of CBSRI is to innovate and accelerate the discovery and development of clinically relevant therapies and technologies. The center will also serve to innovate graduate and medical training. As the only center of its kind in the United States, CBSRI will make UWMadison a hub of translational research and industry-partnered biomedical innovation.

Petros Anagnostopoulos, surgeon in chief, American Family Childrens Hospital; chief, Section of Pediatric Cardiothoracic Surgery; professor, Department of Surgery, Division of Cardiothoracic Surgery

Dr. Anagnostopoulos is certified by the American Board of Thoracic Surgery and the American Board of Surgery. He completed two fellowships, one in cardiothoracic surgery at the University of Pittsburgh School of Medicine and a second in pediatric cardiac surgery at the University of California, San Francisco School of Medicine. He completed his general surgery residency at Henry Ford Hospital in Detroit. Dr. Anagnostopoulos received his MD from the University of Athens Medical School, Greece. His clinical interests include pediatric congenital heart surgery and minimally invasive heart surgery.

Dr. Anagnostopoulos specializes in complex neonatal and infant cardiac reconstructive surgery, pediatric heart surgery, adult congenital cardiac surgery, single ventricle palliation, extracorporeal life support, extracorporeal membrane oxygenation, ventricular assist devices, minimally invasive cardiac surgery, hybrid surgical-catheterization cardiac surgery, off-pump cardiac surgery, complex mitral and tricuspid valve repair, aortic root surgery, tetralogy of Fallot, coronary artery anomalies, Ross operations, obstructive cardiomyopathy, and heart transplantation.

When: Tuesday, Sept. 29, at 7 p.m. CDT

Where: Wisconsin Medicine Livestream: wiscmedicine.org/programs/ending-alzheimers

Continued here:
ONLINE: The Future of Medicine - Isthmus

funded study sheds light on abnormal neural function in rare genetic disorder – National Institutes of Health

By Induced Pluripotent Stem Cells

News Release

Monday, September 28, 2020

Findings show deficits in the electrical activity of cortical cells; possible targets for treatment for 22q11.2 deletion syndrome.

A genetic study has identified neuronal abnormalities in the electrical activity of cortical cells derived from people with a rare genetic disorder called 22q11.2 deletion syndrome. The overexpression of a specific gene and exposure to several antipsychotic drugs helped restore normal cellular functioning. The study, funded by the National Institutes of Health (NIH) and published in Nature Medicine, sheds light on factors that may contribute to the development of mental illnesses in 22q11.2 deletion syndrome and may help identify possible targets for treatment development.

22q11.2 deletion syndrome is a genetic disorder caused by the deletion of a piece of genetic material at location q11.2 on chromosome 22. People with 22q11.2 deletion syndrome can experience heart abnormalities, poor immune functioning, abnormal palate development, skeletal differences, and developmental delays. In addition, this deletion confers a 20-30% risk for autism spectrum disorder (ASD) and an up to 30-fold increase in risk for psychosis. 22q11.2 deletion syndrome is the most common genetic copy number variant found in those with ASD, and up to a quarter of people with this genetic syndrome develop a schizophrenia spectrum disorder.

This is the largest study of its type in terms of the number of patients who donated cells, and it is significant for its focus on a key genetic risk factor for mental illnesses, said David Panchision, Ph.D., chief of the Developmental Neurobiology Program at the NIHs National Institute of Mental Health. Importantly, this study shows consistent, specific patient-control differences in neuronal function and a potential mechanistic target for developing new therapies for treating this disorder.

While some effects of this genetic syndrome, such as cardiovascular and immune concerns, can be successfully managed, the associated psychiatric effects have been more challenging to address. This is partly because the underlying cellular deficits in the central nervous system that contribute to mental illnesses in this syndrome are not well understood. While recent studies of 22q11.2 deletion syndrome in rodent models have provided some important insights into possible brain circuit-level abnormalities associated with the syndrome, more needs to be understood about the neuronal pathways in humans.

To investigate the neural pathways associated with mental illnesses in those with 22q11.2 deletion syndrome, Sergiu Pasca, M.D., associate professor of psychiatry and behavioral sciences at Stanford University, Stanford, California, along with a team of researchers from several other universities and institutes, created induced pluripotent stems cells cells derived from adult skin cells reprogramed into an immature stem-cell-like state from 15 people with 22q11.2 deletion and 15 people without the syndrome. The researchers used these cells to create, in a dish, three-dimensional brain organoids that recapitulate key features of the developing human cerebral cortex.

What is exciting is that these 3D cellular models of the brain self-organize and, if guided to resemble the cerebral cortex, for instance, contain functional glutamatergic neurons of deep and superficial layers and non-reactive astrocytes and can be maintained for years in culture. So, there is a lot of excitement about the potential of these patient-derived models to study neuropsychiatric disease, said Dr. Pasca.

The researchers analyzed gene expression in the organoids across 100 days of development. They found changes in the expression of genes linked to neuronal excitability in the organoids that were created using cells from individuals with 22q11.2 deletion syndrome. These changes prompted the researchers to take a closer look at the properties associated with electrical signaling and communication in these neurons. One way neurons communicate is electrically, through controlled changes in the positive or negative charge of the cell membrane. This electrical charge is created when ions, such as calcium, move into or out of the cell through small channels in the cells membrane. The researchers imaged thousands of cells and recorded the electrical activity of hundreds of neurons derived from individuals with 22q11.2 deletion syndrome and found abnormalities in the way calcium was moved into and out of the cells that were related to a defect in the resting electrical potential of the cell membrane.

A gene called DGCR8 is part of the genetic material deleted in 22q11.2 deletion syndrome, and it has been previously associated with neuronal abnormalities in rodent models of this syndrome. The researchers found that heterozygous loss of this gene was sufficient to induce the changes in excitability they had observed in 22q11.2-derived neurons and that overexpression of DGCR8 led to partial restoration of normal cellular functioning. In addition, treating 22q11.2 deletion syndrome neurons with one of three antipsychotic drugs (raclopride, sulpiride, or olanzapine) restored the observed deficits in resting membrane potential of the neurons within minutes.

We were surprised to see that loss in control neurons and restoration in patient neurons of the DGCR8 gene can induce and, respectively, restore the excitability, membrane potential, and calcium defects, said Pasca. Moving forward, this gene or the downstream microRNA(s) or the ion channel/transporter they regulate may represent novel therapeutic avenues in 22q11.2 deletion syndrome.

Grants:MH107800; MH100900; MH085953; MH060233; MH094714

About the National Institute of Mental Health (NIMH):The mission of theNIMHis to transform the understanding and treatment of mental illnesses through basic and clinical research, paving the way for prevention, recovery and cure. For more information, visit theNIMH website.

About the National Institutes of Health (NIH): NIH, the nation's medical research agency, includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. NIH is the primary federal agency conducting and supporting basic, clinical, and translational medical research, and is investigating the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit http://www.nih.gov.

NIHTurning Discovery Into Health

Khan, T. A., Revah, O., Gordon, A., Yoon, S., Krawisz, A. K., Goold, C., Sun, Y., Kim, C., Tian, Y., Li, M., Schaepe, J. M., Ikeda, K., Amin, N. D., Sakai, N., Yazawa, M., Kushan, L., Nishino, S., Porteus, M. H., Rapoport, J. L. Paca, S. (2020). Neuronal defects in a human cellular model of 22q11.2 deletion syndrome. Nature Medicine. doi: 10.1038/s41591-020-1043-9

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funded study sheds light on abnormal neural function in rare genetic disorder - National Institutes of Health

Stem Cell Market Potential Growth, Size, Share, Demand and Analysis of Key Players Research Forecasts to 2027 – The Daily Chronicle

By Induced Pluripotent Stem Cells

Fort Collins, Colorado The Stem Cell Market is growing at a rapid pace and contributes significantly to the global economy in terms of turnover, growth rate, sales, market share and size. The Stem Cell Market Report is a comprehensive research paper that provides readers with valuable information to understand the basics of the Stem Cell Report. The report describes business strategies, market needs, dominant market players and a futuristic view of the market.

The report has been updated to reflect the most recent economic scenario and market size regarding the ongoing COVID-19 pandemic. The report looks at the growth outlook as well as current and futuristic earnings expectations in a post-COVID scenario. The report also covers changing market trends and dynamics as a result of the pandemic and provides an accurate analysis of the impact of the crisis on the market as a whole.

Stem cell market garnered a revenue of USD 9.45 billion in the year 2019 globally and has been foreseen to yield USD 15.55 billion by the year 2027 at a compound annual growth (CAGR) of 8.0% over the forecast period.

Get a sample of the report @ https://reportsglobe.com/download-sample/?rid=84558

Industry Stem Cell Study provides an in-depth analysis of key market drivers, opportunities, challenges and their impact on market performance. The report also highlights technological advancements and product developments that drive market needs.

The report contains a detailed analysis of the major players in the market, as well as their business overview, expansion plans and strategies. Key players explored in the report include:

The report provides comprehensive analysis in an organized manner in the form of tables, graphs, charts, pictures and diagrams. Organized data paves the way for research and exploration of current and future market outlooks.

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The report provides comprehensive data on the Stem Cell market and its trends to help the reader formulate solutions to accelerate business growth. The report provides a comprehensive overview of the economic scenario of the market, as well as its benefits and limitations.

The Stem Cell Market Report includes production chain analysis and value chain analysis to provide a comprehensive picture of the Stem Cell market. The research consists of market analysis and detailed analysis of application segments, product types, market size, growth rates, and current and emerging industry trends.

Stem Cell Market, By Therapy (2016-2027)

Stem Cell Market, By Technology (2016-2027)

Stem Cell Market, By Application (2016-2027)

Stem Cell Market, By Product (2016-2027)

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The market is geographically spread across several key geographic regions and the report includes regional analysis as well as production, consumption, revenue and market share in these regions for the 2020-2027 forecast period. Regions include North America, Latin America, Europe, Asia Pacific, the Middle East, and Africa.

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Stem Cell Market Potential Growth, Size, Share, Demand and Analysis of Key Players Research Forecasts to 2027 - The Daily Chronicle

The new pharma collaborations driving transformative research in oncology – – pharmaphorum

By Induced Pluripotent Stem Cells

The pharmaceutical industry is one of the most scientifically innovative and competitive industries, particularly in oncology. As of 2018, there were over 1,100 cancer therapies in development, and as of 2020, 362 of them were cell and gene therapies. As a result, there is a need for continued innovation and increased efficiency in terms of drug development to manage cost, complexity and speed to provide potentially transformative therapies for cancer patients.

Within the last two decades, large pharmaceutical corporations have established themselves firmly in oncology by prioritising internal R&D efforts, as well as developing and accessing novel science and technology through collaborations and alliances with biotech companies and academic institutions.

Dramatic advances in the understanding of basic molecular mechanisms of underlying disease has continued to shift R&D focus toward precision medicine choosing the right therapy for a patient based on molecular understanding of their disease and less on traditional cancer therapies such as cytotoxic chemotherapies and broad-cell cycle inhibitors.

As a result of this shift in drug development, a highly concentrated overlay in product modalities and mechanisms of action has crowded the oncology pipeline across a very broad range of hematological and solid tumour indications.

The industry is asking itself how to stay innovative, how to develop and bring to market higher quality therapies to patients and how to do this faster and more efficiently.

A diversity of collaboration types

There is broad recognition that given the breadth and complexity of emerging science driving innovation in oncology, collaborations are essential in order that relevant expertise, know-how and capabilities can be combined in the right way to address patient needs.

Such collaborations take on many forms, ranging from early, multi-party alliances and consortia which are often pre-competitive in nature driving the development and shared learnings from technologies that may be enabling the field as a whole, through to more bespoke collaborations between entities.

Cell therapy research has been built on collaborations amongst scientists and entrepreneurs, providing early proof of concept for modalities thought to be too difficult to commercialise but with a strong potential for patient benefit

These may be more focused on collaborative research and development of novel products, to secure the necessary data for regulatory approvals to make such products available widely to the patients who can benefit from them.

Pre-competitive collaborations, often in basic and preclinical research, can reduce the barrier of competition and drive benefits for all stakeholders, most notably, the patient. As summarised by The National Institutes of Health, this includes reducing the number of redundant clinical trials, enhancing the statistical strength of studies, reducing overall costs and risks, and improving study participant recruitment, all while triggering creativity and innovation between collaborators.

These benefits strengthen capabilities and accelerate product development, ultimately producing higher quality and more effective therapies.

One powerful example is The National Institutes of Healths Partnership for Accelerating Cancer Therapies (PACT), which brought together 11 pharmaceutical companies to accelerate the development of new cancer immunotherapies.

Aligning with the focus of the Cancer Moonshot Research Initiative, PACT aimed to retrospectively analyse patient data from past clinical trials with the goal of predicting future patient outcomes.

This type of approach supports the ability to compare data across all trials and facilitates information sharing between partners, undoubtedly accelerating the pathway to effective therapies.

A second example is the establishment of The Parker Institute for Cancer Immunotherapy, to enable leading academic researchers and companies to come together in a pre-competitive setting, to enable rapid shared understanding and development of immunotherapeutic approaches, including the study of combination regimens.

Such combination trials, particularly those encompassing investigational products, have historically been challenging to undertake given the need for bespoke company-to-company and other 1:1 collaborative agreements. Bringing together multiple academic and industry participants under an open innovation model provides a basis to significantly accelerate the generation of scientific and clinical data that may substantially inform the field of cancer immunotherapy as a whole.

Oncology cell therapy research has been built on foundational academic collaborations amongst scientists and entrepreneurs, providing early proof of concept for modalities thought to be too difficult to commercialise but with a strong potential for patient benefit.

Examples include Kite Pharma, formed from the foundational work at the National Cancer Institute, Juno from the collaboration between the Fred Hutchinson Cancer Center and Memorial Sloan Kettering Cancer Center (all working on the first CAR T-cell candidates), or Adaptimmune working with University of Penn to first show efficacy of optimised TCR T-cells.

For collaborations that are more geared to development of novel therapies, aiming for regulatory approval and commercial availability, bespoke collaborations between biotech and pharma companies are commonplace, whereby the respective expertise and capabilities of each partner are combined in order to optimise and accelerate development, and to enable subsequent, larger scale manufacture and distribution. There are many examples of such collaborations, for which the structure can vary widely depending on the expertise of each partner, and the collaborative ways of working.

For example, under a traditional pharma/biotech collaboration and licensing model, a biotech partner may have primary responsibility for significant elements of research and early product development, and the pharma partner may lead the majority of later stage development, as well as post-approval commercial manufacture and supply. This logically aligns with organisational expertise and scale, and this type of collaboration structure has historically proven to work well. Many novel therapies have been successfully developed through such partnerships.

The rapid emergence of cell and gene therapy has required the industry to establish new and distinct capabilities, such as optimal process development and manufacture of autologous, patient specific cell therapies, whilst minimising the vein-to-vein time (the elapsed time between apheresis treatment for a patient, and reinfusing the final autologous manufactured product).

There are a growing number of biotech and pharma companies that have established or are establishing such end-to-end cell therapy capabilities, which can also play into how collaborations are structured in the field.

Case Study: From Technology Agreement to co-development and co-commercialisation partnership

In 2015, Adaptimmune and Universal Cells signed an agreement to drive the development of technologies leveraging gene-edited Induced Pluripotent Stem Cell (iPSC) lines, towards the development of allogeneic, or off-the-shelf, T-cell therapies. Universal Cells brought leading gene editing capability to make targeted gene edits to modify the characteristics of selected iPSC cell lines, and Adaptimmune the technology to differentiate iPSCs into T-cells.

Back then the science for this collaboration was early and under-developed with both parties embarking on a long-term effort and making significant at-risk investments to determine if edited, functional T-cells could be produced.

Today, Universal Cells (now an Astellas company) and Adaptimmune have established capabilities and expertise to progress novel cell therapies into clinical development, as well as with manufacturing and supply chain.

Based on this progress, in January 2020, Adaptimmune and Astellas signed a product-focused agreement to co-develop and co-commercialise up to three new stem-cell derived allogeneic T-cell therapies for people with cancer.

Given the scientific synergy between Universal Cells and Adaptimmune, and that each company is developing capabilities that may effectively address later stage product development and post-approval commercial supply, the 2020 partnership was structured as a co-development and co-commercialisation agreement. It enables the companies to work closely together, throughout the continuum of research, development and commercialisation.

Astellas and Adaptimmune will collaborate through to the end of phase 1, with Universal Cells leading gene editing activities and Adaptimmune leading iPSC to T-cell differentiation, early product characterisation and development. Beyond that, Astellas and Adaptimmune will decide whether to develop and commercialise a product candidate together under a co-development and co-commercialisation cost and profit-sharing arrangement, or for one company to take it forward alone.

This partnership is an example of how companies can harness their individual science and bring together highly complementary skills and expertise. It will enable the development of new, off-the-shelf T-cell therapies for people with cancer, which could potentially offer significant advantages such as broader access, reduced vein-to-vein time, and lower cost. The co-development and co-commercialisation nature of the agreement allows both companies to collaborate closely and on a long term basis, whilst leveraging end-to-end capabilities established by each company, maximising the velocity of product development, and ultimately delivering novel therapies to patients.

This type of agreement exemplifies how early speculative scientific collaboration can benefit all parties, most importantly the patient. It is one example from many in oncology, that underlines the value of long-term partnership within a field that is evolving rapidly across many scientific, operational and commercial frontiers.

Bringing together both teams of passionate and forward-thinking scientists may contribute to unlocking the current opportunities and challenges of off-the-shelf T-cell therapy development more effectively and efficiently for patients.

Similarly to what we are seeing as the world comes together to fight COVID-19, we as leaders in oncology owe it to patients to constantly look for ways to bring our innovative ideas as quickly as possible to the market. Working together might make that happen faster.

About the author

Helen Tayton-Martin is chief business officer at Adaptimmune.

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The new pharma collaborations driving transformative research in oncology - - pharmaphorum

Autologous Stem Cell and Non-Stem Cell Based Therapies Market – Growth, Trends, and Forecast (2020 – 2025) – GlobeNewswire

By Stem Cell Treatment

September 22, 2020 04:03 ET | Source: ReportLinker

New York, Sept. 22, 2020 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Autologous Stem Cell and Non-Stem Cell Based Therapies Market - Growth, Trends, and Forecast (2020 - 2025)" - https://www.reportlinker.com/p05974135/?utm_source=GNW

- Stem cell technology is found to be a speedily developing technology which plays a major role in regenerative medicine, as it also serves the disciplines of tissue engineering, developmental cell biology, cellular therapeutics, gene therapy, chemical biology, and nanotechnology. Stem cells offer the possibility of replacing the cells and tissues to treat various conditions including spinal cord injury, arthritis, and Parkinsons disease, among others. - The applications of stem cell technologies in the treatment of diseases have ultimately increased the overall adoption rate of these technologies across the world. - The advantage of autologous stem cell transplant is that one is getting ones own cells back. This means there is no risk that the immune system of the individual will reject the transplant or that the transplanted cells will attack or reject the individuals body.

Key Market Trends Cancer Holds Significant Share in the Autologous Stem Cell and Non-Stem Cell Based Therapies Market

- Cancer rates could further increase by 50%, to 15 million new cases by 2020, as per World Cancer Report. It also provides clear evidence that healthy lifestyles and public health action by governments and health practitioners could stem this trend, and prevent as many as one-third of cancers, worldwide. - The American Cancer Society, the leading body in cancer stats and figures, reports 1,685,210 estimated new cancer cases and 595,690 deaths due to cancer in 2016, in the United States. - The National Cancer Institute reports that more than 60% of the worlds new cancer cases occur in Africa, Asia, and Central and South America; 70% of the worlds cancer deaths also occur in these regions. The International Agency for Research on Cancer (IARC) predicts that by 2030, the global burden is expected to rise to 21.7 million new cancer cases and 13 million cancer deaths, simply due to growth and aging of population, leaving aside factors, such as smoking, poor diet, physical inactivity, and fewer childbirths in economically developing countries. - According to WHO, almost 70% of deaths from cancer occur in low and middle-income countries, and only one in five low- and middle-income countries has the necessary data to drive cancer policy. This global and extensive threat of cancer remains a major market driver for new cancer therapies that help in risk assessment, early diagnosis, and effective monitoring of the treatment.

North America Dominates the Autologous Stem Cell and Non-Stem Cell Based Therapies Market

- North America dominated the overall stem cell market with the United States contributing to the largest share in the market. - The ease in the US government regulations and availability of funds from various organizations, like the National Institute of Health, have provided the potential for researchers to invest more in the use of biomarkers in drug discovery, drug development, detection of specific tumors, monitoring biological response to cancer therapy, and genetic studies for the identification of predisposed candidates of cancer. - In 2014, the Sanford Stem Cell Clinical Center at the University of California, San Diego (UCSD) Health System, announced the launch of a clinical trial, in order to assess the safety of neural stem cellbased therapy in patients with chronic spinal cord injury. - Researchers hoped that the transplanted stem cells may develop into new neurons that could replace severed or lost nerve connections, and restore at least some motor and sensory functions. Such numerous stem cell studies across the United States have helped in the growth of the stem cell market.

Competitive Landscape The global Autologous Stem Cell and Non-Stem Cell-Based Therapies market is competitive and consists of a few major players. The companies includes Novartis AG, BrainStorm Cell Limited, Caladrius, Cytori Therapeutics Inc., Dendreon Pharmaceuticals LLC, Gilead Sciences Inc., Regeneus Ltd, U.S. Stem Cell, Inc, among others, hold the substantial market share in the growth of overall market.

Reasons to Purchase this report: - The market estimate (ME) sheet in Excel format - 3 months of analyst support Read the full report: https://www.reportlinker.com/p05974135/?utm_source=GNW

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Autologous Stem Cell and Non-Stem Cell Based Therapies Market - Growth, Trends, and Forecast (2020 - 2025) - GlobeNewswire