StemCell Therapy

Organoid cell culture has transformed cell-based assays in drug discovery and basic biology by conferring physiologic relevance to in vitro cell-based biological models. When provided with a suitable growth environment, including appropriate cultureware, growth factors, extracellular matrix, nutrients, and culture media, organ-derived progenitor cells harvested from patients grow and assemble into three-dimensional structures organoids which incorporate all cell types normally found in the original tissue, and allow physical and chemical interactions between and among cells. By providing greater physiologic relevance and a species- or patient-specific test platform, organoids overcome many limitations of conventional 2D cultures and even live-animal disease models.Organoids arise from organ-derived adult pluripotent stem cells, organ stem cells, or cancer stem cells which possess the innate capacity to expand and differentiate into multiple cell types. Organoids generated from dozens of tissues and organs available commercially, or accessible through published protocols include patient-derived models of liver, heart, pancreas, brain, GI tract, kidney, and recently, of human airwayssuitable for drug and vaccine development and for studying infectious human respiratory diseases.

Corning Life Sciences has collaborated with HUB since 2014 to provide advanced organoids and related technology.

Dr Clevers technology allowed, for the first time, the expansion of adult stem cell-derived organoids in genetically stable form and ultimately, the generation of in vitro models of any epithelial disease from any patient.

A second key benefit was indefinite expansion similar to that of transformed cells, but without the genetic abnormalities inherent in cancer cells. Previously, organoids were generated from embryonic or induced pluripotent stem cells, or from tumor cells which by necessity are genetically modified and therefore unrepresentative of the patient.

Under HUBs commercial development, organoid technology also provides standardization and consistency which is difficult to match, especially with primary cell cultures. Biopsies from the same patient collect differing quantities of cells at widely varying stages of cell lifecycle. When cultured under identical HUB protocols adult progenitor cells give rise to organoids with exactly the same cells in the same proportions, physical configuration, and genetics, every time, and with broad expansion capabilities.

Similarly, transformed cells grown on plastic have modified their gene expression to adapt to tissue culture conditions. Studies with such cells can be useful, provided investigators recognize that the patients original genetics have not been preserved. In HUB organoids the patients molecular footprint is maintained.

One field where this has been particularly useful is infectious diseases. Viruses have evolved to infect and replicate in cells in their normal physiological states. For example, respiratory syncytial virus (RSV) readily grows in organoids but will not infect transformed cells because the cells lack the relevant receptors.

Cell-based studies of airway diseases topical in light of the current COVID-19 pandemic were hampered for years for this reason, and technology for expanding primary cell cultures sufficiently for large-scale studies did not exist. By preserving critical cell surface receptors for infectious agents, the HUB method allows the study of such pathogens as RSV, human papillomavirus, norovirus, coronavirus, influenza, malaria and many others.

Epithelial cells are the first point of contact for pathogenic microbes in the respiratory tract, and fortuitously the cell types most easily grown as organoids. Receptors on airway epithelia and alveolar cells sense infection, which initiates mucosal barrier immunity through club, ciliated, basal, goblet and neuroendocrine cells, which together clear inhaled pathogens.

In a recent Science paper, researchers from the Hubrecht Institute and Erasmus Medical Center reported on how gut organoids helped them to uncover two potential avenues for treating or preventing infection with SARS-CoV-2, the coronavirus responsible for the current pandemic. SARS-CoV-2 is known to infect the lungs, but clinical evidence suggests intestinal involvement in both symptomatology and transmission. For example, rectal swabs contain viral RNA for a time after nasal swabs indicate the infection has resolved, suggesting gastro-intestinal infection and possibly fecaloral transmission.

Differentiated enterocytes strongly express the SARS-CoV-2 angiotensin converting enzyme 2 (ACE2) receptor through which the virus enters cells, with the highest receptor levels found in the brush border of intestinal enterocytes. Surprisingly, virus infected both high- and low expressors of ACE2, and infectivity of organoids was not greatly affected by culture conditions.

SARS-CoV-2 rapidly infected a subset of cells within the organoid, and infection increased over time. Using electron microscopy to visualize cellular components, the researchers found virus particles inside and outside the organoids constituent cells. Infection induced release of interferon, an endogenous antiviral whose activation could serve as the target for potential therapies.

The researchers concluded that intestinal epithelium supports SARS-CoV-2 replication, that human small intestinal organoids serve as an experimental model for coronavirus infection and biology, and that human organoids represent faithful experimental models to study the biology of coronaviruses.

In addition to drug screening and toxicology studies, airway organoids have been utilized to study the basic biology of infectious diseases. In an application note, Corning scientists reported that Corning Matrigel extracellular matrix facilitated the expansion of patient-derived bronchial epithelial cells into airway organoids suitable for high throughput analysis. Organoids streamlined the usual sample preparation protocol to a single operation cell lysis eliminating the normal steps of gene amplification, cDNA conversion, and library preparation.

Comparing normal and asthmatic airway organoids, investigators observed increased expression of genes coding for pro-inflammatory chemokines, receptors, and other proteins associated with inflammation in asthmatic airway cells. They also found that the genes upregulated in organoids derived from healthy cells were the same as those downregulated in organoids from asthmatic cells, and vice-versa. Application of the anti-inflammatory steroid dexamethasone induced up- or downregulation to a greater degree in asthmatic organoids compared with normal organoids.

The Corning study illustrates the versatility of organoids for studying airway diseases in the presence of comorbidities, as well as the ability to respond rapidly with suitable models for infectious diseases.

HUB Organoids derived from adult stem cells harvested from cystic fibrosis patients have proved valuable in the study of CF pathology, and have permitted patient-centered drug testing, which was the first use of HUB Organoids in personalized medicine. The CF patient derived organoids are tested to identify drug treatments for CF patients and in treated accordingly.

Recent studies on interleukin-17 receptors on lung epithelia have uncovered a role for this cytokine in acute and chronic inflammation, and demonstrated that IL-17 receptors participate in the innate immune defense against pulmonary fungal infections. In vivo, IL-17 expression and immune function requires polarized epithelial cells. In a paper appearing in 2019 in Frontiers in Immunology, a group at the University of Perugia, in Italy, wrote that because lung organoids recapitulate tissue polarity, they provide an exciting possibility of using lung organoids to comprehensively investigate IL-17R signaling in the lung, which is likely to offer new opportunities to develop and test therapeutics for inflammatory diseases and identify new molecular targets to improve resistance to infections.

As a scientific discipline, organoids will continue evolving towards greater ease of use, consistency, assay parallelism capabilities, and manufacturability. Organoids and organ-on-a-chip have already been combined in a complex, multi-tissue retina model, while systems consisting of organoids from two or more organs, discussed earlier, are already used routinely.

If organoid research continues at its current pace there is reason to expect significant streamlining of early-stage drug development, specifically around the preclinical and phase 1 stages. Organoids could eliminate some if not all animal testing, but this will require a leap of faith on the part of regulators already accustomed to reviewing animal data and its inherent caveats. At some point organoids might completely eliminate live preclinical screens, allowing drug developers to recruit patients directly into phase 2 based entirely on organoid-based screening.

While organoid investigations inevitably lead to systems of greater complexity, investigators should keep in mind that validation is the key to patient relevant models. HUB Organoids for the first time allow researchers to develop a model and directly test if and how it resembles the patient from which the tissue originated. With increasing complexity, the validation step should remain a focus of model developers and users. Complexity is good, but only up to a point.

Advancing organoids towards these lofty goals, including greater manufacturability, will require cell culture tools up to the task. Industry collaborations assure that tools for 3D cell culture will continue to advance, both for general research and to meet the challenges of emerging infectious diseases.

Authors: Dr Robert Vries, Chief Executive Officer, Hubrecht Organoid Technology (HUB)Elizabeth Abraham, Senior Product Manager, Corning Incorporated

Excerpt from:
Using Organoids in the Study of Infectious Diseases - Technology Networks

New York, Sept. 08, 2020 (GLOBE NEWSWIRE) -- Reportlinker.com announces the release of the report "Global Biotechnology Instrumentation Industry" - https://www.reportlinker.com/p090668/?utm_source=GNW 4 Billion by 2027, growing at a CAGR of 5.6% over the analysis period 2020-2027. Immunoassay Systems, one of the segments analyzed in the report, is projected to record a 4.5% CAGR and reach US$21.8 Billion by the end of the analysis period. After an early analysis of the business implications of the pandemic and its induced economic crisis, growth in the DNA Sequencing Systems segment is readjusted to a revised 8.1% CAGR for the next 7-year period.

The U.S. Market is Estimated at $12.5 Billion, While China is Forecast to Grow at 5.3% CAGR

The Biotechnology Instrumentation market in the U.S. is estimated at US$12.5 Billion in the year 2020. China, the world`s second largest economy, is forecast to reach a projected market size of US$11 Billion by the year 2027 trailing a CAGR of 5.3% over the analysis period 2020 to 2027. Among the other noteworthy geographic markets are Japan and Canada, each forecast to grow at 5.2% and 4.6% respectively over the 2020-2027 period. Within Europe, Germany is forecast to grow at approximately 4.8% CAGR.

Mass Spectrometry Segment to Record 6.8% CAGR

In the global Mass Spectrometry segment, USA, Canada, Japan, China and Europe will drive the 6.9% CAGR estimated for this segment. These regional markets accounting for a combined market size of US$3.9 Billion in the year 2020 will reach a projected size of US$6.3 Billion by the close of the analysis period. China will remain among the fastest growing in this cluster of regional markets. Led by countries such as Australia, India, and South Korea, the market in Asia-Pacific is forecast to reach US$7.2 Billion by the year 2027.We bring years of research experience to this 19th edition of our report. The 233-page report presents concise insights into how the pandemic has impacted production and the buy side for 2020 and 2021. A short-term phased recovery by key geography is also addressed.

Competitors identified in this market include, among others,

Read the full report: https://www.reportlinker.com/p090668/?utm_source=GNW

I. INTRODUCTION, METHODOLOGY & REPORT SCOPE

II. EXECUTIVE SUMMARY

1. MARKET OVERVIEW Biotechnology Tools - Driven by Advancements Recent Market Activity Global Market Analysis Factors Sustaining Market Growth Factors Restraining Growth Improving Economy Signals Market Growth Opportunities Global Competitor Market Shares Biotechnology Instrumentation Competitor Market Share Scenario Worldwide (in %): 2018 & 2029 Impact of Covid-19 and a Looming Global Recession

2. FOCUS ON SELECT PLAYERS Abbott Laboratories (USA) Agilent Technologies, Inc. (USA) Beckman Coulter, Inc. (USA) Bio-Rad Laboratories, Inc. (USA) Bruker Corporation (USA) GE HealthCare (UK) Gilson, Inc. (USA) Harvard Bioscience, Inc. (USA) Hitachi High-Technologies Corp. (Japan) Illumina, Inc. (USA) Lonza Group AG (Switzerland) PerkinElmer, Inc. (USA) Roche Diagnostics (Switzerland) Shimadzu Corp. (Japan) Siemens Healthineers (USA) Thermo Fisher Scientific, Inc. (USA) Waters Corp. (USA)

3. MARKET TRENDS & DRIVERS DNA Sequencing Future Diagnostic Applications of DNA Sequencing Next-Generation Sequencing Technologies Drive the Momentum Liquid Chromatography Growth in New Application Markets HPLC Offers Significant Growth Opportunities Innovative HPLC Products Inject New Growth Ultra-High Pressure Liquid Chromatography MS Systems with UHPLC Advancements in HPLC Columns Electrophoresis Systems Capillary Gel Electrophoresis - Gains Prominence Product Innovations Sustain Sales Immunoassay Instruments Growth Opportunities and Areas Automated Multiplexing Platforms Present Growth Opportunities Radioimmunoassay Systems Lose Ground Chemiluminescence Immunoassays Gain Demand Mass Spectrometry Technological Developments and Expanding End-Use Applications to Bolster Growth A Review for Select MS Technologies Portability: A Major Driving Force for MS Systems Market Nanotube Coating to Enable Miniaturization in Mass Spectrometers High Prices of MS Systems Hold Down Sales Growth Purpose-Built Mass Spectrometers to Transform Personalized Medicine Lack of Suitable Software and Diversity of MS Systems - A Major Challenge Smaller Clinical Laboratories Continue to Shy Away from Mass Spectrometers Microarrays Protein Biochips - Set for Robust Expansion Lab-on-a-Chip: Fusion of Nanotechnology & Genetic Engineering Advancements in Biochip Technology Biochip Technology Boosts Personalized Medicine Biochip Technology Spreads beyond Pharma Industry Data on Specificity of Effect Drives Use of Microarrays in Cosmetics and Personal Healthcare Laboratory Automation Technology Sets the Momentum for Microplate Reader Market Growing Options in Multimode Microplate Readers

4. GLOBAL MARKET PERSPECTIVE Table 1: Biotechnology Instrumentation Global Market Estimates and Forecasts in US$ Thousand by Region/Country: 2020-2027

Table 2: Biotechnology Instrumentation Global Retrospective Market Scenario in US$ Thousand by Region/Country: 2012-2019

Table 3: Biotechnology Instrumentation Market Share Shift across Key Geographies Worldwide: 2012 VS 2020 VS 2027

Table 4: Immunoassay Systems (Product Segment) World Market by Region/Country in US$ Thousand: 2020 to 2027

Table 5: Immunoassay Systems (Product Segment) Historic Market Analysis by Region/Country in US$ Thousand: 2012 to 2019

Table 6: Immunoassay Systems (Product Segment) Market Share Breakdown of Worldwide Sales by Region/Country: 2012 VS 2020 VS 2027

Table 7: DNA Sequencing Systems (Product Segment) Potential Growth Markets Worldwide in US$ Thousand: 2020 to 2027

Table 8: DNA Sequencing Systems (Product Segment) Historic Market Perspective by Region/Country in US$ Thousand: 2012 to 2019

Table 9: DNA Sequencing Systems (Product Segment) Market Sales Breakdown by Region/Country in Percentage: 2012 VS 2020 VS 2027

Table 10: Mass Spectrometry (Product Segment) Geographic Market Spread Worldwide in US$ Thousand: 2020 to 2027

Table 11: Mass Spectrometry (Product Segment) Region Wise Breakdown of Global Historic Demand in US$ Thousand: 2012 to 2019

Table 12: Mass Spectrometry (Product Segment) Market Share Distribution in Percentage by Region/Country: 2012 VS 2020 VS 2027

Table 13: MicroArrays (Product Segment) World Market Estimates and Forecasts by Region/Country in US$ Thousand: 2020 to 2027

Table 14: MicroArrays (Product Segment) Market Historic Review by Region/Country in US$ Thousand: 2012 to 2019

Table 15: MicroArrays (Product Segment) Market Share Breakdown by Region/Country: 2012 VS 2020 VS 2027

Table 16: Liquid Chromatography Systems (Product Segment) World Market by Region/Country in US$ Thousand: 2020 to 2027

Table 17: Liquid Chromatography Systems (Product Segment) Historic Market Analysis by Region/Country in US$ Thousand: 2012 to 2019

Table 18: Liquid Chromatography Systems (Product Segment) Market Share Distribution in Percentage by Region/Country: 2012 VS 2020 VS 2027

Table 19: Laboratory Automation (Product Segment) World Market Estimates and Forecasts in US$ Thousand by Region/Country: 2020 to 2027

Table 20: Laboratory Automation (Product Segment) Market Worldwide Historic Review by Region/Country in US$ Thousand: 2012 to 2019

Table 21: Laboratory Automation (Product Segment) Market Percentage Share Distribution by Region/Country: 2012 VS 2020 VS 2027

Table 22: Electrophoresis Systems (Product Segment) Market Opportunity Analysis Worldwide in US$ Thousand by Region/Country: 2020 to 2027

Table 23: Electrophoresis Systems (Product Segment) Global Historic Demand in US$ Thousand by Region/Country: 2012 to 2019

Table 24: Electrophoresis Systems (Product Segment) Market Share Distribution in Percentage by Region/Country: 2012 VS 2020 VS 2027

Table 25: Other Product Segments (Product Segment) World Market by Region/Country in US$ Thousand: 2020 to 2027

Table 26: Other Product Segments (Product Segment) Historic Market Analysis by Region/Country in US$ Thousand: 2012 to 2019

Table 27: Other Product Segments (Product Segment) Market Share Breakdown of Worldwide Sales by Region/Country: 2012 VS 2020 VS 2027

III. MARKET ANALYSIS

GEOGRAPHIC MARKET ANALYSIS

UNITED STATES Market Facts & Figures US Biotechnology Instrumentation Market Share (in %) by Company: 2018 & 2025 Market Analytics Table 28: United States Biotechnology Instrumentation Market Estimates and Projections in US$ Thousand by Product Segment: 2020 to 2027

Table 29: Biotechnology Instrumentation Market in the United States by Product Segment: A Historic Review in US$ Thousand for 2012-2019

Table 30: United States Biotechnology Instrumentation Market Share Breakdown by Product Segment: 2012 VS 2020 VS 2027

CANADA Table 31: Canadian Biotechnology Instrumentation Market Estimates and Forecasts in US$ Thousand by Product Segment: 2020 to 2027

Table 32: Canadian Biotechnology Instrumentation Historic Market Review by Product Segment in US$ Thousand: 2012-2019

Table 33: Biotechnology Instrumentation Market in Canada: Percentage Share Breakdown of Sales by Product Segment for 2012, 2020, and 2027

JAPAN Table 34: Japanese Market for Biotechnology Instrumentation: Annual Sales Estimates and Projections in US$ Thousand by Product Segment for the Period 2020-2027

Table 35: Biotechnology Instrumentation Market in Japan: Historic Sales Analysis in US$ Thousand by Product Segment for the Period 2012-2019

Table 36: Japanese Biotechnology Instrumentation Market Share Analysis by Product Segment: 2012 VS 2020 VS 2027

CHINA Table 37: Chinese Biotechnology Instrumentation Market Growth Prospects in US$ Thousand by Product Segment for the Period 2020-2027

Table 38: Biotechnology Instrumentation Historic Market Analysis in China in US$ Thousand by Product Segment: 2012-2019

Table 39: Chinese Biotechnology Instrumentation Market by Product Segment: Percentage Breakdown of Sales for 2012, 2020, and 2027

EUROPE Market Facts & Figures European Biotechnology Instrumentation Market: Competitor Market Share Scenario (in %) for 2018 & 2025 Market Analytics Table 40: European Biotechnology Instrumentation Market Demand Scenario in US$ Thousand by Region/Country: 2020-2027

Table 41: Biotechnology Instrumentation Market in Europe: A Historic Market Perspective in US$ Thousand by Region/Country for the Period 2012-2019

Table 42: European Biotechnology Instrumentation Market Share Shift by Region/Country: 2012 VS 2020 VS 2027

Table 43: European Biotechnology Instrumentation Market Estimates and Forecasts in US$ Thousand by Product Segment: 2020-2027

Table 44: Biotechnology Instrumentation Market in Europe in US$ Thousand by Product Segment: A Historic Review for the Period 2012-2019

Table 45: European Biotechnology Instrumentation Market Share Breakdown by Product Segment: 2012 VS 2020 VS 2027

FRANCE Table 46: Biotechnology Instrumentation Market in France by Product Segment: Estimates and Projections in US$ Thousand for the Period 2020-2027

Table 47: French Biotechnology Instrumentation Historic Market Scenario in US$ Thousand by Product Segment: 2012-2019

Table 48: French Biotechnology Instrumentation Market Share Analysis by Product Segment: 2012 VS 2020 VS 2027

GERMANY Table 49: Biotechnology Instrumentation Market in Germany: Recent Past, Current and Future Analysis in US$ Thousand by Product Segment for the Period 2020-2027

Table 50: German Biotechnology Instrumentation Historic Market Analysis in US$ Thousand by Product Segment: 2012-2019

Table 51: German Biotechnology Instrumentation Market Share Breakdown by Product Segment: 2012 VS 2020 VS 2027

ITALY Table 52: Italian Biotechnology Instrumentation Market Growth Prospects in US$ Thousand by Product Segment for the Period 2020-2027

Table 53: Biotechnology Instrumentation Historic Market Analysis in Italy in US$ Thousand by Product Segment: 2012-2019

Table 54: Italian Biotechnology Instrumentation Market by Product Segment: Percentage Breakdown of Sales for 2012, 2020, and 2027

UNITED KINGDOM Table 55: United Kingdom Market for Biotechnology Instrumentation: Annual Sales Estimates and Projections in US$ Thousand by Product Segment for the Period 2020-2027

Table 56: Biotechnology Instrumentation Market in the United Kingdom: Historic Sales Analysis in US$ Thousand by Product Segment for the Period 2012-2019

Table 57: United Kingdom Biotechnology Instrumentation Market Share Analysis by Product Segment: 2012 VS 2020 VS 2027

REST OF EUROPE Table 58: Rest of Europe Biotechnology Instrumentation Market Estimates and Forecasts in US$ Thousand by Product Segment: 2020-2027

Table 59: Biotechnology Instrumentation Market in Rest of Europe in US$ Thousand by Product Segment: A Historic Review for the Period 2012-2019

Table 60: Rest of Europe Biotechnology Instrumentation Market Share Breakdown by Product Segment: 2012 VS 2020 VS 2027

ASIA-PACIFIC Table 61: Biotechnology Instrumentation Market in Asia-Pacific by Product Segment: Estimates and Projections in US$ Thousand for the Period 2020-2027

Table 62: Asia-Pacific Biotechnology Instrumentation Historic Market Scenario in US$ Thousand by Product Segment: 2012-2019

Table 63: Asia-Pacific Biotechnology Instrumentation Market Share Analysis by Product Segment: 2012 VS 2020 VS 2027

REST OF WORLD Table 64: Rest of World Biotechnology Instrumentation Market Estimates and Forecasts in US$ Thousand by Product Segment: 2020 to 2027

Table 65: Rest of World Biotechnology Instrumentation Historic Market Review by Product Segment in US$ Thousand: 2012-2019

Table 66: Biotechnology Instrumentation Market in Rest of World: Percentage Share Breakdown of Sales by Product Segment for 2012, 2020, and 2027

IV. COMPETITION Total Companies Profiled: 131Read the full report: https://www.reportlinker.com/p090668/?utm_source=GNW

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Read more:
Global Biotechnology Instrumentation Industry - GlobeNewswire

A new study, led by neuroscientists from Stanford University, has homed in on the specific brain circuit responsible for stress-induced insomnia. The research suggests this same circuit is responsible for stress-related immune system dysfunction, pointing to a close relationship between stress, insomnia and weakened immunity.

It is well known that psychosocial or environmental stress can lead to immune system abnormalities. Insomnia is also commonly associated with stress. But ... do these two stress-induced conditions share the same neural circuitry?

This sort of stress-induced insomnia is well known among anybody thats tried to get to sleep with a looming deadline or something the next day, says Jeremy Borniger, one of the authors on the new study. And in the clinical world, its been known for a long time that chronically stressed patients typically do worse on a variety of different treatments and across a variety of different diseases.

Using a transgenic mouse model, the researchers first pinpointed a cluster of neurons in the paraventricular nucleus of hypothalamus responsible for the stress-induced release of cortisol. Activity in this brain area was found in stimulate a nearby cluster of neurons in the lateral hypothalamus. This area in the lateral hypothalamus was seen to elicit a kind of hyperarousal associated with insomnia.

Using optogenetics the researchers could either block this novel neural circuit, causing the mice to sleep comfortably after exposure to a stressful experience, or specifically activate the stress-responsive neurons and watch the animals immediately wake from slumber.

It seems like its a pretty sensitive switch, in that even very weak stimulation of the circuit can drive insomnia, adds Borniger.

The researchers then looked closely at the effects of stimulating this stress-induced neural pathway on immune system activity. Peripheral immunosuppression was indeed triggered by this same neural pathway. This suggests the effect stress has on both wakefulness and the immune system is, in part, related to this initial, cortisol-releasing, neural pathway.

Borniger says understanding how stress triggers both insomnia and immunosuppression helps researchers look to novel treatments for a number of autoimmune diseases. Interfering with this brain circuit could offer new ways to treat disease. And, of course, new ways to potentially reduce the negative effects of stress on our sleep.

"I'm really interested in how we can manipulate distinct circuits in the brain to control not just the immune system at baseline, but in disease states like inflammatory bowel disease or in cancer or in psoriasisthings that are associated with systemic inflammation, says Borniger. Because if we can understand and manipulate the immune system using the natural circuitry in the body rather than using a drug that hits certain targets within the system, I think that would be much more effective in the long run, because it just co-opts the natural circuits in the body."

The new study was published in the journal Science Advances.

Source: Cold Spring Harbor Laboratory

See the article here:
Brain circuit linking stress, insomnia and the immune system discovered - New Atlas

(Editor's note: This is the first of a two-part letter.)

The health and safety of our island community should be the number one priority of our government. The focus must include our physical and our too often overlooked psychological well-being. We are all the recipients of the current health directives - wear a mask, practice reasonable social/physical distancing and proper hygiene. These are efforts at protecting ourselves. There is something else equally important we can do. We also need measures to prevent severe illness if we do get infected.

We need to keep our immune systems functioning at peak performance. After almost all COVID-19 related deaths, we learn that the patients had other illnesses or conditions that weakened their ability to fight the infection and we refer to these as comorbidities. Even if we are in the greatest of shape physically, we should strive to boost our immune system, our internal defense system, to potentially help our bodies fight infections, especially COVID-19. I am not about to ask you to buy some sort of hocus-pocus immune booster concoction for $39.99 plus shipping. The reason those types of advertisements appeal to so many is that we are not often told of the immune boosting things we can do on our own. Much research has arrived at the same conclusions and recommended the same thing: managing our daily stress, getting enough sleep, eating a well-balanced diet and daily physical exercise.

The immune system is an armamentarium of cells and proteins that defend our body against infection. It safeguards us from invaders including viruses, bacteria, fungus and foreign bodies. Our internal warriors are composed of battalions of defenders, armies and specialized soldiers that attack the invaders. This is a truly complex intricate network of cells, antibodies and molecules which are labeled with names that look like highly secure passwords, such as CD8+, IL-1, IFN-, TNF-, TGF-.

Excess stress weakens the immune system. The science behind that statement is a mountain of research that supports the concept of small amounts of chemicals being released from the brain during stress. The weakening of our immune system from the released chemicals can be silent. The impact of the stress chemicals can be physical and thus more evident. Many have experienced this as acid reflux during stressful times at home or work. The brain sends the stress-related neurotransmitters (tiny chemical signals) to the nerves that control the muscle that keeps acid in the stomach. The signal causes the muscle to malfunction and the patient feels it as heartburn. Yes, clearly stress can have a significant impact on the function of our bodies. The silent impact on the immune system can be much worse than heartburn or stress-induced headaches.

All of us, to some degree, are stressed just by living during this COVID-19 pandemic and have been for the many months it has been around. Most are at least a little worried about themselves or a loved one contracting and dying from the virus. This is compounded by the plethora of the psychosocial and economic impacts of the pandemic we see every day. Most are making this worse by checking their phones for updates several times a day or more. The additional burden of unemployment, piles of unpaid bills, social isolation and increasing marital discord are felt in many homes. Current data show that divorce rates in the U.S. have soared by 34% during the COVID-19 pandemic with marriages starting to crumble just three weeks into quarantine. Newlywed separation has doubled. The overall prevalence of anxiety, depression, insomnia and harmful alcohol use has increased. There are numerous reports in the psychiatric literature regarding COVID-19 related suicides. Social isolation and difficulty getting help have increased suicides rates in the USA and other countries. The Office of the Guam Chief Medical Examiner has recorded 26 suicides from January to August - more than have died from COVID-19. It may be getting worse as 15 suicides were recorded in the last 3 months alone.

Stress management does not need to be painful, overwhelm our schedules or ruin our budgets. A daily 10-minute walk is a great place to start. Dont set an unrealistic goal. Just take a 10-minute stroll every day and take it from there. It is a good idea to avoid caffeine and alcohol. I am concerned about the use of alcohol to self-treat stress and using caffeine as a substitute for sleep. Nicotine consumption here I am actually saying that the goal is zero. Smoking is a surefire way to weaken your immune system. If you are having trouble quitting, get help. Finally, talk to someone you trust. The more you communicate your frustrations of daily life, the better you will be able to handle them and the less likely your stress will negatively impact your immune system.

Dr. Ramel Carlos is a board-certified neurologist practicing in Guam for 18 years and a specialist in epilepsy and clinical neurophysiology. He is also a pediatrician, a diplomate of the American Board of Disability Analysts and the editor-in-chief of The Guam Medical Association Journal.

See the rest here:
A doctor's Rx: How to boost our immune system during the pandemic, part 1 - The Guam Daily Post

Men's delayed immune-system responses to the coronavirus could put them at higher risk of dying from COVID-19 than women, according to a study from University of Washington researchers.

They found that, for women under the age of 60, their immune systems produced a near immediate defense against the virus. However, for men of all ages, it took an average of three days for their bodies to deploy T cells (white blood cells that sense and destroy virus-infected cells)to fight the novel coronavirus.

The researchers came to this conclusion after looking at 430 COVID-19 nasal swab tests 176 from men and 201 from women which they collected from the University of Washington Virology Laboratory between March and August.

This study expanded on previous research, which found women who have COVID-19 (the disease caused by the coronavirus) tend to develop more T cells, which help the body kill coronavirus-infected cells, than men who have COVID-19.

The researchers said the new findings could help to explain why nearly twice as many men have died from COVID-19 than women.

The researchers' findings line up with previous research that suggests a person's sex affects how many virus-fighting cells a person develops when they become sick.

Females have greater amounts of the hormones estrogen, progesterone, and androgen than males, for example.

These hormones are believed to play a role in immune-system response when a person is sick.

An August study in the journal Nature found that women developed more coronavirus-fighting cells than men did, regardless of their age. For women, their age didn't affect how many cells they produced.

"We now have clear data suggesting that the immune landscape in COVID-19 patients is considerably different between the sexes and that these differences may underlie heightened disease susceptibility in men," Akiko Iwasaki, senior author of the August study, said in a press release.

The new study comes with caveats. The researchers of the new study said that their experiment should be duplicated with other bodily fluid samples, since nose swabs aren't the most effective way to test a person's immune response.

Additionally, factors like smoking and preexisting health conditions, not just a person's sex, can make them more susceptible to severe COVID-19 symptoms. Therefore, researchers can't definitively say whether sex created the delayed immune response in men.

Still, the findings suggest men and women's bodies respond differently when they're infected, and that could mean they need different approaches to treatment too.

As Iwasaki told the New York Times, "natural infection is clearly failing" men, who tend to have worse symptoms and higher mortality rates than women when it comes to COVID-19. They might need a more doses of a coronavirus vaccine than women due to their delayed immune responses.

"You could imagine scenarios where a single shot of a vaccine might be sufficient in young individuals or maybe young women, while older men might need to have three shots of vaccine," Marcus Altfeld, an immunologist at the Heinrich Pette Institute in Germany, told the New York Times.

More:
Men may have slower immune response to coronavirus than women: study - Business Insider - Business Insider

A new study suggests immune responses to coronavirus in severely ill and critically ill patients are as strong or stronger than those of patients with milder illness. This adds to the evidence that the immune system itself is to blame for the most life-threatening form of the infection.

Immune cells known as T cells are responsible for recognizing pathogens, killing infected cells, and recruiting other branches of the immune system to combat infections.

However, according to the new study, T cell responses to the new coronavirus in critically ill patients appear to be just as robust as those with a less severe form of the illness.

The finding reinforces the conclusion that an inadequate immune response to SARS-CoV-2, the coronavirus that causes COVID-19, is not responsible for critical illness and death. Rather, an excessive immune response is to blame.

Stay informed with live updates on the current COVID-19 outbreak and visit our coronavirus hub for more advice on prevention and treatment.

The team of researchers, led by Marien Hospital Herne and Ruhr-Universitt Bochum in Herne, Germany, compared the T cell responses of 28 COVID-19 patients during the acute phase of the infection and after recovery in survivors.

Of these infections, 7 were categorized as moderate, 9 were severe, and 12 were critical.

The scientists measured the concentration of two T cell types in blood samples from each patient: helper T cells and killer or cytotoxic T cells.

They also analyzed the strength of these cells responses to three distinct parts of the virus: the three proteins that make up its spikes, its membrane, and the shell or nucleocapsid surrounding its nuclear material.

In addition, the team measured levels of cytokines immune signaling molecules that T cells produce to combat infection.

They found that in patients with critical illness, the scale of their immune responses was similar or even higher, compared with moderate or severe cases.

There were also no apparent associations between successful clearance of the virus or death and changes in T cell responses.

The total number of specific immune cells, as well as their functionality, was not better in patients who survived COVID-19 than in those who died from it, says Dr. Ulrik Stervbo, one of the authors.

The study features in the journal Cell Reports Medicine.

T cells migrate to a viral infection site, where they kill infected cells and select other parts of the immune system to neutralize the virus.

But these same T cells can also create a cytokine storm, which is responsible for a potentially fatal complication known as acute respiratory distress syndrome (ARDS).

Even though further studies will be necessary to understand the specific mechanism of COVID-19 development, our data suggest that excessive SARS-CoV-2-specific T cell response can cause [immune damage] leading to COVID-19-related lung failure, says lead author Prof. Nina Babel.

The new research adds to a growing body of evidence that excessive immune responses cause life-threatening COVID-19.

A major study published in June 2020 found that dexamethasone, a corticosteroid that suppresses the bodys immune response, saved the lives of around a third of all patients on ventilators over a 28-day period.

A more recent study, reported by Medical News Today, suggests that another kind of immune-suppressing drug, known as an interleukin-6 inhibitor, may help prevent severe COVID-19 infections from becoming life-threatening.

The authors of the new study acknowledge some limitations of their research.

They do not know exactly when patients in their research contracted the virus. Therefore, the slightly higher T cell response in critically ill patients may simply result from a longer period of infection.

In addition, they were unable to analyze the entire range of T cell subtypes and the cytokines they produce. So, it is possible that they missed protective or detrimental immune effects that impacted non-critical and critical patients differently.

For live updates on the latest developments regarding the novel coronavirus and COVID-19, click here.

Continued here:
Critically ill patients have robust immunity to new coronavirus - Medical News Today

As the world awaits the arrival of a safe and effective coronavirus vaccine, a team of researchers has come forward with a provocative new theory: that masks might help to crudely immunize some people against the virus.

The unproven idea, described in a commentary published Tuesday in the New England Journal of Medicine, is inspired by the age-old concept of variolation, the deliberate exposure to a pathogen to generate a protective immune response. First tried against smallpox, the risky practice eventually fell out of favor, but paved the way for the rise of modern vaccines.

Masked exposures are no substitute for a bona fide vaccine. But data from animals infected with the coronavirus, as well as insights gleaned from other diseases, suggest that masks, by cutting down on the number of viruses that encounter a persons airway, might reduce the wearers chances of getting sick. And if a small number of pathogens still slip through, the researchers argue, these might prompt the body to produce immune cells that can remember the virus and stick around to fight it off again.

You can have this virus but be asymptomatic, said Dr. Monica Gandhi, an infectious disease physician at the University of California, San Francisco, and one of the commentarys authors. So if you can drive up rates of asymptomatic infection with masks, maybe that becomes a way to variolate the population.

That does not mean people should don a mask to intentionally inoculate themselves with the virus. This is not the recommendation at all, Dr. Gandhi said. Neither are pox parties, she added, referring to social gatherings that mingle the healthy and the sick.

The theory cannot be directly proven without clinical trials that compare the outcomes of people who are masked in the presence of the coronavirus with those who are unmasked an unethical experimental setup. And while outside experts were intrigued by the theory, they were reluctant to embrace it without more data, and advised careful interpretation.

It seems like a leap, said Saskia Popescu, an infectious disease epidemiologist based in Arizona who was not involved in the commentary. We dont have a lot to support it.

Taken the wrong way, the idea could lull the masked into a false sense of complacency, potentially putting them at higher risk than before, or perhaps even bolster the incorrect notion that face coverings are entirely useless against the coronavirus, since they cannot render the wearer impervious to infection.

We still want people to follow all the other prevention strategies, Dr. Popescu said. That means staying vigilant about avoiding crowds, physical distancing and hand hygiene behaviors that overlap in their effects, but cant replace one another.

The coronavirus variolation theory hinges on two assumptions that are difficult to prove: that lower doses of the virus lead to less severe disease, and that mild or asymptomatic infections can spur long-term protection against subsequent bouts of sickness. Although other pathogens offer some precedent for both concepts, the evidence for the coronavirus remains sparse, in part because scientists have only had the opportunity to study the virus for a few months.

Experiments in hamsters have hinted at a connection between dose and disease. Earlier this year, a team of researchers in China found that hamsters housed behind a barrier made of surgical masks were less likely to get infected by the coronavirus. And those who did contract the virus became less sick than other animals without masks to protect them.

A few observations in humans seem to support this trend as well. In crowded settings where masks are in widespread use, infection rates seem to plummet. And although face coverings cannot block all inbound virus particles for all people, they do seem to be linked to less illness. Researchers have uncovered largely silent, symptomless outbreaks in venues from cruise ships to food processing plants, all full of mostly masked people.

Data linking dose to symptoms have been gathered for other microbes that attack the human airway, including influenza viruses and the bacteria that cause tuberculosis.

But despite decades of research, the mechanics of airborne transmission largely remain a black box, said Jyothi Rengarajan, an expert in vaccines and infectious disease at Emory University who was not involved in the commentary.

That is partly because it is difficult to pin down the infectious dose required to sicken a person, Dr. Rengarajan said. Even if researchers eventually settle on an average dose, the outcome will vary from person to person, since factors like genetics, a persons immune status and the architecture of their nasal passages can all influence how much virus can colonize the respiratory tract.

And confirming the second half of the variolation theory that masks allow entry to just enough virus to prime the immune system might be even trickier. Although several recent studies have pointed to the possibility that mild cases of Covid-19 can provoke a strong immune response to the coronavirus, durable protection cannot be proven until researchers gather data on infections for months or years after these have resolved.

On the whole, the theory has some merits, said Angela Rasmussen, a virologist at Columbia University who was not involved in the commentary. But Im still pretty skeptical.

It is important to remember, she said, that vaccines are inherently less dangerous than actual infections, which is why practices like variolation (sometimes called inoculation) eventually became obsolete. Before vaccines were discovered, doctors made do by rubbing bits of smallpox scabs or pus into the skin of healthy people. The resulting infections were usually less severe than smallpox cases caught the typical way, but people definitely got smallpox and died from variolation, Dr. Rasmussen said. And variolation, unlike vaccines, can make people contagious to others.

Dr. Gandhi acknowledged these limitations, noting that the theory should not be construed as anything other than that a theory. Still, she said, Why not drive up the possibility of not getting sick and having some immunity while were waiting for the vaccine?

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A New Theory Asks: Could a Mask Be a Crude Vaccine? - The New York Times

Peng Y, Mentzer AJ, Liu G, Yao X, Yin Z, Dong D, Dejnirattisai W, Rostron T, Supasa P, Liu C, Lpez-Camacho C, Slon-Campos J, Zhao Y, Stuart DI, Paesen GC, Grimes JM, Antson AA, Bayfield OW, Hawkins DEDP, Ker DS, Wang B, Turtle L, Subramaniam K, Thomson P, Zhang P, Dold C, Ratcliff J, Simmonds P, de Silva T, Sopp P, Wellington D, Rajapaksa U, Chen YL, Salio M, Napolitani G, Paes W, Borrow P, Kessler BM, Fry JW, Schwabe NF, Semple MG, Baillie JK, Moore SC, Openshaw PJM, Ansari MA, Dunachie S, Barnes E, Frater J, Kerr G, Goulder P, Lockett T, Levin R, Zhang Y, Jing R, Ho LP, Cornall RJ, Conlon CP, Klenerman P, Screaton GR, Mongkolsapaya J, McMichael A, Knight JC, Ogg G, Dong T. Broad and strong memory CD4+ and CD8+ T cells induced by SARS-CoV-2 in UK convalescent individuals following COVID-19. Nat. Immunol.2020 Sep 04 [Epub ahead of print]. doi: 10.1038/s41590-020-0782-6. PMID: 32887977. View full text

Link:
Robust T Cell Response and Immune Memory in Recovered COVID-19 Patients - Medscape

One of the major challenges facing gene therapy - a way to treat disease by replacing a patients defective genes with healthy ones - is that it is difficult to safely deliver therapeutic genes to patients without the immune system destroying the gene, and the vehicle carrying it, which can trigger life-threatening widespread inflammation.

Three decades ago researchers thought that gene therapy would be the ultimate treatment for genetically inherited diseases like hemophilia, sickle cell anemia and genetic diseases of metabolism. But the technology couldnt dodge the immune response.

Since then, researchers have been looking for ways to perfect the technology and control immune responses to the gene or the vehicle. However, many of the strategies tested so far have not been completely successful in overcoming this hurdle.

Drugs that suppress the whole immune system, such as steroids, have been used to dampen the immune response when administering gene therapy. But its difficult to control when and where steroids work in the body, and they create unwanted side effects. My colleague Mo Ebrahimkhani and I wanted to tackle gene therapy with immune-suppressing tools that were easier to control.

I am a medical doctor and synthetic biologist interested in gene therapy because six years ago my father was diagnosed with pancreatic cancer. Pancreatic cancer is one of the deadliest forms of cancer, and the current available therapeutics usually fail to save patients. As a result, novel treatments such as gene therapy might be the only hope.

Yet, many gene therapies fail because patients either already have pre-existing immunity to the vehicle used to introduce the gene or develop one in the course of therapy. This problem has plagued the field for decades, preventing the widespread application of the technology.

Traditionally scientists use viruses - from which dangerous disease-causing genes have been removed - as vehicles to transport new genes to specific organs. These genes then produce a product that can compensate for the faulty genes that are inherited genetically. This is how gene therapy works.

Though there have been examples showing that gene therapy was helpful in some genetic diseases, they are still not perfect. Sometimes, a faulty gene is so big that you cant simply fit the healthy replacement in the viruses commonly used in gene therapy.

Another problem is that when the immune system sees a virus, it assumes that it is a disease-causing pathogen and launches an attack to fight it off by producing antibodies and immune response just as happens when people catch any other infectious viruses, like SARS-CoV-2 or the common cold.

Recently, though, with the rise of a gene editing technology called CRISPR, scientists can do gene therapy differently.

CRISPR can be used in many ways. In its primary role, it acts like a genetic surgeon with a sharp scalpel, enabling scientists to find a genetic defect and correct it within the native genome in desired cells of the organism. It can also repair more than one gene at a time.

Scientists can also use CRISPR to turn off a gene for a short period of time and then turn it back on, or vice versa, without permanently changing the letters of DNA that makes up or genome. This means that researchers like me can leverage CRISPR technology to revolutionize gene therapies in the coming decades.

But to use CRISPR for either of these functions, it still needs to be packaged into a virus to get it into the body. So some challenges, such as preventing the immune response to the gene therapy viruses, still need to be solved for CRISPR-based gene therapies.

Being trained as a synthetic biologist, I teamed up with Ebrahimkhani to use CRISPR to test whether we could shut down a gene that is responsible for immune response that destroys the gene therapy viruses. Then we investigated whether lowering the activity of the gene, and dulling the immune response, would allow the gene therapy viruses to be more effective.

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A gene called Myd88 is a key gene in the immune system and controls the response to bacteria and viruses, including the common gene therapy viruses. We decided to temporarily turn off this gene in the whole body of lab animals.

We injected animals with a collection of the CRISPR molecules that targeted the Myd88 gene and looked to see whether this reduced the quantity of antibodies that were produced to specifically fight our gene therapy viruses. We were excited to see that the animals that received our treatment using CRISPR produced less antibody against the virus.

This prompted us to ask what happens if we give the animal a second dose of the gene therapy virus. Usually the immune response against a gene therapy virus prevents the therapy from being administered multiple times. Thats because after the first dose, the immune system has seen the virus, and on the second dose, antibodies swiftly attack and destroy the virus before it can deliver its cargo.

We saw that animals receiving more than one dose did not show an increase in antibodies against the virus. And, in some cases, the effect of gene therapy improved compared with the animals in which we had not paused the Myd88 gene.

We also did a number of other experiments that proved that tweaking the Myd88 gene can be useful in fighting off other sources of inflammation. That could be useful in diseases like sepsis and even COVID-19.

While we are now beginning to improve this strategy in terms of controlling the activity of the Myd88 gene. Our results, now published in Nature Cell Biology,provide a path forward to program our immune system during gene therapies and other inflammatory responses using the CRISPR technology.

Here is the original post:
CRISPR can help combat the troubling immune response against gene therapy - The Conversation US

Since the first vaccine was developed in 1796, vaccinations have been phenomenally successful at preventing infectious diseases, and wiping out some altogether.

The latest video in our new YouTube series, Science with Sam, explains how vaccines work by training your immune system to recognise viruses and bacteria. Ever wondered how flu vaccines are made or why you need a new one every year? Click play to find out.

We also take a look at the unprecedented worldwide effort to develop a vaccine for the coronavirus, and consider the challenges involved in making, testing and distributing covid-19 vaccines.

Tune in every week toyoutube.com/newscientistfor a new episode, or check back tonewscientist.com

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Most of us have never had to worry about getting smallpox, polio or diphtheria. A hundred years ago, these diseases were common killers. Now, smallpox is a thing of the past, while polio and diphtheria are very rare in most of the world. The reason? Vaccines.

Vaccines are a way of training the immune system for a big fight, so that when it comes up against the same opponent in the future, it knows exactly how to defeat it.

When you encounter a virus or bacterium for the first time, your body has a hard time fighting it. But over time, it learns to recognise the danger. Your immune system produces powerful proteins called antibodies that target and eliminate disease-causing microbes.

After you recover from an infection, specialised cells remain in your blood and keep a memory of that pathogen theyre called memory cells so the next time you face the pathogen, your body can quickly produce the right antibodies to fight it off.

Vaccines are a clever way of harnessing this mechanism to make us immune to a disease. They are made of weakened or killed viruses or bacteria that trigger an immune response, without making us ill.

The first vaccine was developed in 1796 by Edward Jenner. At the time It was commonly believed that dairymaids were immune to smallpox because they were commonly exposed to cowpox, which is a related but less deadly virus. Jenner decided to test this idea by injecting an 8-year-old boy with pus from a dairy maids cowpox lesions. A few months later he injected the boy with smallpox and found the boy was indeed immune. Who said ever said science was pretty?

Since then, vaccination programmes have been extremely successful at preventing diseases, and even eliminating some altogether. Smallpox, a disease that killed around 300 million people in the 20th century, was finally eradicated in 1980.

What about the coronavirus? Right now, there are over 100 vaccines currently in development. Scientists have moved incredibly quickly, considering we knew almost nothing about this virus at the start of this year. It normally takes years to get to this point. The fastest vaccine ever developed before was for Ebola and that took five years.

There are several different ways to make a vaccine being tried. One is to use whole viruses that have been inactivated so they cant cause a full infection. This might be done by killing them with heat.

Then there are vaccines that are made from live viruses, but they are weakened so they wont grow well in the human body. These vaccines tend to generate a strong and long-lasting immune response. For example the MMR vaccine, for measles, mumps and rubella, contains three live viruses.

Some vaccines put viral molecules into the body the important bits that our immune cells can recognise rather than whole viruses. This is how the injected flu vaccine works, and several groups are working on coronavirus vaccines like this.

The flu virus, or influenza, is a particularly difficult virus to vaccinate against, because there are many variants, or strains, that circulate. Its like the virus has many hats, and changes them often, and that makes it hard for our immune system to recognise it when a new one comes around. To produce the vaccine, the virus has to be grown in chicken eggs in a process that takes many months and millions of eggs. Every year virologists have to predict which flu strains are going to dominate in the next season, so that companies can make enough doses to meet demand. Sometimes they get it wrong, and even when theyre right, the mutating virus might mean the vaccine doesnt work as well as we hoped.

What we really want is a universal flu vaccine based on parts of the virus that dont change. Research on that is ongoing, but unfortunately it doesnt get as much investment as it needs

A relatively new approach that is being investigated is to make a vaccine containing the genetic instructions for making viral proteins, in the form of DNA or RNA. Once inside the body, the genetic code causes a persons cells to produce distinctive proteins normally found on the virus. These proteins trigger an immune response, and that creates an immunological memory.

The University of Oxford is working on a vaccine that uses a harmless virus to deliver the viral genes into cells. Its based on a virus that causes colds in chimpanzees, but its been genetically modified so that it cant reproduce in humans. The first clinical trials have shown that it is safe and induces a strong immune response.

For all the latest news on vaccines and the coronavirus why not subscribe to New Scientist? Theres a special discount code for you: get a 20 per cent discount by entering the code SAM20.

Despite all the effort being put into coronavirus vaccines, theres no guarantee that this will give us the magic bullet were looking for. Theres so much we dont know about how our immune systems respond to the virus and it may not even be possible to generate long-term immunity. A vaccine might mean you just get a bit less sick from the disease, and you might need a new dose each year.

Then there is the challenge of manufacturing and distributing billions of doses to every country in the world. It may take years to make enough to go around, raising tricky questions about who should be first in line. Some countries including the UK have made deals to get their hands on the first shipments, before the vaccines have been proven to work.

To defeat the pandemic, we need to make sure everyone who needs vaccines has access to them. We need to think globally, cooperatively, and act less like children squabbling over cookies.

To successfully wipe out a disease, a large proportion of the population needs to be inoculated, creating what is known as herd immunity, meaning there are enough immune people in the population to stop a virus from circulating. That brings us to another problem: some people are deeply sceptical about vaccines, which could be an obstacle to getting vaccination rates up to the levels required.

This mistrust has been fuelled by unfounded scare stories, such as the false idea that the MMR vaccine causes autism. All vaccines have to be rigorously assessed for their safety before they are used widely, and continue to be monitored after they are rolled out. Large clinical trials have repeatedly found no link between the MMR vaccine and autism.

Despite this, rising anti-vaccination sentiment has led to a surge in measles in the US,with more than 1000 cases reported in 2019. And in a recent survey, 1 in 4 people in the US said they wouldnt take a coronavirus vaccine if it was available.

According to the World Health Organization, immunisations prevent an estimated 2-3 million deaths every year, in people from all age groups. By any measure, vaccines are one of the most successful innovations humankind has ever come up with. The coronavirus has reminded us just how vulnerable we are to infections, and that new diseases can emerge at any moment. Vaccines are our best hope for defeating them.

What is a black hole? And could you survive one?

Is our reality just one part of a multiverse?

More on these topics:

Read more from the original source:
What is a vaccine and how do they work? Find out in Science with Sam - New Scientist

In a season when we would usually be out cheering on our local sports teams, we are spending more time at home and repeating a new mantra: Wash your hands, practice social distancing, wear a mask.

But what if you could play offense instead of defense to fend off colds and viruses? What if adjusting your daily habits could build your immunity to help your body fend off illness, not only this year but every year?

Thats not only possible, says Katie Moksnes Bowman, its something she encourages her patients to do every day.

Stress is the number one way we increase inflammation in the body, says Moksnes Bowman, a licensed acupuncturist and Doctor of Acupuncture and Chinese Medicine (DACM) for Northwestern Health Sciences University. She says inflammation can affect digestion, sleep patterns, pain, and your bodys immunity.

The key to improving your immunity is to reduce inflammation in your body.

The amount of stress that has been created from the pandemic is causing issues for people physically and emotionally, she says. In Chinese medicine, your digestion matters, sleep matters, your immune system matters.

When I am in practice with a patient, we talk about sleep, bowels, diet and movement at every single treatment. I really want to work with them where theyre at.

She sees patients ranging from professional athletes to seniors with mobility issues and everyone in between, so there is no one-size-fits-all approach to treatment.

In Chinese medicine, we really view the body as a whole, she says. For example, if a patient has shoulder pain, Moksnes Bowman proceeds knowing the shoulder does not work independently from the rest of the body.

"The amount of stress that has been created from the pandemic is causing issues for people physically and emotionally. In Chinese medicine, your digestion matters, sleep matters, your immune system matters." Kate Moksnes Bowman, Northwestern Health Sciences University

If you are not digesting your foods properly, if youre not getting a good nights sleep, she says, I can do a ton of work on your shoulder, but its not going to repair well.

To help patients improve their health and build their immunity, she suggests small changes in diet and exercise, such as drinking enough water, reducing caffeine and sugar consumption, adding anti-inflammatory foods to their diet, and getting more movement every day.

I am not going to overhaul your whole diet, she says. If you do not want to stop eating pizza, I cannot make you stop eating pizza. But she might suggest that you try goat cheese on your pizza or sample a cauliflower crust.

I see myself as a reminder person, she says. I have patients come in and I say, How did your diet go this week? Did you eat something green? That means a plant, you know, not a green Jolly Rancher.

That question always gets a laugh, but the point is that little changes can make a difference in reducing inflammation and improving immunity.

When we are talking about diet and exercise, both of those things reduce inflammation and so does sleeping. Sleeping is a time to repair your body, Moksnes Bowman says. Asked what tops her list as the most important step, she says: Its not a hierarchy for me. Its more of a circle than a list, because all of those things are going to influence the next thing.

Small adjustments in diet and exercise are something patients do on their own between clinic visits, where Moksnes Bowman and other practitioners offer a range of therapies, from acupuncture and massage to cupping, Gua Sha, herbal medicine and even recipes to help improve your immunity.

If you have a lot of stress and are getting the common cold five times a winter, I would suggest you consider herbal medicine, she says. She advises against buying supplements in the grocery aisle. Seek a health professional who is specialized before taking Vitamin D, C or Elderberry syrup. They are all really good things, but theyre not always the right thing for everybody. Its always important to make sure you are taking the right amount.

Creating good sleep habits and a good sleeping environment are important, too. If you are on your phone or watching TV at night, the blue light from the device stimulates a part of the brain that doesn't allow you to fall asleep as well, she says.

Improved diet and exercise, combined with acupuncture or other types of Chinese medicine, can reduce inflammation over time by increasing blood flow and releasing endorphins, which Moksnes Bowman describes as that calm, happy hormone. That is our own bodys way of reducing pain in the body.

And that calm, happy hormone can lead to a good nights sleep, as described in a text from one of Moksnes Bowmans patients, who said: I cant believe how much my sleep improved by getting acupuncture.

The results arent anecdotal, she says. Sleep-tracking devices demonstrate that acupuncture can improve sleep; they record how well and deeply you are sleeping and if you are waking frequently during the night.

And while youre getting those extra ZZZs, your body is resting and fortifying its immunity.

One of the side effects of social distancing and working from home has been an increase in loneliness. Moksnes Bowman says that after a brief shutdown of the NWHSU Bloomington Clinic several months ago, she noticed two things when the clinic reopened: Patients who had missed appointments were in pain, and they were lonely.

People wanted to talk for so long, she says. I made my treatments a bit longer so patients could just talk, because people were feeling lonely.

She and other practitioners frequently refer patients to therapists, Tai Chi or Pilates instructors or others when they see an opportunity to help the patient move, relax or sort things out. Taking a deep breath and getting some release is also good for building a sense of well-being.

Think of amping up your immune system as the ultimate DIY project. Add some green to your diet, make sure you drink enough water, cut out some caffeine and get enough sleep for starters, and then add some acupuncture or massage. Together those steps can help fortify your immunity.

And keep in mind that this year, none of that replaces the need to frequently wash your hands, socially distance wherever possible and wear a mask when its not.

___________________________________________________________________________

Located in Bloomington,Northwestern Health Sciences Universityis a pioneer in integrative natural health care education, offering degree programs in chiropractic, acupuncture, Chinese medicine, massage therapy, medical assisting, medical laboratory programs, post-bac/pre-health, radiation therapy, and B.S. completion. At press time, itsBloomington clinicis open to the public and services include chiropractic care, Chinese medicine, massage therapy, naturopathic medicine, Bloomington Clinic offers integrative, natural care for the entire family in one location.

Each monththe Bloomington Clinic providers host a Provider Talks webinar that discusses topics from foot health to the ABZzzzs of Sleep to Promoting Health through the Seasons. Learn more about the webinar serieshere.

Telemedicine is a convenient way to care for yourself during these unprecedented times. Appointment times vary depending on the service. Providers are part ofNorthwestern Health Sciences University, a non-profit industry leader in integrative and natural healthcare education that provides access to the latest evidence and state-of-the-art technology so you get the natural solutions you truly need.

See more content fromNorthwestern Health Sciences University.

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Immune-Boosting Strategies to Stay Ahead of the Cold - Mpls.St.Paul Magazine

As we continue to navigate the global pandemic more attention is being focused on a long sought after vaccine. Dr. Greg talks withJerry Woodward, a professor of Microbiology, Immunology and Molecular Genetics who led a preclinical study at UK on one particular vaccine that shows promise. He also discusses the efficacy of producing a shot once a vaccine is tested and approved.

From UK Now:

PDS Biotechnology, a clinical stage immunotherapy company,has announcedpositive results from preclinical testing conducted at the University of Kentucky College of Medicine of its COVID-19 vaccine candidate, PDS0203.

PDS0203 stands out among COVID-19 vaccines currently in development because it includes a vaccine technology pioneered by PDS Biotech called Versamune, which stimulates important parts of the immune system to activate T cells.

Versamuneactivates an important immunological signaling pathway known to be essential in the induction of both anti-viral and anti-tumor immune responses.It also more efficient at presenting the disease-associated protein to immunological pathways that activate both CD8 (killer) and CD4 (helper) T cells that can recognize, kill and protect against a specific disease.

The most effective vaccines stimulate both antibody and T cells because both of those arms of the immune system are important to eliminate different viral infections, said Jerry Woodward, a professor of Microbiology, Immunology and Molecular Genetics who led the preclinical study at UK. While many of the vaccines out there stimulate a good antibody response, they dont always activate T cells. Thats one of the key advantages of the Versamunetechnology.

PDS0203 combines Versamunenanoparticles with a protein recognized by the human immune system that is derived from SARS-CoV-2, the virus that causes COVID-19. Prototype vaccines were tested at UK based on various recombinant SARS-CoV-2 proteins, including protein constructs created by UKs Protein Core lab.

In mouse models, PDS0203 showed strong activation of both protective antibodies as well as highly active and potent virus-specific CD8 killer and CD4 helper T cells within 14 days of treatment.PDS Biotech is submitting the findings to a peer-reviewed scientific journal and is expected to advance the PDS0203 vaccine to a phase 1 safety and immunogenicity clinical trial in humans.

To test the antibody arm of the immune response, mice are vaccinated and serum is separated from blood samples and tested for the amount of antibodies that will bind to the protein. To test the T cell arm of the immune response, T cells are isolated from the mice and tested for their ability to directly respond to peptides, or short pieces of protein, which are derived from the SARS-Cov-2protein. The results have been promising, Woodward says.

Vaccination with the recombinant proteins including the spike protein alone elicits lower levels of antibody response and almost no T cell response, Woodward said. When Versamuneis added, it dramatically increases both the antibody and T cell immune responses.

PDS Biotech contracts with expert labs like Woodwards for independent analysis of vaccine efficacy and research in the development of novel cancer therapies and infectious disease vaccines. Woodwards lab has been working with the company for several years, and recently received funding from the National Institutes of Allergy and Infectious Diseases to complete preclinical development of a Versamune-based universal influenza vaccine to provide broad protection against multiple strains of the flu virus. This spring, the focus of Woodwards collaboration with PDS Biotech expanded primarily from cancer to address the COVID-19 pandemic.

Versamunepresents unique potential for a vaccine to provide the level of immune response needed for protection against COVID-19, Woodward says.

Were optimistic an effective COVID-19 vaccine will be available relatively soon. There are probably over a hundred companies working on different vaccines and a lot of them are probably going to work," Woodward said."I believe that the Versamune-based vaccine due to its mechanism of action, simplicity and preliminary efficacy and human safety data, has excellent potential to be one of the more successful global vaccines.

Read more:
Meet A COVID Vaccine Researcher Here At UK This Week On Dr. Greg - WUKY

The medtech industry has borne the brunt of the COVID-19, and though strained for revenues, it has shown resilience and commitment by working unrelentingly to ensure availability of products (for both COVID and non-COVID emergencies) across the country. The medtech industry is in dire need of stimuli says Pavan Choudary, Chairman & Director General, Medical Technology Association of India and reiterates the policy changes required to reinvigorate the sector and ease some of the burden placed on this nascent industry, Chairman & Director General, Medical Technology Association of India narrates how the sector has also ensured that regular servicing and maintenance of capital equipment at the hospitals continues despite the financial blows it has taken.

The medtech industry is now in dire need of stimuli says Choudary and reiterates the policy changes required to reinvigorate the sector and ease some of the burden placed on this nascent industry

The unprecedented situation created by COVID-19 has resulted in alarm bells ringing across industries. After multiple lockdowns to curb the spread of infection, we are now in the phase of unlock 3.0 where businesses are cautiously starting to resume operations.

The corridor of uncertainty in the last six months has battered Indias economy which is projected to contract by 4.5 per cent this fiscal according to the International Monetary Fund (IMF). The collateral effect of the lockdowns has been sorely felt as several sectors including automobile, aviation, textiles, tourism, hospitality, real estate and electronics had almost completely come to a standstill. During this time, and in the absence of a vaccine or a reliable therapeutic remedy, the country relied on its healthcare and medical technology industry to spearhead the fight against COVID-19; and they have delivered, with uncanny grit and commitment.

The medtech sector has shown great determination in the face of adversity to ensure continued supply of critical medical devices and services, despite being bogged down by several operational issues like scarcity of contractual manpower for loading and un-loading, restrictive movement of service personnel and goods in several areas, stalling of customs clearance of imports, etc. The industry is also reeling under taxing financial challenges like escalation in costs due to the hike in freight charges, at the same time it has been hit by significant fall in revenue due to postponement and cancellation of elective procedures which drive a large part of the demand for medical devices.

It is estimated that medical technology industry has suffered a 50-85 per cent drop in revenue across categories in April-June due to the situation. Slicing the data category wise shows us that the cardiology category experienced a downfall in revenue up to 60 per cent in the first quarter of the financial year. The orthopaedic industry encountered an even bigger fall in revenue to an extent of up to 85 per cent. The opthalmology sector also recorded a similar impact as its revenue fell up to 75 per cent during April-June, 2020. Even the critical care device segment fell to nearly half. These challenges have been further compounded by the falling INR value, high basic customs duty rate and the newly imposed health cess on imported medical devices.

The medical device industry has borne the brunt of these issues, and has been strained for revenues, it is bleeding, yet has shown resilience and commitment by working unrelentingly to ensure availability of products (for both COVID and non-COVID emergencies) across the country. It has also ensured that regular servicing and maintenance of capital equipment at the hospitals continues despite the financial blows it has taken.

Several global medtech companies have even gone further by bringing COVID specific product designs and specifications (ventilators, face shields, medical beds) from the US into India to work with local manufacturers to manufacture in India and plug any potential holes in the supply.

Another significant impact of COVID-19 situation has been on the employment across sectors in India. According to data from the Center for Monitoring Indian Economy (CMIE), Indias overall unemployment rate as on August 13, 2020 stood at 7.9 per cent and is expected to settle at a higher level than seen before the COVID-19 induced lockdown. In the medical device sector, the effects of shrinking margins of hospitals can be seen at the channel and service dealership networks, and sub-dealers are already experiencing significant workforce downsizing. So far the global medtech fraternity have heeded to the governments request of protecting the jobs of its workforce, even while facing significant financial blows. However if the situation does not improve, these efforts may not be sustainable.

The medtech industry is in dire need of stimuli; to reinvigorate the sector the government must look towards easing some of the burden it has placed on this nascent industry. For the next steps, the government should consider removing the high customs duty on imported medical devices this would also increase healthcare affordability for patients at a time they need it the most, if this is not possible then at the minimum the government must roll back the additional burden of health cess imposed on imported medical devices, it must also look at ways to facilitate the resumption of elective procedures by issuing safety SOPs/ guidelines, this will go a long way in restoring the revenue streams of the medtech industry. The sector which is championing the fight against the pandemic cannot be allowed to crumble, for India will not be able to sustain its fall.

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How Indian medtech is battling the COVID-19 pandemic - Express Healthcare

Overview Of Absorbable and Non-Absorbable Sutures Industry 2020-2028:

This has brought along several changes in This report also covers the impact of COVID-19 on the global market.

The Absorbable and Non-Absorbable Sutures Market analysis summary by Reports Insights is a thorough study of the current trends leading to this vertical trend in various regions. Research summarizes important details related to market share, market size, applications, statistics and sales. In addition, this study emphasizes thorough competition analysis on market prospects, especially growth strategies that market experts claim.

Absorbable and Non-Absorbable Sutures Market competition by top manufacturers as follow: B. Braun Melsungen AG, Ethicon, Smith & Nephew, Demetech Corporation, Conmed Corporation, W.L. Gore & Associates, Tepha, Meta Biomed, Zimmer Biomet, CP Medical, Miltex (A Integra LifeSciences Corporation Company), Assut Medical Sarl, DyNek Pty, Footberg, Stoelting, Unimed Medical Industries, Teleflex Incorporated, Boston Scientific Corporation, Medtronic, Surgical Specialties Corporation, Resorba Medical GmbH, Medline Industries, AD Surgical, Santec Medicalprodukte, Clinisut, Coreflon, Aspen Surgical, Medipac, Sutures, Pierson Surgical

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The global Absorbable and Non-Absorbable Sutures market has been segmented on the basis of technology, product type, application, distribution channel, end-user, and industry vertical, along with the geography, delivering valuable insights.

The Type Coverage in the Market are:

Absorbable SuturesNon-Absorbable Sutures

Market Segment by Applications, covers:

CardiovascularOrthopedicGynecologyOpthalmologyGeneral SurgeryOthers

Market segment by Regions/Countries, this report coversNorth AmericaEuropeChinaRest of Asia PacificCentral & South AmericaMiddle East & Africa

Major factors covered in the report:

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New Comprehensive Report on Absorbable and Non-Absorbable Sutures Market to Witness an Outstanding Growth during 2020 2028 with Top Players Like...

-Parkinsons Disease R&D Day to be hosted by Gavin Corcoran, MD, Chief R&D Officer, on October 30th, 2020, with leading movement disorder specialists

NEW YORK and BASEL, Switzerland, Sept. 08, 2020 (GLOBE NEWSWIRE) -- Axovant Gene Therapies Ltd (Nasdaq: AXGT), a clinical-stage company developing innovative gene therapies, today announced that the company will provide a corporate overview and participate in 1:1 meetings at upcoming virtual investor and patient conferences in September. Additionally, the company announced plans for their 1st Parkinsons Disease R&D Day with key opinion leaders.

Investor and Patient Conference Presentation details:

A live webcast of the presentations will be available in the Events section of Axovant's website at http://www.axovant.com. A replay will be available for approximately 30 days following the conference.

About Axovant Gene Therapies

Axovant Gene Therapies is a clinical-stage gene therapy company focused on developing a pipeline of innovative product candidates for debilitating neurodegenerative diseases. Our current pipeline of gene therapy candidates target GM1 gangliosidosis, GM2 gangliosidosis (also known as Tay-Sachs disease and Sandhoff disease), and Parkinsons disease. Axovant is focused on accelerating product candidates into and through clinical trials with a team of experts in gene therapy development and through external partnerships with leading gene therapy organizations. For more information, visit http://www.axovant.com.

Contacts:

Media & Investors

Parag MeswaniAxovant Gene Therapies Ltd.(212) 547-2523media@axovant.cominvestors@axovant.com

Source:Axovant Gene Therapies

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Axovant Announces First Parkinson's Disease Gene Therapy R&D Day and Participation in Upcoming September Conferences" - GlobeNewswire

One of the major challenges facing gene therapy a way to treat disease by replacing a patients defective genes with healthy ones is that it is difficult to safely deliver therapeutic genes to patients without the immune system destroying the gene, and the vehicle carrying it, which can trigger life-threatening widespread inflammation.

Three decades ago researchers thought that gene therapy would be the ultimate treatment for genetically inherited diseases like hemophilia, sickle cell anemia and genetic diseases of metabolism. But the technology couldnt dodge the immune response.

Since then, researchers have been looking for ways to perfect the technology and control immune responses to the gene or the vehicle. However, many of the strategies tested so far have not been completely successful in overcoming this hurdle.

Drugs that suppress the whole immune system, such as steroids, have been used to dampen the immune response when administering gene therapy. But its difficult to control when and where steroids work in the body, and they create unwanted side effects. My colleague Mo Ebrahimkhani and I wanted to tackle gene therapy with immune-suppressing tools that were easier to control.

I am a medical doctor and synthetic biologist interested in gene therapy because six years ago my father was diagnosed with pancreatic cancer. Pancreatic cancer is one of the deadliest forms of cancer, and the current available therapeutics usually fail to save patients. As a result, novel treatments such as gene therapy might be the only hope.

Yet, many gene therapies fail because patients either already have pre-existing immunity to the vehicle used to introduce the gene or develop one in the course of therapy. This problem has plagued the field for decades, preventing the widespread application of the technology.

Traditionally scientists use viruses from which dangerous disease-causing genes have been removed as vehicles to transport new genes to specific organs. These genes then produce a product that can compensate for the faulty genes that are inherited genetically. This is how gene therapy works.

Though there have been examples showing that gene therapy was helpful in some genetic diseases, they are still not perfect. Sometimes, a faulty gene is so big that you cant simply fit the healthy replacement in the viruses commonly used in gene therapy.

Another problem is that when the immune system sees a virus, it assumes that it is a disease-causing pathogen and launches an attack to fight it off by producing antibodies and immune response just as happens when people catch any other infectious viruses, like SARS-CoV-2 or the common cold.

Recently, though, with the rise of a gene editing technology called CRISPR, scientists can do gene therapy differently.

CRISPR can be used in many ways. In its primary role, it acts like a genetic surgeon with a sharp scalpel, enabling scientists to find a genetic defect and correct it within the native genome in desired cells of the organism. It can also repair more than one gene at a time.

Scientists can also use CRISPR to turn off a gene for a short period of time and then turn it back on, or vice versa, without permanently changing the letters of DNA that makes up or genome. This means that researchers like me can leverage CRISPR technology to revolutionise gene therapies in the coming decades.

But to use CRISPR for either of these functions, it still needs to be packaged into a virus to get it into the body. So some challenges, such as preventing the immune response to the gene therapy viruses, still need to be solved for CRISPR-based gene therapies.

Being trained as a synthetic biologist, I teamed up with Ebrahimkhani to use CRISPR to test whether we could shut down a gene that is responsible for immune response that destroys the gene therapy viruses. Then we investigated whether lowering the activity of the gene, and dulling the immune response, would allow the gene therapy viruses to be more effective.

CRISPR can precisely remove even single units of DNA. KEITH CHAMBERS/SCIENCE PHOTO LIBRARY/Getty Images

A gene called Myd88 is a key gene in the immune system and controls the response to bacteria and viruses, including the common gene therapy viruses. We decided to temporarily turn off this gene in the whole body of lab animals.

We injected animals with a collection of the CRISPR molecules that targeted the Myd88 gene and looked to see whether this reduced the quantity of antibodies that were produced to specifically fight our gene therapy viruses. We were excited to see that the animals that received our treatment using CRISPR produced less antibody against the virus.

This prompted us to ask what happens if we give the animal a second dose of the gene therapy virus. Usually the immune response against a gene therapy virus prevents the therapy from being administered multiple times. Thats because after the first dose, the immune system has seen the virus, and on the second dose, antibodies swiftly attack and destroy the virus before it can deliver its cargo.

We saw that animals receiving more than one dose did not show an increase in antibodies against the virus. And, in some cases, the effect of gene therapy improved compared with the animals in which we had not paused the Myd88 gene.

We also did a number of other experiments that proved that tweaking the Myd88 gene can be useful in fighting off other sources of inflammation. That could be useful in diseases like sepsis and even COVID-19.

While we are now beginning to improve this strategy in terms of controlling the activity of the Myd88 gene. Our results, now published in Nature Cell Biology,provide a path forward to program our immune system during gene therapies and other inflammatory responses using the CRISPR technology.

Samira Kiani, Associate Professor of Pathology, University of Pittsburgh

This article is republished from The Conversation under a Creative Commons license. Read the original article.

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CRISPR Can Help Combat the Troubling Immune Response Against Gene Therapy - Gizmodo Australia

New Jersey, United States, The Gene Therapy Market report 2020 provides a detailed impression, describe the product industry scope and the market expanded insights and forecasts up to 2027. It shows market data according to industry drivers, restraints and opportunities, analyzes the market status, the industry share, size, future Trends and growth rate of the market. The Gene Therapy Market report is categorized by application, end user, technology, product / service types, and other, as well as by region. In addition, the report includes the calculated expected CAGR of chitosan acetate-market derivative from the earlier records of the Gene Therapy Market, and current market trends, which are organized with future developments.

Gene Therapy Market was valued at USD 3.69 Billion in 2019 and is projected to reach USD 24.78 Billion by 2027, growing at a CAGR of 26.9% from 2020 to 2027.

Gene Therapy Market, By Product

Viral Vectorso Adeno-associated virus vectorso Retroviral vectors Gammaretroviral vectors Lentiviral vectorso Other viral vectors (herpes simplex and adenoviral vectors) Non-viral Vectorso Oligonucleotideso Other non-viral vectors (plasmids and RNAi)

Gene Therapy Market, By Indication

Neurological Diseases Cancer Hepatological Diseases Duchenne Muscular Dystrophy Other Indications

Gene Therapy Market, By Delivery Method

Ex vivo In vivo

The report provides detailed coverage of the Gene Therapy Market, including structure, definitions, applications, and Industry Chain classifications. The Gene Therapy Market analysis is provided for the international markets including development trends, competitive landscape analysis, investment plan, business strategy, opportunities and development status of key regions. Development policies and plans are discussed and manufacturing processes and cost structures analyzed. This report also includes information on import / export consumption, supply and demand, costs, industry share, policy, Price, Sales and gross margins.

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Gene Therapy Market forecast up to 2027, with information such as company profiles, product picture and specification, capacity production, price, cost, revenue, and contact information. Upstream raw materials and equipment as well as downstream demand analyses are also carried out. The Gene Therapy Market size, development trends and marketing channels are analyzed. Finally, the feasibility of new investment projects is assessed and general research results are offered.

The Gene Therapy Market was created on the basis of an in-depth market analysis with contributions from industry experts. The report covers the growth prospects in the coming years and the discussion of the main providers.

To understand how the effects of COVID-19 are addressed in this report. A sample copy of the report is available at https://www.verifiedmarketresearch.com/product/gene-therapy-market/?utm_source=TDC&utm_medium=001

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Gene Therapy Market is Thriving Worldwide 2020 | Trends, Growth and Profit Analysis, Forecast by 2027 - The Daily Chronicle

The report covers the forecast and analysis of the gene therapy market on a global and regional level. The study provides historical data from 2015 to 2018 along with a forecast from 2019 to 2027 based on revenue (USD Million). The study includes drivers and restraints of the gene therapy market along with the impact they have on the demand over the forecast period. Additionally, the report includes the study of opportunities available in the gene therapy market on a global level.

In order to give the users of this report a comprehensive view of the gene therapy market, we have included a competitive landscape and an analysis of Porters Five Forces model for the market. The study encompasses a market attractiveness analysis, wherein all the segments are bench marked based on their market size, growth rate, and general attractiveness.

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The report provides company market share analysis to give a broader overview of the key players in the market. In addition, the report also covers key strategic developments of the market including acquisitions & mergers, new service launches, agreements, partnerships, collaborations & joint ventures, research & development, and regional expansion of major participants involved in the market on a global and regional basis.

The study provides a decisive view of the gene therapy market by segmenting the market based on the type, vector type, therapy area, and regions. All the segments have been analyzed based on present and future trends and the market is estimated from 2019 to 2027. The regional segmentation includes the current and forecast demand for North America, Europe, Asia Pacific, Latin America, and the Middle East and Africa.

Gene therapy is utilized for treating neurodegenerative disorders like Alzheimer, amyotrophic lateral sclerosis, and spinal muscular atrophy. Gene therapy is one of the key treatment kinds that will propel the market growth over the forecast period. Moreover, gene therapy also finds lucrative applications in precision medicine. In addition to this, a rise in the occurrence of cancer is prompting the demand to treat the disease through gene therapy.

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Based on the type, the market can be segregated into Germ Line Gene Therapy and Somatic Gene Therapy. In terms of vector type, the gene therapy industry can be divided into Viral Vectors, Non-Viral Vectors, and Human Artificial Chromosome. On the basis of therapy area, the market for gene therapy can be classified into Cancer, Neurological Diseases, Infectious Diseases, Genetic Disorders, Rheumatoid Arthritis, and Others.

The key players included in this market are Advanced Cell & Gene Therapy, Audentes Therapeutics, Benitec Biopharma, Biogen, Blubird Bio, Inc., Bristol-Myers Squibb Company, CHIESI Farmaceutici SPA, Eurofins Scientific, Geneta Science, Genzyme Corporation, Gilead, GlaxoSmithKline PLC, Human Stem Cells institute, Novartis AG, Orchard Therapeutics, Pfizer Inc., Sangamo therapeutics, Spark therapeutics, and Voyager Therapeutics.

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Gene Therapy Market By Industry Type, By Brand And Major Players 2020-2027 - The Daily Chronicle

TEL AVIV, Israel, Sept. 08, 2020 (GLOBE NEWSWIRE) -- VBL Therapeutics (Nasdaq: VBLT) announced today the successful completion of a Type B pre-IND meeting with the U.S. Food and Drug Administration (FDA) regarding the Company's development plan for VB-601. VB-601 is the Companys lead anti-MOSPD2 antibody for immune-inflammatory indications, for which a briefing package for the pre-IND meeting was submitted in June. Based on the FDA's feedback, VBL plans to advance its IND-enabling activities for VB-601 as planned.

We are very pleased with the outcome of the pre-IND meeting with the FDA, said Dror Harats, M.D., CEO of VBL Therapeutics. VB-601 is a first-in-class product candidate that has a completely novel mechanism of action. It can block the ability of monocyte to migrate to inflammatory sites, no matter which molecules try to attract them in. Therefore, it is important that we have reached alignment with the FDA on the path forward for VB-601. With this green light, we plan to continue to advance VB-601, aiming to start a first-in-human study in the second half of 2021.

About VB-601VBL is advancing a drug development program that is exploring the potential of MOSPD2 (motile sperm domain-containing protein 2), a protein that VBL has identified as a key regulator of cell motility, as a therapeutic target for inflammatory diseases. VB-601 is a proprietary anti-MOSPD2 monoclonal antibody which has potential for treatment of multiple chronic inflammatory diseases.

About VBLVascular Biogenics Ltd., operating asVBL Therapeutics, is a clinical stage biopharmaceutical company focused on the discovery, development and commercialization of first-in-class treatments for cancer. VBLs lead oncology product candidate, ofranergene obadenovec (VB-111), is a first-in-class, targeted anti-cancer gene-therapy agent that is being developed to treat a wide range of solid tumors. It is conveniently administered as an IV infusion once every two months. It has been observed to be well-tolerated in >300 cancer patients and demonstrated activity signals in a VBL-sponsored all comers phase 1 trial as well as in three VBL-sponsored tumor-specific phase 2 studies. Ofranergene obadenovec is currently being studied in a VBL-sponsored phase 3 potential registration trial for platinum-resistant ovarian cancer.

Forward Looking StatementsThis press release contains forward-looking statements. All statements other than statements of historical fact are forward-looking statements, which are often indicated by terms such as anticipate, believe, could, estimate, expect, goal, intend, look forward to, may, plan, potential, predict, project, should, will, would and similar expressions. These forward-looking statements may include, but are not limited to, statements regarding VBLs programs, including VB-601, including their pre-clinical and clinical development, therapeutic potential and clinical results. These forward-looking statements are not promises or guarantees and involve substantial risks and uncertainties. Among the factors that could cause actual results to differ materially from those described or projected herein include uncertainties associated generally with research and development, clinical trials and related regulatory reviews and approvals, the risk that historical clinical trial results may not be predictive of future trial results, that our financial resources do not last for as long as anticipated, and that we may not realize the expected benefits of our intellectual property protection. A further list and description of these risks, uncertainties and other risks can be found in our regulatory filings with theU.S. Securities and Exchange Commission, including in our annual report on Form 20-F for the year endedDecember 31, 2019, and subsequent filings with theSEC. Existing and prospective investors are cautioned not to place undue reliance on these forward-looking statements, which speak only as of the date hereof. VBL Therapeutics undertakes no obligation to update or revise the information contained in this press release, whether as a result of new information, future events or circumstances or otherwise.

INVESTOR CONTACT:

Michael RiceLifeSci Advisorsmrice@lifesciadvisors.com(646) 597-6979

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VBL Therapeutics Announces Successful Completion of Pre-IND Meeting with FDA Regarding Proposed Clinical Development of VB-601 - BioSpace

Seeing a child debilitated by illness is never easy.

When doctors tell youthere is nothing they nor you can do to help ease yourbaby's suffering, well, parents who know that type of helplessness often find it hard to describe.

We were told to take my son home and love him, becausehe probably wouldnt live past his second birthday, said Pace father Todd Hamrick. But, were way past that birthday now.

Hamricks son, Alek, was diagnosed at six months old with spinal muscular atrophy and not expected to live long enough to toddle. ButAlek, now 3, has beaten the odds and outlived that initial, bleak prognosis.

His parents attribute much of his success to his doctor, Richard Finkel, who entered Alek into a clinical trial for what they believe has been a wonder drug for their little boy, Evrysdi, which was recently approved by the Food and Drug Administration.

Whats hard to even get around is that people even bothered to research it, Todd Hamrick said. Its just a small amount of the population that has SMA. Its not like researching a blood pressure medication.

Spinal muscular atrophy, or SMA,is a genetic disorder caused by a loss of nerve cells that effect human motor function.

Essentially, those afflicted by SMA are made weak. Their muscleswaste away. In many cases, eventually, a person loses their ability to walk, to eat andevento breathe, and they die.

Aleks mother, Iwona Hamrick, is a nurse at a local hospital and wellremembers the moment she heardher sons diagnosis.

It was unimaginable. His pregnancy was normal, she said. We did genetic testing and it was negative. Unfortunately, at that time, they were not screening for his disease. So, from a healthy baby to a dying baby, you know?

The parents felt they had to travel, in more ways than one, to find the places and help that they could for their Alek.

Todd Hamrick said that he and wife decided to move from Gulf Breeze to Pace after Aleks diagnosis after feeling ostracized by many of their former acquaintances. The parents felt like some people who they used to know were made uncomfortable by their son's illness.

The area is very in-the-dark when it comes to children with issues, Todd Hamrick said. If your kids are healthy and you'rehealthy, its a great area. But, it doesnt attract the greatest talent or best and biggest facilities or endowments.

So, Alek traveled with his family to meet his future doctor, Finkel, at the Nemours Children's Hospital in Orlando.

Alekwas first treated with a gene therapy drug, and he made some response with that, Finkel told the News Journal. But more recently, he started on a second drug, which seems to be having an enhanced effect, I must say.

Finkel, an expert in the field of pediatric neurologic disorders, left Florida in March for a position leading the new Center for Experimental Neurotherapeutics at St. Jude Childrens Research Hospital in Memphis, Tennessee. Buthe has continued to monitor Aleks progress via video.

Both of the drugs he has received, the gene therapy and this new drug, Evrysdi, are designed to increase a certain protein in Aleks body that is deficient because of his genetic disorder, he explained. But they do it in different ways. The potential advantage of his new drug, Evrysdi because its an oral drug; you take it by mouth it goes into the stomach and into the bloodstream, and from there, it goes to all the tissues of the body.

And, we think that there is an enhanced effect, becauseit gets into the muscle tissue, Finkel continued. "These are very, very, early daysin trying to make assessments, soI dont want to say that we can come to any kind of conclusions yet."

However the cutting-edge drug works doesnt matter to a mother, whos just glad that it isworking.

It gave us hope. Thats for sure, Iwona Hamrick said. Becausewe felt helpless.

Since Alek started his new treatment last November, his strength has increased tremendously.

His muscle tone got better, Iwona Hamrick said. He is much stronger in the upper body, so much so, he is pushing his little wheelchair.

Alek can now cruise around his Pace home in an extraordinarily lite-weight wheelchair designed by a Swedish inventor who alsohas a child with SMA.

Alek had a lot of trouble before starting this medication even pushing it, Iwona Hamrick said. Sonowhe is just rolling around the house. Also, he is barring more weight on his legs.

Recently, Alek has started to be able to walk in a pool a huge milestone for the toddler.

But some worries remain the same.

Every day, Alek must use a type of breathing machine.

Its a cough assist machine, Todd Hamrick explained. We use it two times a day, when hes healthy. Becausewhere we can just clear our throats when we cough, he doesnt have that strength no lung strength.

Alek attends physical therapy, aqua-therapy,hippotherapy, occupational therapy and speech therapy sessions every week to try and ensure he remains healthy and continues to properly develop.

My worries have changed a lot, Todd Hamrick said. I used to worry my child was going to die. Now, Im worrying about if other kids will bully him at school.

"But that'sa great worry to have," he continued. "Compared to how it use to be, getting picked on is a great thing to worry about.

Colin Warren-Hicks can be reached at colinwarrenhicks@pnj.com or 850-435-8680.

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Pace toddler wasn't supposed to survive. Thanks to wonder drug, parents say he's thriving - Pensacola News Journal