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Much of what we will be as adults depends on the first years of life, on what we simply observe happening around us and not only on what we are taught explicitly. This also applies to the development of the visual system. This is the conclusion reached by two neuroscientists of SISSA (Scuola Internazionale Superiore di Studi Avanzati), who, for the first time, have experimentally shown the importance of passive visual experience for the maturation and the proper functioning of some key neurons involved in the process of vision. The research, published on Science Advances, is a fundamental step towards understanding learning mechanisms during development. It also has potential clinical implications, for the study of new visual rehabilitation therapies, and technological implications, where it could lead to an improvement of the learning algorithms employed by artificial vision systems.

From the early stages of gestation, our visual system is subject to continuous stimuli that become increasingly intense and structured after birth. They are at the centre of the learning mechanisms that, according to some theories, are fundamental to the development of vision. "Learning comes in two flavours: either 'supervised' (i.e., guided by a 'teacher') or 'unsupervised' (i.e., based on spontaneous, passive exposure to the environment)" explains Davide Zoccolan, director of the Visual Neuroscience Lab of SISSA and lead researcher. "The first is the one we can all associate with our parents or teachers, who direct us to the recognition of an object. The second one happens spontaneously, passively, when we move around the world observing what happens around us."

Giulio Matteucci and Davide Zoccolan have studied the role of spontaneous visual experience and, in particular, the role of the temporal continuity of visual stimuli. This property of natural visual experience is considered fundamental for the maturation of the visual system by some theoretical models that mathematically describe the biological learning processes.

To test this hypothesis, the researchers daily exposed two groups of young rodents to different visual environments. "We played a series of videos, in either their original version or after randomly shuffling the single frames (or images), thus destroying the temporal continuity of visual experience" explain the scientists. "In the subjects exposed to this discontinuous visual flow we observed the impairment of the maturation of some cells of the visual cortex called 'complex'. These neurons play a key role in visual processing: they allow recognising the orientation of the contour of an object regardless of its exact position in the visual field, a perceptual ability that only recently has been implemented in artificial vision systems. Having shown that their maturation is highly sensitive to the degree of continuity of visual experience is the first direct experimental confirmation of the theoretical prediction."

These observations show the importance of passive visual experience for the development of the visual system. They also indicate how forms of spontaneous learning are at the base of the development of at least some elementary visual function, while other forms of learning only come into play later, due to the acquisition of more specific and sophisticated skills.

These are results with potential clinical and technological implications, as Zoccolan explains. "In some developing countries, there are children suffering from congenital cataract, who, after the surgery to remove it, have to develop substantially from scratch their visual recognition skills. Already today, some rehabilitative approaches exploit the temporal continuity of specific visual stimuli (for example, geometric shapes in motion) to teach these patients to discriminate visual objects. Our results confirm the validity of these approaches, revealing the neuronal mechanisms behind it and suggesting possible improvements and simplifications," concludes the neuroscientist. "Furthermore, the development of artificial visual systems currently uses mainly 'supervised' learning techniques, which require the use of millions of images. Our results suggest that these methods should be complemented by 'unsupervised' learning algorithms that mimic the processes at work in the brain, to make training faster and more efficient".

Neuroscience

Here are the Rutgers athletes graduating in 2020 – nj.com

May 31, 2020 medical

Over 100 current and former Rutgers student-athletes are part of the Class of 2020.

Below are Rutgers athletics graduates (an asterisk denotes a masters degree) ahead of Sundays virtual graduation. Graduate names were provided by Rutgers Athletics Communications:

BASEBALL:Steven Acosta (economics)Serafino Brito (criminal justice)Tommy Genuario (labor studies and employment relations)Anthony Greco (human resource management)Kyle Muller (sport management)John Parkinson (human resource management)

SOFTBALL:Hailey Hoklotubbe (biological sciences)Cambria Keefer (communication)

MENS BASKETBALL:Shaq Carter (labor studies and employment relations)Joey Downes (English)Peter Kiss (labor studies and employment relations)Jacob Young (labor studies and employment relations)

WOMENS BASKETBALL:Arella Guirantes (journalism and media studies)Jordan Wallace (criminal justice)Charise Wilson (adult and continuing education)*

MENS CROSS COUNTRY:Andrew Comito (industrial engineering)Nicholas Pschunder (economics)Patrick Walsh (planning and public policy/political science)

WOMENS CROSS COUNTRY:Emma Bergman (public health)Kelsey Farbanish (chemical engineering)Stephanie Mauer (exercise science)Lou Mialhe (public health)Nadia Saponara (environmental policy, institutions and behavior)

FIELD HOCKEY:Austyn Cuneo (public health)Alanna Gollotto (public health)Emily Howarth (psychology)Amanda Lamb (sport management)Nicole Santore (human resource management/labor studies and employment relations)

FOOTBALL:Jamaal Beaty (labor studies and employment relations)Brendan Bordner (finance)Anthony Cioffi (communication)Malik Dixon (labor studies and employment relations)Zack Heeman (counseling psychology)*Sam Howson (political science)Mohamed Jabbie (labor studies and employment relations)Adam Korsak (labor studies and employment relations)Kyle LaPorte (labor studies and employment relations)Mike Lonsdorf (supply chain and marketing science)Alan Lucy (communication)Elorm Lumor (communication)Mike Maietti (criminal justice)Kobe Marfo (information technology and informatics)Cole Murphy (finance)Jim Onulak (information technology and informatics/labor studies and employment relations)Willington Previlon (information technology and informatics)Freddie Recio (sociology)Deonte Roberts (labor studies and employment relations)Austin Rosa (political science)Kamaal Seymour (information technology and informatics)Matthew Sportelli (labor studies and employment relations/economics)Reggie Stephens (labor studies and employment relations)Manny Taylor (labor studies and employment relations)Prince Taylor (labor studies and employment relations)

MENS GOLF:Tony Jiang (labor studies and employment relations/economics)

WOMENS GOLF:Ana Maria Cortes (finance/leadership and management)Ching Nam Lee (supply chain and marketing science)

GYMNASTICS:Chloe DeVries (criminal justice)Shannon Farrell (labor studies and employment relations)Kaitlyn Hall (labor studies and employment relations)Erin McLachlan (journalism and media studies)Polina Poliakova (psychology)

MENS LACROSSE:Brian Eletti (sport management)Brodie Gillespie (economics)William Kelly (pre-business)John Lloyd (economics)Robert Marron (civil engineering)Owen Mead (biological sciences)Kieran Mullins (cell biology and neuroscience)Mark Schachte (finance)Jack Thompson (aerospace engineering)

WOMENS LACROSSE:Samantha Budd (biomedical engineering)Brianna Cirino (psychology)Jordan Drab (information technology and informatics)Monica Dresnin (communication)Allie Ferrara (labor studies and employment relations)Jenna Martinelli (exercise science)Christina Petito (public health)Samantha Scarpello (communication)

ROWING:Rebecca Barglowski (English)Olivia Betz (sport management)Sydney Canfield (environmental science/environmental policy, institutions and behavior)Rebecca Chanin (political science/Middle Eastern studies)Nina Gangi (ecology, evolution and natural resources)Rosalina Guarino (marketing)Rucha Janodia (cell biology and neuroscience)Kirsten Jeansson (biological sciences)Merve Pekdemir (industrial engineering)Grace Pettit (psychology)Natalie Summerfelt (exercise science)Rachel Usen (sport management)Julia Wilson (communication)

MENS SOCCER:Jake Longo (finance)Timothy McQuaid (economics)

WOMENS SOCCER:Taylor Aylmer (exercise science)Carina Handley (criminal justice)Megan Katona (communication)Brittany LaPlant (psychology)Casey Murphy (communication)Jenna Sayers (human resource management)Brianna Starr (public health)Chantelle Swaby (sport management)Amanda Visco (sport management)Tiernny Wiltshire (criminal justice)

WOMENS SWIMMING AND DIVING:Francesca Bertotto (labor and employment relations)Alexis Brewer (exercise science)Sarah Davis (nutritional sciences)Alexandra Fabugais-Inaba (journalism and media studies)Clare Lawlor (exercise science)Meghan Moses (biological science)Nadia Nabhan (human resource management)Katherine Scott (labor and employment relations)Francesca Stop (design)

WOMENS TENNIS:Jacqueline Cochrane (political science)Katherine Muzik (human resource management)Kyra Yap (chemical engineering)

MENS TRACK AND FIELD:Alanzo Aris (exercise science)Jarrod Brovero (sport management)Greg Harnett (supply chain analytics)*Sean Martinek (sport management)Christopher Mirabelli (Global Sports Business)*Conor Murphy (human resource management)*Jason Schweizer (sport management)Jared Skalski (industrial engineering)Michael Thomas (supply chain and marketing science)

WOMENS TRACK AND FIELD:Kathryn Campbell (psychology)Selena Thorne (communication)

VOLLEYBALL:Stasa Miljevic (supply chain and marketing science)Jasmine Stackhouse (journalism and media studies/Africana studies)Karysa Swackenberg (public policy)

WRESTLING:Anthony Ashnault (Global Sports Business)*Zach Firestone (human resource management)Joe Grello (human resource management/labor studies and employment management)Anthony Olivieri (human resource management)Jordan Pagano (psychology)Willie Scott (labor studies and employment relations/information technology and informatics)Mike VanBrill (human resource management)

Rutgers will hold its virtual university-wide commencement on Sunday, May 31 at 2 p.m.

From the university website:

Rutgers University will stream a virtual celebration on May 31 to honor the 2020 graduates of Rutgers-New Brunswick and Rutgers Biomedical and Health Sciences during a pandemic that required remote instruction through the final weeks of the spring semester.

President Robert Barchi will preside over and confer degrees during Rutgers Universitys 254th Anniversary Commencement celebration, which will feature award-winning NBC News anchor Lester Holt delivering an address to the graduates from his home studio. Holt also will receive an honorary Doctor of Humane Letters degree.

Commencement is an important milestone, not only for our students and their families, but for our faculty and staff, our alumni, and for the Rutgers community as a whole, Barchi said. In this time of uncertainty, celebrating graduation is more important than ever, because it brings us together to recognize achievements with a sense of pride and admiration, even amidst social distancing.

Get Rutgers Sports Insider text messages from reporters: Cut through the clutter of social media and communicate directly with the Rutgers beat writers. Plus, exclusive news and analysis every day. Sign up now.

Please subscribe now and support the local journalism YOU rely on and trust.

James Kratch may be reached at jkratch@njadvancemedia.com. Tell us your coronavirus story or send a tip here.

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Neuroscience

Monrovia Unified Announces Class of 2020 Valedictorian and Salutatorian – monroviaweekly

May 31, 2020 medical

For their strong academic achievement, perseverance, and dedication to pursuing their goals, Monrovia High School seniors Kate Tadeo and Jessica Lee have been named the Class of 2020s valedictorian and salutatorian, respectively.

It is with great pleasure that we celebrate Monrovias top scholars, who have displayed the hard work, dedication, and wisdom we admire in our student and academic leaders, Monrovia Board President Rob Hammond said. Kate and Jessica are wonderful people with great hearts and bright futures.

Tadeo earned a 4.74 GPA and will attend Columbia University to study neuroscience and behavior, with plans to become an anesthesiologist. Tadeo has been designated a John W. Kluge Scholar through the Columbia Undergraduate Scholar Program.

Tadeo completed 15 Advanced Placement (AP) classes, as well as several courses at Citrus College as part of Monrovias dual-enrollment Early College Program. Tadeo is a graduate of Monrovias Math and Science Academy (MASA) and a member of the National Honors Society and California Scholarship Federation (CSF).

It feels very good to have all of the hard work pay off, Tadeo said. There were so many nights, especially in my junior year, when I stayed up all night long studying for my AP classes. But I am so happy to be going to Columbia. Im ready for my next step.

Tadeos best memories of school include four years on the cross-country team, which helped her to relax, and serving as vice president of Monrovias Interact Club, where she performed community service in partnership with Rotary International, including the annual Santa Clothes event for Foothill Unity Center K-8 students.

Every December, we would take them on $250 shopping sprees at Kohls, Tadeo said. We would go into the store with the kids and help them pick out clothes. It was a chance for them to choose their wardrobe with someone closer to their age. They were so happy. It was adorable.

Kate and Jessica represent the best of Monrovia Unified: academic excellence, school spirit, community activism, and integrity. As is often the case with our students, Superintendent Dr. Katherine Thorossian said. I am inspired by their enthusiasm and optimism.

Lee earned a 4.56 GPA, has completed 13 AP and six Honors classes andwill attend UC Berkeley to study environmental engineering.Lee is a MASA graduate, is a member of the Mandarin Honors Society and CSF and served as captain of the Monrovia girls varsity tennis team.

My love for the environment actually comes from cars. When I discovered Tesla electric cars, I became interested in technology and developing products that are environmentally friendly and benefit humanity. Lee said. I even brainstormed and developed self-watering pots, of which I made over 300, to donate to my local nursing homes. This way the community could enjoy nature indoors with ease. Id love to become an entrepreneur one day.

Lee is part of a Toastmasters Gavel Public Speaking Club, which hosts youth workshops that help elementary school students with public speaking, offering tips on eye contact and body language. The group, which consists of high school student leaders across Southern California, has raised money for the United Way HomeWalk, a 5k to end homelessness in Los Angeles, and has an annual holiday tradition of singing carols and performing skits at area nursing homes.

Senior year has been my favorite year. Its been very relaxing, Lee said. Ive really enjoyed being with my friends and not worrying about college submissions. There were many new places in Monrovia that we would go to. Thats my favorite memory of school.

Tadeo and Lee are continuing family traditions. Tadeos brother, Kemyl, and Lees brother, Kevin were Monrovia High valedictorians.

I have had the pleasure of knowing Kate and Jessica since they arrived at Monrovia High and am so proud of them for all of the work they have accomplished here, Principal Kirk McGinnis said. It has been a struggle for our seniors this year, but Kate and Jessica have come through it all as true leaders, with confidence and compassion. Congratulations to the Monrovia High Class of 2020.

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Biochemistry

NIH Award Supports Research on Biological Drug to Rebuild Heart Tissue – University of Arkansas Newswire

May 31, 2020 medical

University of Arkansas

Josh Sakon, University of Arkansas

FAYETTEVILLE, Ark. With funding from the National Institutes of Health, University of Arkansas researchers hope to develop the first therapeutic drug that can regenerate heart tissue. The lesion-seeking biological drug, released through stent placement, could treat coronary blockages and prevent heart failure.

Currently, there are no viable therapeutics available on the market that can promote regeneration of the heart to prevent myocardial infarction, or heart attack, said Josh Sakon, professor of biochemistry in the J. William Fulbright College of Arts and Sciences. All available medicines treat only symptoms to slow the onset of heart failure. The design of our biologics improves current methods of controlled release, because it takes advantage of specific biochemical events that occur during heart failure.

Biologics, or biological drugs, are pharmaceutical products made from or containing components of living organisms. Used in biotechnology, biologics include a variety of products taken from humans, animals or microorganisms.

Sakon received $30,000 from the NIH and a matching gift from the Commercialization Fund, a subset of the U of A Chancellors Fund to develop and commercialize sFGF1, a human fibroblast growth factor designed by Suresh Thallapuranam, professor of biochemistry. Fibroblast growth factors are cell-signaling proteins involved in a variety of processes critical to normal physiological development. Irregularities in the function of these proteins lead to a range of developmental defects.

Thallapuranam and Kartik Balachandran, associate professor of biomedical engineering, are part of Sakons team focused on developing the drug. They are working on fusing sFGF1 with a different, collagen-binding protein released through stents, the thin mesh tubes that a heart surgeon inserts into arteries and blood vessels to relieve blockage and promote tissue healing. As Sakon mentioned, the advantage of their drug is that it functions in accordance with specific biochemical activity that occurs leading up to and during an adverse event.

In addition to funding drug development, the NIH award will help the researchers obtain intellectual property and pursue critical safety and feasibility assessments, including toxicity and biocompatibility testing in both lab and animal studies. Their results will be used to secure Small Business Technology Transfer funding for preclinical efficacy studies before seeking approval from the U.S. Food and Drug Administration. The NIH funding will also help the researchers identify a potential drug carrier.

The researchers project is one of seven biomedical innovations funded by the NIH via XLerateHealth and its affiliate, the Southeast XLerator Network, which is led by the University of Kentucky. The award is part of the networks Ideas to Products program that supports researchers with competitive proof-of-concept funding that will help accelerate healthcare technologies for commercialization.

With 24 academic institutions, the Southeast XLerator Network was created to support the commercialization of promising life science and healthcare innovation in several southeastern states and Puerto Rico. Its program goal is to broaden the geographic distribution of NIH funding and to help accelerate early-stage biomedical technology from laboratory to market, with an emphasis on supporting geographically underserved areas in healthcare.

According to the American Heart Association, more than 600,000 Americans experience a new myocardial infarction each year, with 275,000 deaths attributable to heart failure. About one in four patients who survive an initial heart attack develop heart failure within four years of the initial first heart attack. Rapid diagnosis and intervention after a coronary blockage can significantly improve chances of patient survival.

Suresh Thallapuranam holds the Cooper Chair of Bioinformatics Research.

About the University of Arkansas: The University of Arkansas provides an internationally competitive education for undergraduate and graduate students in more than 200 academic programs. The university contributes new knowledge, economic development, basic and applied research, and creative activity while also providing service to academic and professional disciplines. The Carnegie Foundation classifies the University of Arkansas among fewer than 3 percent of colleges and universities in America that have the highest level of research activity. U.S. News & World Report ranks the University of Arkansas among its top American public research universities. Founded in 1871, the University of Arkansas comprises 10 colleges and schools and maintains a low student-to-faculty ratio that promotes personal attention and close mentoring.

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NIH Award Supports Research on Biological Drug to Rebuild Heart Tissue - University of Arkansas Newswire

Biochemistry

Automatic Biochemistry Analyzers Market Research Report 2020: Key Players, Applications, Drivers, Trends and Forecast to 2026 – WaterCloud News

May 31, 2020 medical

Prefectural Hospital

In addition, the report categorizes product type and end uses as dynamic market segments that directly impact the growth potential and roadmap of the target market. The report highlights the core developments that are common to all regional hubs and their subsequent impact on the holistic growth path of the Automatic Biochemistry Analyzers market worldwide. Other valuable aspects of the report are the market development history, various marketing channels, supplier analysis, potential buyers and the analysis of the markets industrial chain.

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Table of Content

1 Introduction of Automatic Biochemistry Analyzers Market

1.1 Overview of the Market1.2 Scope of Report1.3 Assumptions

2 Executive Summary

3 Research Methodology of Verified Market Research

3.1 Data Mining3.2 Validation3.3 Primary Interviews3.4 List of Data Sources

4 Automatic Biochemistry Analyzers Market Outlook

4.1 Overview4.2 Market Dynamics4.2.1 Drivers4.2.2 Restraints4.2.3 Opportunities4.3 Porters Five Force Model4.4 Value Chain Analysis

5 Automatic Biochemistry Analyzers Market, By Deployment Model

5.1 Overview

6 Automatic Biochemistry Analyzers Market, By Solution

6.1 Overview

7 Automatic Biochemistry Analyzers Market, By Vertical

7.1 Overview

8 Automatic Biochemistry Analyzers Market, By Geography

8.1 Overview8.2 North America8.2.1 U.S.8.2.2 Canada8.2.3 Mexico8.3 Europe8.3.1 Germany8.3.2 U.K.8.3.3 France8.3.4 Rest of Europe8.4 Asia Pacific8.4.1 China8.4.2 Japan8.4.3 India8.4.4 Rest of Asia Pacific8.5 Rest of the World8.5.1 Latin America8.5.2 Middle East

9 Automatic Biochemistry Analyzers Market Competitive Landscape

9.1 Overview9.2 Company Market Ranking9.3 Key Development Strategies

10 Company Profiles

10.1.1 Overview10.1.2 Financial Performance10.1.3 Product Outlook10.1.4 Key Developments

11 Appendix

11.1 Related Research

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Market Research Intellect provides syndicated and customized research reports to clients from various industries and organizations with the aim of delivering functional expertise. We provide reports for all industries including Energy, Technology, Manufacturing and Construction, Chemicals and Materials, Food and Beverage and more. These reports deliver an in-depth study of the market with industry analysis, market value for regions and countries and trends that are pertinent to the industry.

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Biochemistry

Fort Bend ISD Class of 2020 valedictorians, salutatorians – Chron.com

May 31, 2020 medical

Austin High School valedictorian Joshua Cheung is planning to attend the University of Texas at Austin to study mechanical engineering. His advice: Try your best. Remember what is most important to you and avoid losing sight of your goals. Dont take life too seriously and remember to have fun!

Photo: Courtesy Fort Bend ISD

Fort Bend ISD Class of 2020 valedictorians, salutatorians

Fort Bend ISD recently announced the top two students for each of the districts 11 high school Class of 2020 graduates.Fort Bend County Judge KP George, who served as district trustee before winning election as county judge, urged students to continue striving for excellence.

Congratulations to our future leaders, Judge George said in a telephone interview Friday. I encourage you to strive higher and work harder, so you can achieve your hopes and dreams to build a better future for all. We need you more than ever.

Related: New venue, different dates announced for Fort Bend ISD graduations due to COVID-19

Austin High School

Valedictorian Joshua Cheung is planning to attend the University of Texas at Austin to study mechanical engineering. His advice: Try your best. Remember what is most important to you and avoid losing sight of your goals. Dont take life too seriously and remember to have fun! Salutatorian Naveen Ali is planning to attend the University of Texas at Austin to study computer science. His advice: Life is a collection of failures. The people that succeed are those who learn from these failures.

Bush High School

Valedictorian Evan He is planning to attend the University of Texas at Austin to study biomedical engineering with plans to later to start a company that solves the antibiotic resistance crisis from the worlds over-reliance on antibiotics. His advice: Never lose an opportunity because you doubted yourself. Living life without regrets means committing wholeheartedly to the most challenging decisions. If you never test the boundaries of your limits, you will never be able to reach your full potential. Salutatorian Jada Dan Nguyen is planning to attend the University of Texas at Austin to study biology and public health and go on to graduate from medical school and become a cardiologist. Her advice: Be prepared to adapt and learn to take experiences as lessons, a sign, or motivation.

Clements High School

Valedictorian Siddharth Muppalla is a National Merit Scholar who is planning to study mathematics and computer science at Massachusetts Institute of Technology to pursue a career in finance. His advice: Reality is built by your beliefs. Salutatorian Stephan Xie plans to study computer science and philosophy at Rice University. His advice: Be fearless leaders and fight for solutions to the world we now handle.

Dulles High School

Valedictorian Shaan Parekh is a National Merit Scholar who aspires to become an entrepreneur and is planning to attend the University of Texas at Austin to study computer science and business. His advice: Do more, and then some. Salutatorian Krish Singal plans to attend the University of Texas at Austin to study computer science and mathematics as a Turing Scholar and aspires to innovate, discover and build a better tomorrow with the power of science. His advice: Live life with a mission and savor the adventure.

Elkins High School

Valedictorian Kaitlyn Nguyen plans to attend the University of California at Los Angeles to study biochemistry and aspires to graduate from medical school and become a doctor. Her advice: Take chances, make mistakes, and get messy! Salutatorian Jesica Joy plans to study biochemistry at the University of Texas at Austin with a goal of graduating from medical school and working in emergency medicine. Her advice: Work hard and never lose sight of what inspires and excites you. Find what youre passionate about and follow it.

Hightower High School

Valedictorian Isabella Gandara is a National Merit Scholar who plans to study biological engineering and computer science at the Massachusetts Institute of Technology to eventually pursue scientific research as a principal investigator in the field of computational biology. Her advice: Look to other people for inspiration, but never try to imitate their success. Your life, your happiness, and your success should be uniquely your own. Salutatorian Snehal Anil Kumar is planning to study biochemistry at the University of Texas at Austin with her goal to attend medical school. Her advice: Strive to be a lighthouse to the despairing ship captains of the world.

Kempner High School

Valedictorian Emily Nguyen plans to study biological sciences at Rice University and hopes to graduate from medical school and become a doctor. Her advice: We have but one life. Lets live it well and do some good along the way. Salutatorian Trish Nguyen-Thach plans to study biology at the University of Houston with the goal of becoming a dentist with a possible specialization in specialize in orthodontics or prosthodontics. Her advice: With patience and persistence, we can achieve anything. We are the future and the change.

Marshall High School

Valedictorian Christian Wilson plans to study arts and entertainment tech at the University of Texas and hopes to work in the entertainment sector as a director, screen writer, animator or working for Disney. His advice: Do not be stressed about the little things in life because if you are, you will not be able to enjoy the big things that are going to happen. Just handle your business and have fun while doing so. Salutatorian Mija Obey is planning to study forensic chemistry at Sam Houston State University. Her goal is to become a Forensic Scientist in more than one department and find my purpose in life:. Her advice: A smooth sea never made a skilled sailor- Franklin D. Roosevelt

Ridge Point High School

Valedictorian John Breinholt IV will study chemistry at the University of Utah with further plans to study orthopedic surgery for the spine at the University of Arizona Medical School. Advice: Successful careers take more than just skill or intelligence. You will hardly get anywhere with a bad attitude towards others. Salutatorian Meredith Stickler is planning to study business at the University of Texas at Austin and hopes to graduate from law school. Her advice: Set goals to push yourself. Pain is temporary, but quitting is forever.

Travis High School

Valedictorian Sahana Ramaswamy will study biomedical engineering at Texas A&M University with post-college plans to work in a research position and aid in the development of biomedical technology. Advice: Your efforts always matter. You may not see the results today or tomorrow, but success will undoubtedly be in your future. Never give up. Salutatorian Amy Li plans to study design at the University of Texas and become a creative director or an industrial designer. Advice: Believe in yourself and be curious.

Willowridge High School

Valedictorian Alexander Vazquez-Benitez will study biomedical engineering at the University of Texas at Austin and aspires to become a biomedical engineer. Advice: Be sure to learn from your mistakes, persevere and be open to change. Salutatorian Neida Murillo plans to study biochemistry at Texas A&M University and hopes to become a perfusionist. Advice: You are capable of a lot, which you have proven by graduating amid a difficult time. Remember to hide from the procrastination monster.

Graduation ceremonies are scheduled June 1-6 at Kenneth Hall Stadium.

knix@hcnonline.com

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Biochemistry

Mynomx Pioneers the Personalization Science of Food Nutrition to Prevent and Fight Onset of COVID-19 – Yahoo Finance

May 31, 2020 medical

Mynomx Inc. (formerly Precision Wellness, Inc.), a Silicon Valley-based company at the intersection of next-generation AI analytics and the latest medical and nutrition science, today announced their personalized nutrition approach to boosting cardio and metabolic health for disease prevention and immune system support.

The Novel Coronavirus (COVID-19) has swept the world and struck those with underlying cardiometabolic syndrome: inflammation, hypertension, obesity, diabetes, and cardiovascular disorders, the hardest. The incidence and prevalence of people with cardiometabolic syndromes are on the rise, with over 40% of the US population suffering from one form of cardiovascular disease, posing the greatest burden as the nation's costliest chronic disease and number one killer.

It is clear a new approach to prevention is needed and one that involves proper nutritional interventions. Mynomx focuses on preventing the onset and progression of cardiovascular and metabolic disorders, using food as medicine, through an AI-driven personalized nutrition approach designed to each person's unique metabolism, biochemistry, health, and genetics.

"Expression of our genetic blueprint works hand-in-hand with our nutritional consumption to define our metabolism. The food that we eat directly affects the biochemical pathways that may result in a metabolic imbalance within every tissue and cell, including those of our immune system", explains Dr. Mehrdad Rezaee, Interventional Cardiologist at Cardiac and Vascular Care, a clinical scientist and a Mynomx co-founder.

The Mynomx personalized nutrition approach is predicated on AI health predictive and food recommendation engines designed from the ground up to improve balance across those cardio and metabolic pillars of health that prevent the onset of inflammation, hypertension, obesity, dyslipidemia, and diabetes.

According to Dr. Rezaee, "Achieving metabolic balance leads to an efficient metabolism which is associated with increased energy levels, optimal weight, and a bolstered immune system that can remove toxins, fight bacteria and viruses, and help in preventing the onset and severity of disease, as well as the recovery from injuries."

Unlike other food platforms that only score the quality of food without the knowledge of a person's true state of health, Mynomx's personalized nutrition platform connects food, nutrition, and health at the molecular level to provide precision nutrition food scoring and recommendations based on a person's unique biology and health.

Each person's unique health and biochemistry requires different nutrients, restrictions, and sensitivities that define their personalized dietary pattern. Mynomx combines this pattern with an individual's preference, to produce a curated list of foods ranked based on this precision nutrition score.

"We believe we can profoundly improve the health of our communities through actionable health insights and recommendations that use food-as-medicine personalized to bolster each person's metabolic response," explains Mynomx CEO Nazhin Zarghamee.

Mynomx AI applies this food scoring to whole foods, meals, packaged foods, restaurants, and recipes, to allow for healthy choices at the point of food shopping, meal selection, and meal planning decision making. Food retailers can use the Mynomx platform to build deeper personalization and engagement applications.

Mynomx's outcome-driven approach is predicated around nutritional guidelines and patterns designed to boost metabolic functioning and fight COVID-19. Government and self-insured organizations can use Mynomx predictive analytics to understand the at-risk population and deliver personalized nutrition programs to drive population health, ensuring the health of our communities.

Mynomx health predictions (previously Precision Wellness) have been validated with the highest levels of accuracy across 2.8M patient populations in conjunction with leading institutions such as Stanford Medicine [or University] & Broad Institute (a Harvard, MIT, Massachusetts General Hospital Collaborative). Reference Publication.

About Mynomx

Mynomx is a leading scientific food personalization company that offers organizations and individuals an advanced, integrative approach to managing their health through personalized health insights and nutritional intervention. The data-driven Mynomx analytic platform, powered by the latest in nutritional science at the molecular level, multi-omics, and next-generation AI, offers the means to manage health through "food as medicine," preventing disease and supporting healthy aging. In addition to serving individuals, our platform is ideal for insurance and self-insured organization, corporate wellness, testing, and diagnostic companies as well as food retailers who are seeking deeper personalization and engagement. To learn more, visit http://www.mynomx.com.

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Mynomx Pioneers the Personalization Science of Food Nutrition to Prevent and Fight Onset of COVID-19 - Yahoo Finance

Biochemistry

CCRC researchers focusing on COVID-19 – University of Georgia

May 31, 2020 medical

UGAs Complex Carbohydrate Research Center is tackling the pandemic

Within weeks of the appearance of COVID-19, five teams of researchers at the University of Georgias Complex Carbohydrate Research Center put other research work aside to understand the virus, how it gets into our cells, and the changes that occur inside infected cells.

This work could help identify patients most at risk early, identify ways to slow down the disease, understand which drugs provide some hope to fight it, and perhaps, in a more distant future, to even develop vaccines for viruses before a disease spreads in humans.

With COVID-19, like other diseases, a key part of understanding the disease is understanding the role played by branching structures of sugars called complex carbohydrates or glycans.

There is no human disease that doesnt in some way involve carbohydrates, said Michael Tiemeyer, Distinguished Research Professor and co-director of the CCRC.

And no center in the world brings together as many world-renowned carbohydrate researchers as CCRC, which this year is celebrating 35 years of being a leader in glycoscience, or the study of complex carbohydrates.

CCRC faculty member and GRA Distinguished Investigator Lance Wells and other UGA collaborators are working to study the virus and its coating of carbohydrates that affect COVID-19s ability to bind to a host.

Rob Woods, professor of biochemistry and molecular biology, and his collaborators are applying 3D computational models they had created to study influenza to understand the novel coronavirus. Their models analyze the position of glycans on the viruss surface that help it evade the hosts immune system.

When a virus tries to infect a cell, it first encounters a wall of glycans that covers the cell. Geert-Jan Boons, UGA Foundation Distinguished Professor in Biochemical Sciences, studies how viruses find a way through this carbohydrate forest. His lab creates complex carbohydrates, like the ones that surround human cells, to test whether viruses can bind to them or not. For the COVID-19 research they are focusing on a class of carbohydrate that they already had successfully produced.

Carbohydrates also play a role in how the COVID-19 infection progresses.

The problem my team and I are trying to answer is how to know who should go into the hospital and who shouldnt, Tiemeyer said. Just knowing how much virus someone has isnt enough, because severity doesnt necessarily correlate with viral load. His collaborators, respiratory biologists at the University of North Carolina, discovered that COVID-19 targets glands in the airway.

It is not only glands that the disease affects. The metabolism of any infected cell will change, too, and traces of these changes can be found in the blood.

The starting point for Art Edisons group is comparing blood samples from ferret models. Edisons expertise lies in identifying small molecules in the blood called metabolitesbasically any small molecule in our bodies, in our food, or produced by our cells, such as cholesterol and vitaminsusing CCRCs specialized facilities.

Edison also stressed that, if collaboration and knowledge sharing are a key part of what the CCRC does, they matter now more than ever.

In this project, more than in any other in my career, we want to make measurements that will make a difference and share our data as soon as it is collected and we know its any good, he said. It is not the time for personal territory or trying to be the first at publishing.

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CCRC researchers focusing on COVID-19 - University of Georgia

Biochemistry

New genomic method helps obtain high-resolution maps of DNA in the cell nucleus – News-Medical.net

May 31, 2020 medical

Researchers at Karolinska Institutet in Sweden have developed a new sequencing method that makes it possible to map how DNA is spatially organized in the cell nucleus - revealing which genomic regions are at higher risk of mutation and DNA damage.

The technique is described in an article published in the scientific journal Nature Biotechnology.

Most cells in the human body contain approximately two metres of DNA. This long stretch of DNA is divided in 46 large pieces - the chromosomes - which occupy discrete regions of the cell nucleus known as chromosome territories.

How individual parts of the genome are spatially arranged in the nucleus strongly affects how they are being read by the cell's transcriptional apparatus. However, the spatial arrangement of individual genes in the three-dimensional (3D) space of the nucleus has remained largely unexplored.

Now, a team of researchers led by Dr. Magda Bienko at Science for Life Laboratory (SciLifeLab) and the Department of Medical Biochemistry and Biophysics at Karolinska Institutet has developed a new genomic method, named Genomic loci Positioning by Sequencing or GPSeq, which can be used to obtain high-resolution maps of how DNA is spatially organized in the cell nucleus.

The method works by gradually cutting the DNA from the nuclear periphery towards the centre, followed by reading the DNA sequence around each cut. Mathematical modelling can then be used to reconstruct the 3D genome structure and find where individual genes and regions between genes are located along the nuclear radius as well as in relation to each other.

We found that the spatial distribution of different types of chromatin (composed of DNA, RNA and protein complexes) often differed from what we expected to find.

Dr Magda Bienko, Senior Author, Science for Life Laboratory, Department of Medical Biochemistry, Karolinska Institutet

"To our surprise, we found that the picture is not as simple as having all the inactive chromatin sitting at the nuclear periphery and the active chromatin amassed in the centre.

Instead, there is a continuum, a gradient of increasing activity from the nuclear periphery towards the interior, even though the inactive chromatin can be found in the very centre of the nucleus too."

An important aspect of knowing where different genomic regions are located in the nucleus is that it is now possible to map where DNA damage and mutations are most likely to occur, explains Dr. Nicola Crosetto, a senior researcher at the same department at Karolinska Institutet and the other senior author of the paper.

"We discovered that DNA mutations that are often encountered in different cancer types are enriched in the inactive chromatin located at the nuclear periphery, which might have to do with the fact that many mutagens originate from outside the cell," he says.

"On the other hand, DNA breaks and gene fusions are much more likely to be found in the nuclear centre, which might be due to the high levels of transcription that we find in the centre."

Source:

Journal reference:

Girelli, G., et al. (2020) GPSeq reveals the radial organization of chromatin in the cell nucleus. Nature Biotechnology. doi.org/10.1038/s41587-020-0519-y.

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New genomic method helps obtain high-resolution maps of DNA in the cell nucleus - News-Medical.net

Biochemistry

Medical Grade Chitosan Market Recent Trends and Developments, by Type, by Product, Regional growth, Profit Margin, Market size, Revenue and Sales over…

May 31, 2020 medical

In-depth Report On Medical Grade Chitosan Market including Market Landscape, and Market size, Revenues by players, Revenues by regions.

The global Medical Grade Chitosan market is broadly analyzed in this report that sheds light on critical aspects such as the vendor landscape, competitive strategies, market dynamics, and regional analysis. The report helps readers to clearly understand the current and future status of the global Medical Grade Chitosan market. The research study comes out as a compilation of useful guidelines for players to secure a position of strength in the global market. The authors of the report profile leading companies of the global Medical Grade Chitosan market, Also the details about important activities of leading players in the competitive landscape.

Some of the Important Key player operating in the Report are: Primex, KitoZyme, BIO21, YSK, Vietnam Food, NovaMatrix, KIMICA, Ningbo Zhenhai Haixin Biological, Golden-Shell Pharmaceutical, Zhejiang Fengrun Biotech, Jiangsu Shuanglin, Jiangsu Aoxin Biotechnology, Qingdao Yunzhou Biochemistry

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The report predicts the size of the global Medical Grade Chitosan market in terms of value and volume for the forecast period 2020-2026. As per the analysis provided in the report, the global Medical Grade Chitosan market is expected to rise at a CAGR of xx % between 2020 and 2026 to reach a valuation of US$ xx million/billion by the end of 2026. In 2020, the global Medical Grade Chitosan market attained a valuation of US$ XX million/billion. The market researchers deeply analyze the global Medical Grade Chitosan industry landscape and the future prospects it is anticipated to create

Segmental Analysis

The report has classified the global Medical Grade Chitosan industry into segments including product type and application. Every segment is evaluated based on growth rate and share. Besides, the analysts have studied the potential regions that may prove rewarding for the Medical Grade Chitosan manufacturers in the coming years. The regional analysis includes reliable predictions on value and volume, thereby helping market players to gain deep insights into the overall Medical Grade Chitosan industry.

Global Medical Grade Chitosan Market Segment By Type:

Animal Origin Chitosan, Plant Based Chitosan

Global Medical Grade Chitosan Market Segment By Application:

Chitosan (CS) is a linear polysaccharide which is achieved by deacetylation of chitin, which is the second most plentiful compound in nature, after cellulose. Chitosan was applied in pharmaceutics/drug/gene delivery and cell encapsulation. Chitosan was applied in binding to protein drugs, contact lenses and implants. GMP grade chitosan covers chitosan for a variety of medical applications. The industrys leading producers are Primex, KitoZyme and BIO21, with a combined revenue share of 29.72% in 2019. In 2019, the

Competitive Landscape

It is important for every market participant to be familiar with the competitive scenario in the global Medical Grade Chitosan industry. In order to fulfill the requirements, the industry analysts have evaluated the strategic activities of the competitors to help the key players strengthen their foothold in the market and increase their competitiveness.

Key companies operating in the global Medical Grade Chitosan market include: Primex, KitoZyme, BIO21, YSK, Vietnam Food, NovaMatrix, KIMICA, Ningbo Zhenhai Haixin Biological, Golden-Shell Pharmaceutical, Zhejiang Fengrun Biotech, Jiangsu Shuanglin, Jiangsu Aoxin Biotechnology, Qingdao Yunzhou Biochemistry

Key questions answered in the report:

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Table of Contents

1 Medical Grade Chitosan Market Overview1.1 Medical Grade Chitosan Product Overview1.2 Medical Grade Chitosan Market Segment by Type1.2.1 Animal Origin Chitosan1.2.2 Plant Based Chitosan1.3 Global Medical Grade Chitosan Market Size by Type (2015-2026)1.3.1 Global Medical Grade Chitosan Market Size Overview by Type (2015-2026)1.3.2 Global Medical Grade Chitosan Historic Market Size Review by Type (2015-2020)1.3.2.1 Global Medical Grade Chitosan Sales Market Share Breakdown by Type (2015-2026)1.3.2.2 Global Medical Grade Chitosan Revenue Market Share Breakdown by Type (2015-2026)1.3.2.3 Global Medical Grade Chitosan Average Selling Price (ASP) by Type (2015-2026)1.3.3 Global Medical Grade Chitosan Market Size Forecast by Type (2021-2026)1.3.3.1 Global Medical Grade Chitosan Sales Market Share Breakdown by Application (2021-2026)1.3.3.2 Global Medical Grade Chitosan Revenue Market Share Breakdown by Application (2021-2026)1.3.3.3 Global Medical Grade Chitosan Average Selling Price (ASP) by Application (2021-2026)1.4 Key Regions Market Size Segment by Type (2015-2020)1.4.1 North America Medical Grade Chitosan Sales Breakdown by Type (2015-2026)1.4.2 Europe Medical Grade Chitosan Sales Breakdown by Type (2015-2026)1.4.3 Asia-Pacific Medical Grade Chitosan Sales Breakdown by Type (2015-2026)1.4.4 Latin America Medical Grade Chitosan Sales Breakdown by Type (2015-2026)1.4.5 Middle East and Africa Medical Grade Chitosan Sales Breakdown by Type (2015-2026)1.5 Coronavirus Disease 2019 (Covid-19): Medical Grade Chitosan Industry Impact1.5.1 How the Covid-19 is Affecting the Medical Grade Chitosan Industry1.5.1.1 Medical Grade Chitosan Business Impact Assessment Covid-191.5.1.2 Supply Chain Challenges1.5.1.3 COVID-19s Impact On Crude Oil and Refined Products1.5.2 Market Trends and Medical Grade Chitosan Potential Opportunities in the COVID-19 Landscape1.5.3 Measures / Proposal against Covid-191.5.3.1 Government Measures to Combat Covid-19 Impact1.5.3.2 Proposal for Medical Grade Chitosan Players to Combat Covid-19 Impact 2 Global Medical Grade Chitosan Market Competition by Company2.1 Global Top Players by Medical Grade Chitosan Sales (2015-2020)2.2 Global Top Players by Medical Grade Chitosan Revenue (2015-2020)2.3 Global Top Players Medical Grade Chitosan Average Selling Price (ASP) (2015-2020)2.4 Global Top Manufacturers Medical Grade Chitosan Manufacturing Base Distribution, Sales Area, Product Type2.5 Medical Grade Chitosan Market Competitive Situation and Trends2.5.1 Medical Grade Chitosan Market Concentration Rate (2015-2020)2.5.2 Global 5 and 10 Largest Manufacturers by Medical Grade Chitosan Sales and Revenue in 20192.6 Global Top Manufacturers by Company Type (Tier 1, Tier 2 and Tier 3) (based on the Revenue in Medical Grade Chitosan as of 2019)2.7 Date of Key Manufacturers Enter into Medical Grade Chitosan Market2.8 Key Manufacturers Medical Grade Chitosan Product Offered2.9 Mergers & Acquisitions, Expansion 3 Global Medical Grade Chitosan Status and Outlook by Region (2015-2026)3.1 Global Medical Grade Chitosan Market Size and CAGR by Region: 2015 VS 2020 VS 20263.2 Global Medical Grade Chitosan Market Size Market Share by Region (2015-2020)3.2.1 Global Medical Grade Chitosan Sales Market Share by Region (2015-2020)3.2.2 Global Medical Grade Chitosan Revenue Market Share by Region (2015-2020)3.2.3 Global Medical Grade Chitosan Sales, Revenue, Price and Gross Margin (2015-2020)3.3 Global Medical Grade Chitosan Market Size Market Share by Region (2021-2026)3.3.1 Global Medical Grade Chitosan Sales Market Share by Region (2021-2026)3.3.2 Global Medical Grade Chitosan Revenue Market Share by Region (2021-2026)3.3.3 Global Medical Grade Chitosan Sales, Revenue, Price and Gross Margin (2021-2026)3.4 North America Medical Grade Chitosan Market Size YoY Growth (2015-2026)3.4.1 North America Medical Grade Chitosan Revenue YoY Growth (2015-2026)3.4.2 North America Medical Grade Chitosan Sales YoY Growth (2015-2026)3.5 Asia-Pacific Medical Grade Chitosan Market Size YoY Growth (2015-2026)3.5.1 Asia-Pacific Medical Grade Chitosan Revenue YoY Growth (2015-2026)3.5.2 Asia-Pacific Medical Grade Chitosan Sales YoY Growth (2015-2026)3.6 Europe Medical Grade Chitosan Market Size YoY Growth (2015-2026)3.6.1 Europe Medical Grade Chitosan Revenue YoY Growth (2015-2026)3.6.2 Europe Medical Grade Chitosan Sales YoY Growth (2015-2026)3.7 Latin America Medical Grade Chitosan Market Size YoY Growth (2015-2026)3.7.1 Latin America Medical Grade Chitosan Revenue YoY Growth (2015-2026)3.7.2 Latin America Medical Grade Chitosan Sales YoY Growth (2015-2026)3.8 Middle East and Africa Medical Grade Chitosan Market Size YoY Growth (2015-2026)3.8.1 Middle East and Africa Medical Grade Chitosan Revenue YoY Growth (2015-2026)3.8.2 Middle East and Africa Medical Grade Chitosan Sales YoY Growth (2015-2026) 4 Global Medical Grade Chitosan by Application4.1 Medical Grade Chitosan Segment by Application4.1.1 Wound Care4.1.2 Healthcare Products4.1.3 Antibacterial Products4.1.4 Others4.2 Global Medical Grade Chitosan Sales by Application: 2015 VS 2020 VS 20264.3 Global Medical Grade Chitosan Historic Sales by Application (2015-2020)4.4 Global Medical Grade Chitosan Forecasted Sales by Application (2021-2026)4.5 Key Regions Medical Grade Chitosan Market Size by Application4.5.1 North America Medical Grade Chitosan by Application4.5.2 Europe Medical Grade Chitosan by Application4.5.3 Asia-Pacific Medical Grade Chitosan by Application4.5.4 Latin America Medical Grade Chitosan by Application4.5.5 Middle East and Africa Medical Grade Chitosan by Application 5 North America Medical Grade Chitosan Market Size by Country (2015-2026)5.1 North America Market Size Market Share by Country (2015-2020)5.1.1 North America Medical Grade Chitosan Sales Market Share by Country (2015-2020)5.1.2 North America Medical Grade Chitosan Revenue Market Share by Country (2015-2020)5.2 North America Market Size Market Share by Country (2021-2026)5.2.1 North America Medical Grade Chitosan Sales Market Share by Country (2021-2026)5.2.2 North America Medical Grade Chitosan Revenue Market Share by Country (2021-2026)5.3 North America Market Size YoY Growth by Country5.3.1 U.S. Medical Grade Chitosan Market Size YoY Growth (2015-2026)5.3.2 Canada Medical Grade Chitosan Market Size YoY Growth (2015-2026) 6 Europe Medical Grade Chitosan Market Size by Country (2015-2026)6.1 Europe Market Size Market Share by Country (2015-2020)6.1.1 Europe Medical Grade Chitosan Sales Market Share by Country (2015-2020)6.1.2 Europe Medical Grade Chitosan Revenue Market Share by Country (2015-2020)6.2 Europe Market Size Market Share by Country (2021-2026)6.2.1 Europe Medical Grade Chitosan Sales Market Share by Country (2021-2026)6.2.2 Europe Medical Grade Chitosan Revenue Market Share by Country (2021-2026)6.3 Europe Market Size YoY Growth by Country6.3.1 Germany Medical Grade Chitosan Market Size YoY Growth (2015-2026)6.3.2 France Medical Grade Chitosan Market Size YoY Growth (2015-2026)6.3.3 U.K. Medical Grade Chitosan Market Size YoY Growth (2015-2026)6.3.4 Italy Medical Grade Chitosan Market Size YoY Growth (2015-2026)6.3.5 Russia Medical Grade Chitosan Market Size YoY Growth (2015-2026) 7 Asia-Pacific Medical Grade Chitosan Market Size by Country (2015-2026)7.1 Asia-Pacific Market Size Market Share by Country (2015-2020)7.1.1 Asia-Pacific Medical Grade Chitosan Sales Market Share by Country (2015-2020)7.1.2 Asia-Pacific Medical Grade Chitosan Revenue Market Share by Country (2015-2020)7.2 Asia-Pacific Market Size Market Share by Country (2021-2026)7.2.1 Asia-Pacific Medical Grade Chitosan Sales Market Share by Country (2021-2026)7.2.2 Asia-Pacific Medical Grade Chitosan Revenue Market Share by Country (2021-2026)7.3 Asia-Pacific Market Size YoY Growth by Country7.3.1 China Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.2 Japan Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.3 South Korea Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.4 India Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.5 Australia Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.6 Taiwan Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.7 Indonesia Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.8 Thailand Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.9 Malaysia Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.10 Philippines Medical Grade Chitosan Market Size YoY Growth (2015-2026)7.3.11 Vietnam Medical Grade Chitosan Market Size YoY Growth (2015-2026) 8 Latin America Medical Grade Chitosan Market Size by Country (2015-2026)8.1 Latin America Market Size Market Share by Country (2015-2020)8.1.1 Latin America Medical Grade Chitosan Sales Market Share by Country (2015-2020)8.1.2 Latin America Medical Grade Chitosan Revenue Market Share by Country (2015-2020)8.2 Latin America Market Size Market Share by Country (2021-2026)8.2.1 Latin America Medical Grade Chitosan Sales Market Share by Country (2021-2026)8.2.2 Latin America Medical Grade Chitosan Revenue Market Share by Country (2021-2026)8.3 Latin America Market Size YoY Growth by Country8.3.1 Mexico Medical Grade Chitosan Market Size YoY Growth (2015-2026)8.3.2 Brazil Medical Grade Chitosan Market Size YoY Growth (2015-2026)8.3.3 Argentina Medical Grade Chitosan Market Size YoY Growth (2015-2026) 9 Middle East and Africa Medical Grade Chitosan Market Size by Country (2015-2026)9.1 Middle East and Africa Market Size Market Share by Country (2015-2020)9.1.1 Middle East and Africa Medical Grade Chitosan Sales Market Share by Country (2015-2020)9.1.2 Middle East and Africa Medical Grade Chitosan Revenue Market Share by Country (2015-2020)9.2 Middle East and Africa Market Size Market Share by Country (2021-2026)9.2.1 Middle East and Africa Medical Grade Chitosan Sales Market Share by Country (2021-2026)9.2.2 Middle East and Africa Medical Grade Chitosan Revenue Market Share by Country (2021-2026)9.3 Middle East and Africa Market Size YoY Growth by Country9.3.1 Turkey Medical Grade Chitosan Market Size YoY Growth (2015-2026)9.3.2 Saudi Arabia Medical Grade Chitosan Market Size YoY Growth (2015-2026)9.3.3 UAE Medical Grade Chitosan Market Size YoY Growth (2015-2026) 10 Company Profiles and Key Figures in Medical Grade Chitosan Business10.1 Primex10.1.1 Primex Corporation Information10.1.2 Primex Description, Business Overview and Total Revenue10.1.3 Primex Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.1.4 Primex Medical Grade Chitosan Products Offered10.1.5 Primex Recent Development10.2 KitoZyme10.2.1 KitoZyme Corporation Information10.2.2 KitoZyme Description, Business Overview and Total Revenue10.2.3 KitoZyme Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.2.4 Primex Medical Grade Chitosan Products Offered10.2.5 KitoZyme Recent Development10.3 BIO2110.3.1 BIO21 Corporation Information10.3.2 BIO21 Description, Business Overview and Total Revenue10.3.3 BIO21 Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.3.4 BIO21 Medical Grade Chitosan Products Offered10.3.5 BIO21 Recent Development10.4 YSK10.4.1 YSK Corporation Information10.4.2 YSK Description, Business Overview and Total Revenue10.4.3 YSK Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.4.4 YSK Medical Grade Chitosan Products Offered10.4.5 YSK Recent Development10.5 Vietnam Food10.5.1 Vietnam Food Corporation Information10.5.2 Vietnam Food Description, Business Overview and Total Revenue10.5.3 Vietnam Food Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.5.4 Vietnam Food Medical Grade Chitosan Products Offered10.5.5 Vietnam Food Recent Development10.6 NovaMatrix10.6.1 NovaMatrix Corporation Information10.6.2 NovaMatrix Description, Business Overview and Total Revenue10.6.3 NovaMatrix Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.6.4 NovaMatrix Medical Grade Chitosan Products Offered10.6.5 NovaMatrix Recent Development10.7 KIMICA10.7.1 KIMICA Corporation Information10.7.2 KIMICA Description, Business Overview and Total Revenue10.7.3 KIMICA Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.7.4 KIMICA Medical Grade Chitosan Products Offered10.7.5 KIMICA Recent Development10.8 Ningbo Zhenhai Haixin Biological10.8.1 Ningbo Zhenhai Haixin Biological Corporation Information10.8.2 Ningbo Zhenhai Haixin Biological Description, Business Overview and Total Revenue10.8.3 Ningbo Zhenhai Haixin Biological Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.8.4 Ningbo Zhenhai Haixin Biological Medical Grade Chitosan Products Offered10.8.5 Ningbo Zhenhai Haixin Biological Recent Development10.9 Golden-Shell Pharmaceutical10.9.1 Golden-Shell Pharmaceutical Corporation Information10.9.2 Golden-Shell Pharmaceutical Description, Business Overview and Total Revenue10.9.3 Golden-Shell Pharmaceutical Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.9.4 Golden-Shell Pharmaceutical Medical Grade Chitosan Products Offered10.9.5 Golden-Shell Pharmaceutical Recent Development10.10 Zhejiang Fengrun Biotech10.10.1 Company Basic Information, Manufacturing Base and Competitors10.10.2 Medical Grade Chitosan Product Category, Application and Specification10.10.3 Zhejiang Fengrun Biotech Medical Grade Chitosan Sales, Revenue, Price and Gross Margin (2015-2020)10.10.4 Main Business Overview10.10.5 Zhejiang Fengrun Biotech Recent Development10.11 Jiangsu Shuanglin10.11.1 Jiangsu Shuanglin Corporation Information10.11.2 Jiangsu Shuanglin Description, Business Overview and Total Revenue10.11.3 Jiangsu Shuanglin Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.11.4 Jiangsu Shuanglin Medical Grade Chitosan Products Offered10.11.5 Jiangsu Shuanglin Recent Development10.12 Jiangsu Aoxin Biotechnology10.12.1 Jiangsu Aoxin Biotechnology Corporation Information10.12.2 Jiangsu Aoxin Biotechnology Description, Business Overview and Total Revenue10.12.3 Jiangsu Aoxin Biotechnology Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.12.4 Jiangsu Aoxin Biotechnology Medical Grade Chitosan Products Offered10.12.5 Jiangsu Aoxin Biotechnology Recent Development10.13 Qingdao Yunzhou Biochemistry10.13.1 Qingdao Yunzhou Biochemistry Corporation Information10.13.2 Qingdao Yunzhou Biochemistry Description, Business Overview and Total Revenue10.13.3 Qingdao Yunzhou Biochemistry Medical Grade Chitosan Sales, Revenue and Gross Margin (2015-2020)10.13.4 Qingdao Yunzhou Biochemistry Medical Grade Chitosan Products Offered10.13.5 Qingdao Yunzhou Biochemistry Recent Development 11 Medical Grade Chitosan Upstream, Opportunities, Challenges, Risks and Influences Factors Analysis11.1 Medical Grade Chitosan Key Raw Materials11.1.1 Key Raw Materials11.1.2 Key Raw Materials Price11.1.3 Raw Materials Key Suppliers11.2 Manufacturing Cost Structure11.2.1 Raw Materials11.2.2 Labor Cost11.2.3 Manufacturing Expenses11.3 Medical Grade Chitosan Industrial Chain Analysis11.4 Market Opportunities, Challenges, Risks and Influences Factors Analysis11.4.1 Market Opportunities and Drivers11.4.2 Market Challenges11.4.3 Market Risks11.4.4 Porters Five Forces Analysis 12 Market Strategy Analysis, Distributors12.1 Sales Channel12.2 Distributors12.3 Downstream Customers 13 Research Findings and Conclusion 14 Appendix14.1 Methodology/Research Approach14.1.1 Research Programs/Design14.1.2 Market Size Estimation14.1.3 Market Breakdown and Data Triangulation14.2 Data Source14.2.1 Secondary Sources14.2.2 Primary Sources14.3 Author Details14.4 Disclaimer

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Medical Grade Chitosan Market Recent Trends and Developments, by Type, by Product, Regional growth, Profit Margin, Market size, Revenue and Sales over...