Each week, The Dailys Science & Tech section produces a roundup of the most exciting and influential research happening on campus or otherwise related to Stanford. Heres our digest for the weeks of Aug 30 Sept 12.

Coronavirus antibodies treatment in phase II experimental trials

Stanford Medicine researchers are participating in a phase II multi-site clinical trial to test an antibody-drug designed to diminish early COVID-19 symptoms in patients with mild to moderate cases. Preliminary results are expected later this month.

The goal is to see if we can get sick people better faster, reducing both the length of their illness and how long they are shedding the virus, and therefore help prevent others from getting sick, Department of Emergency Medicine Chair Andra Blomkalns told Stanford Medicine News. I think this treatment shows great promise.

At Stanford Hospitals, the clinical site aims to enroll 20 to 40 patients who have tested positive for COVID-19. The experimental treatment involves using antibodies from patients who have recovered from COVID-19, then injecting these antibodies into COVID-19 positive patients.

Our hope is to effect treatment early in the course of disease, before it has time to progress further and potentially damage organs, Blomkalns said.

Microorganism yeast cells reprogrammed to produce plant-based drugs

Yeast cellular machinery can be genetically reprogrammed to change these microscopic organisms into factories that convert sugar and amino acids into plant-based drugs, a study published on Sept. 2 in Nature reports.

The drug shortages were seeing around the COVID-19 crisis drive home why we need new and more reliable ways to source these plant-based medicines, which take months to years to grow and come from a few countries, where climate change, natural disasters and geopolitical issues can disrupt supplies, bioengineering professor Christina Smolke told Stanford News.

The findings suggest that by making genetic modifications to the organelles found in yeast cells, the team can manipulate cellular processes to manufacture the desired chemical drug. In this case, researchers wanted to produce tropane alkaloid molecules for medicinal uses.

Plants are the worlds best chemists, Smolke said. We want to recapitulate their unique and useful chemistries in domesticated microbes to build complex molecules inspired by the natural world but tailored to better meet human needs.

Mosquito-borne disease likelihood increases as climate warms

In Sub-Saharan African, malaria rates are predicted to decrease, while other mosquito-borne diseases such as dengue fever, will increase significantly due to warming climates and urbanization, a study published on Sept. 9 in Lancet Planetary Health reports.

Climate change is going to rearrange the landscape of infectious disease, biology assistant professor Erin Mordecai told Stanford News. Chikungunya and dengue outbreaks like weve recently seen in East Africa are only becoming more likely across much of the continent. We need to be ready for this emerging threat.

The Aedes aegypti mosquito can transmit a wide variety of diseases, including Rift Valley Fever, yellow fever, Zika, chikungunya and dengue. The findings suggest that Aedes aegypti breeding grounds have expanded due to urbanization and warming climate. The mosquitos enjoy living in human-made water containers, like buckets or water storage tanks, and warm temperatures.

Its vital to focus on controlling mosquitoes that spread diseases like dengue because there are no medical treatments for these diseases, pediatrics professor Desiree LaBeaud told Stanford News. On top of that, a shift from malaria to dengue may overwhelm health systems because diseases introduced to new populations often lead to large outbreaks.

Contact Derek Chen at derekc8 at stanford.edu.

More here:
Research Roundup: Researchers test experimental COVID-19 antibodies treatment on patients - The Stanford Daily

CHAMPAIGN, Ill. The National Science Foundation and the U.S. Department of Agricultures National Institute of Food and Agriculture are announcing an investment of more than $140 million to establish seven artificial intelligence institutes in the U.S. Two of the seven will be led by teams at the University of Illinois, Urbana-Champaign. They will support the work of researchers at the U. of I. and their partners at other academic and research institutions. Each of the new institutes will receive about $20 million over five years.

The USDA-NIFA will fund the AI Institute for Future Agricultural Resilience, Management and Sustainability at the U. of I. Illinois computer science professor Vikram Adve will lead the AIFARMS Institute.

The NSF will fund the AI Institute for Molecular Discovery, Synthetic Strategy and Manufacturing, also known as the Molecule Maker Lab Institute. Huimin Zhao, a U. of I. professor of chemical and biomolecular engineering and of chemistry, will lead this institute.

AIFARMS will advance AI research in computer vision, machine learning, soft-object manipulation and intuitive human-robot interaction to solve major agricultural challenges, the NSF reports. Such challenges include sustainable intensification with limited labor, efficiency and welfare in animal agriculture, the environmental resilience of crops and the preservation of soil health. The institute will feature a novel autonomous farm of the future, new education and outreach pathways for diversifying the workforce in agriculture and technology, and a global clearinghouse to foster collaboration in AI-driven agricultural research, Adve said.

Computer science professor Vikram Adve will lead the AI Institute for Future Agricultural Resilience, Management and Sustainability at the U. of I.

Photo by L. Brian Stauffer

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The Molecule Maker Lab Institute will focus on the development of new AI-enabled tools to accelerate automated chemical synthesis to advance the discovery and manufacture of novel materials and bioactive compounds, the NSF reports. The institute also will train a new generation of scientists with combined expertise in AI, chemistry and bioengineering. The goal of the institute is to establish an open ecosystem of disruptive thinking, education and community engagement powered by state-of-the-art molecular design, synthesis and spectroscopic characterization technologies all interfaced with AI and a modern cyberinfrastructure, Zhao said.

Huimin Zhao, a professor of chemical and biomolecular engineering and of chemistry, will lead the new Molecule Maker Lab Institute at Illinois.

Photo by L. Brian Stauffer

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The National Science Foundation and USDA-NIFA recognize the breadth and depth of Illinois expertise in artificial intelligence, agricultural systems and molecular innovation, U. of I. Chancellor Robert Jones said. It is no surprise to me that two of seven new national AI institutes will be led by our campus. I look forward to seeing the results of these new investments in improving agricultural outcomes and innovations in basic and applied research.

Adve is a co-director of the U. of I. Center for Digital Agriculture with crop sciences bioinformatics professor Matthew Hudson. AIFARMS will be under the CDA umbrella. Zhao and Hudson are affiliates of the Carl R. Woese Institute for Genomic Biology, where Zhao leads the Biosystems Design theme. The Molecule Maker Lab Institute will be associated with two campus institutes: IGB and the Beckman Institute for Advanced Science and Technology.

For more information, see related posts, below, from associated campus units:

Editors notes:

To reach Vikram Adve, email vadve@illinois.edu.

To reach Huimin Zhao, email zhao5@illinois.edu.

Excerpt from:
U of I to lead two of seven new national artificial intelligence institutes - University of Illinois News

Four Oaklanders check into their rooms at UC Berkeley on Aug. 21. Left to right: Jacob Williams, 20, a neurobiology major and Tijaan Henderson, 19, studying bioengineering, both chose to stay close to Cal for lab access; Shaka Tellem, 19, studying political economics is an Associate Students of University of California senator; and Mohammed Mustafa, 19, a computer science student is looking for lab access. Photo: Pete Rosos

For some students, the desire for a typical college experience drew them to Berkeley this weekend, despite the fact that all their classes will be online, theyll only be able to socialize with 10-12 neighbors and student organizations are banned from meeting in person.

Others arriving for Cal move-in which this year was spread over four days, one of many health and safety measures forced on the process by COVID-19 feared experiencing a blow to their education. Still others simply wanted to escape the distractions of living at home.

Around 2,000 students trickled into UC Berkeleys dormitories between Thursday and Sunday, ahead of the start of fall semester. (The university is only allowing 3,200 of enrolled students to stay in on-campus housing.)

Move-in happened in hourly time slots to keep crowds to a minimum. Each student had two appointments: one for a COVID-19 test at the schools testing site, and one for an hour-long window to move all of their belongings into their room. Afterwards, the students begin a mandated 7- to 10-day self-sequester, when they may only leave their rooms to pick up meals from dining services and return to their rooms to eat.

Maya Zhus decision to return to campus was complicated, the 18-year-old sophomore said as she waited for her time slot to move in her belongings.

I dont think theres much I need here for learning, she said, but she hopes being on campus will help her concentrate on her virtual classes. Finishing her classes remotely at home felt like an extended summer, she explained.

I need to step it up a little bit, Zhu admitted.

For Alex Ocampo, 18, of San Francisco, a room to herself will be a welcome relief: Ive always wanted to be independent, she said.

Ocampo has been at home since her high school went online. She had no private place to study and was often subject to distractions from family members. Being in Berkeley, in a private dorm room, will let her focus on her first year of college, she said.

For Cameron Johnson, 19, living at school will help her feel like shes still getting part of the normal college experience, she said. Her decision to move to Berkeley from Manhattan Beach, California, pitted the risk of COVID-19 against social isolation.

Incoming student Cameron Johnson wants to feel like shes still getting part of the normal college experience.

I had to weigh the fact that most of my friends were leaving, Johnson said.

Johnsons mother, Elise Johnson, had accompanied her daughter to Berkeley to help her move in. Its a privilege to be able to be in a dorm, she said. Im grateful for [Cameron] to have this typical experience in this non-typical world were in.

Nearly all of the students arriving in Berkeley have had some experience with online learning since the pandemic began. Johnson and Alad Peretz, 18, were both underwhelmed by their high schools virtual classrooms.

They had to scramble to get all the classes online, Johnson said, and the results were not the best. Shes hoping for a more rigorous experience at UC Berkeley, she added.

Peretzs online classes in Miami, Florida were also difficult to manage, but hes hoping the few months the university had to prepare will make a difference.

Peretz road-tripped to California from Miami in an RV with his parents and sister to move into his room, a triple that he has to himself. Hes excited to make social connections with his pod and hopes the close quarters will foster deep connections.

I was ready to head out, strike out on my own, he said. I think itll be nice.

Grace Garcia, 18, felt stressed and excited as she arrived on campus from Los Angeles. Without a roommate, shell have to face her first weeks of college with more self-sufficiency than shed anticipated, she said.

I feel like I have to grow up a little quicker, she said. Im just glad I get to come.

Garcia flew to Berkeley on a half-empty airplane with her brother, Robert Garcia, 19, a Cal sophomore who returned because he finds it easier to focus on his studies outside the family home. Hes also hoping his economics classes can return to something resembling normal within a few months.

We just want the virus to end as soon as possible to go to in-person classes next semester, he said.

As Grace Garcia moved into her dorm, Robert Garcia prepared to settle into an off-campus apartment with two friends. Hes glad to be at the same school as his little sister so he can look out for her, he said.

I know my parents are happy, he added.

At noon on Aug. 20, foot traffic was low and traffic was calm as Heidi Scribner, the universitys executive director of housing, events and facilities, and Jo Mackness, assistant vice chancellor and chief operating officer of student affairs, observed the street from outside the Unit 1 dormitory on Channing Way.

Its a very happy and sad day today, given COVID times. Jo Mackness, UC Berkeley

The day was very slow and steady, which is exactly what we want it to be, said Mackness. We really engineered the number of people that could be here each hour.

Echoing the students moving in, Mackness said she sees the complexities of the decision to live on-campus.

Its a very happy and sad day today, given COVID times, she said. Its a sad thing that students dont get to experience the full college move-in day, but shes happy that the university can provide housing for whom theres no better option.

As for Scribner, who has overseen many move-ins over her 20-year career, she said this is the strangest.. Its Groundhog Day: Were going to do it four times.

As Zhu prepared for her self-sequester, she found herself a little unclear about the schools safety plan. Still, the risks to her education and future outweighed the risk of COVID-19, she said, and she intends to take responsibility for her own health.

Its on me, Zhu said. Nobody else can make sure Im safe.

View post:
UC Berkeley move in was anything but normal this year - Berkeleyside

This is the latest report, covering the current COVID-19 impact on the market. The pandemic of Coronavirus (COVID-19) has affected every aspect of life globally. This has brought along several changes in market conditions. The rapidly changing market scenario and initial and future assessment of the impact are covered in the report.

Reports Monitor introduces a new report titles Global Industrial Bioprocessing Market that studies all the vital factors related to the Global Industrial Bioprocessing market that are crucial for the growth and development of businesses in the given market parameters. The report highlights the important elements related to the market such as the market share, company profiles, profitability, barriers and restraints, opportunities and threats, advertising, technological advancements, key market players, regional segmentation, and many more important elements related to the Global Industrial Bioprocessing Market.

TheMajorPlayers Covered in this Report:BD Biosciences, BioPharm International, GE Healthcare, Thermo Fisher Scientific, Danaher Corporation, Sartorius Stedim Biotech, Merck Millipore, 3M Company, Eppendorf AG, Finesse Solutions, Applikon Biotechnology B.V., Cesco Bioengineering& More.

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In 2019, the global Industrial Bioprocessing market size was million US$ and it is expected to reach a million US$ by the end of 2026, with a CAGR between 2020 and 2026.

Segment by Type, the product can be split intoUpstream BioprocessingDownstream Bioprocessing

Market segment by Application, split intoFoodMedicalPharmaceuticals and NutraceuticalsChemicalsFuelsOther

The report specifically highlights the market share, company profiles, regional outlook, product portfolio, a record of the recent developments, strategic analysis, key players in the market, sales, distribution chain, manufacturing, production, new market entrants as well as existing market players, advertising, brand value, popular products, demand and supply, and other important factors related to the market to help the new entrants understand the market scenario better.

Regional Analysis For Industrial Bioprocessing Market:

North America(United States, Canada, and Mexico)Europe(Germany, France, UK, Russia, and Italy)Asia-Pacific(China, Japan, Korea, India, and Southeast Asia)South America(Brazil, Argentina, Colombia, etc.)Middle East and Africa(Saudi Arabia, UAE, Egypt, Nigeria, and South Africa)

In this study, the years considered to estimate the market size of the Industrial Bioprocessing are as follows:

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The market research report on the Global Industrial Bioprocessing market has been carefully curated after studying and observing various factors that determine the growth such as environmental, economic, social, technological and political status of the regions mentioned. A thorough analysis of the data regarding revenue, production, and manufacturers gives out a clear picture of the global scenario of the Industrial Bioprocessing market. The data will also help key players and new entrants understand the potential of investments in the Global Industrial Bioprocessing Market.

Key features of this report are:

1. It provides valuable insights into the Global Industrial Bioprocessing Market.2. Provides information for the years 2020-2026. Important factors related to the market are mentioned.3. Technological advancements, government regulations, and recent developments are highlighted.4. Advertising and marketing strategies, market trends, and analysis are studied in this report.5.Growth analysis and predictions until the year 2026.6. Statistical analysis of the key players in the market is highlighted.

For More Details On this Report:https://www.reportsmonitor.com/report/1023746/Industrial-Bioprocessing-Market

To conclude, the Industrial Bioprocessing Industry report mentions the key geographies, market landscapes alongside the product price, revenue, volume, production, supply, demand, market growth rate, and forecast, etc. This report also provides SWOT analysis, investment feasibility analysis, and investment return analysis.

Contact UsJay MatthewsDirect: +1 513 549-5911 (U.S.)+44 203 318 2846 (U.K.)Email: [emailprotected]

Originally posted here:
Industrial Bioprocessing Market Opportunity Assessment 2020-2026 Growing with Major Key Player BD Biosciences, BioPharm International, GE Healthcare,...

SCOTTSDALE, AZ July 28, 2020 PathogenDx , Inc., an Arizona based technology company which has developed an ultra-accurate DNA-based customized pathogen testing platform for the food, agricultural, and health sectors, announced today that the company has been awarded a federal grant from the National Institutes of Health (NIH) under their Rapid Acceleration of Diagnostic (RADx) program. The resources will be used to increase the testing capacity of PathogenDxs DetectX-Rv Microarray Assay for COVID-19 testing to a national level.

The NIH launched the RADx initiative with the mission to make millions of tests available to Americans, especially those most vulnerable and disproportionately impacted by the pandemic, by late summer of this year. It was established to propel innovation in the development, commercialization, and implementation of technologies for COVID-19 testing. The RADx program funds projects working on new applications of existing technologies that make tests easier to use, easier to access and more accurate.

We are honored to receive a federal grant from the NIH under their RADx program. The infusion of capital will help bring our microarray tests to the broader population during a time when we need it most, said Milan Patel, CEO of PathogenDx. The NIH and UMass Medical School partnership is an incredibly synergistic collaboration working to develop innovative testing technologies to address not just the COVID-19 testing challenge, but also to prepare for the next wave. Technologies like our DetectX-Rv microarray will be critical when facing the predicted uptick in the fall in addition to the extra challenge of distinguishing different symptoms such as the flu and common cold, in addition to COVID-19.

PathogenDxs DetectX-Rv Microarray Assay for COVID-19 testing is a multiplex viral diagnostic assay for the detection of SARS-CoV-2, and is currently in the process of receiving FDA authorization. The test delivers better sensitivity and specificity than current qRT-PCR FDA-authorized COVID-19 tests while also detecting COVID-like-viruses and subsequent mutations from SARS-CoV-2, making it one of the most extensive tests in the industry. With a multiplex system, thousands of samples can be tested each day, the level necessary and needed in terms of population-level testing, as well as opening up the economy in a risk-mitigated fashion.

This project is supported by the NIH Rapid Acceleration of Diagnostics (RADx) program and has been funded in whole or in part with Federal funds from National Heart, Lung and Blood Institute, National Institute of Biomedical Imaging and Bioengineering, National Institutes of Health, Department of Health and Human Services, under Grant No. 3U54HL143541-02S1.

More:
PathogenDx Receives Federal Grant From the NIH as Part of the RADx Program - Lab Manager Magazine

AI research by the National Science Foundation will expand to a broader range of businesses across the U.S. economy through five new NSF AI institutes being created at a cost of $100 million.

The new initiatives, which were unveiled Aug. 26 by the agency, will deepen the NSFs artificial intelligence research to expand the nations workforce and drive new possibilities for a wide range of businesses, educational institutions, medicine, banking and other organizations.

In a related announcement, two complementary AI research institutes are also being created by the U.S. Department of Agriculture over the next five years using $40 million in funding to expand AI research in farming and food processing.

The new AI institutes will emphasize use-inspired research to help businesses and organizations, said James Donlon, program director for information and intelligent systems in the NSFs directorate for computer and information science and engineering (CISE) division.

Were trying to tackle some of the grand challenges that we see in these different sectors of the economy to advance AI and a wide range of industries, said Donlon. It is what we hope to fuel, to understand AI more and to make a big impact.

The new institutes are organizing and creating implementation teams immediately, he said. They are champing at the bit to get going and onto their research.

The institutes will start their work as early as September through November.

One of the things Im really pleased to see, true to the goals of the program, is that each one of the institutes includes not only the promise to advance AI but also bold advances to help create this future AI workforce that well need to be competitive, said Donlon.

The efforts will create new collaborations and a network of AI research to expand these efforts, he added.

The new NSF AI institutes are:

Led by NSF, the AI initiatives are being conducted in partnership with the U.S.D.A.s National Institute of Food and Agriculture, the U.S. Department of Homeland's Security Science and Technology Directorate, and the U.S. Department of Transportation's Federal Highway Administration, according to the NSF. The institutes will serve as nodes in a broader nationwide network that will pursue transformational advances in sectors of societal impact, from extreme weather preparedness to K-12 education.

The new U.S.D.A. AI institutes are:

Erwin Gianchandani, deputy assistant director for the NSFs directorate for computer and information science and engineering (CISE) division, said the newly-funded institutes have their roots in NSF-funded research going back many decades.

Were trying to unleash the potential and bringing together data and advanced computing capabilities, said Gianchandani.

A wide range of other organizations will also be involved in the AI research initiatives, including minority colleges and universities, companies, states and others, he said. The first programs will involve research in about 20 U.S. states.

This is really about a coalition of the willing coming together in a meaningful way, said Gianchandani. It is a first installment, a first round of institutes we are funding now.

Another funding round could come a year from now to further expand the program across the nation, he said.

Related

See the original post:
Fueling AI to Grow the Economy Is Goal of 5 New NSF AI Institutes - EnterpriseAI

One of the main problems with protective equipment, be it for astronauts, firefighters, or soldiers, is that materials strong enough to protect against ballistic threats typically cant protect against extreme temperatures and vice versa.

As a result, most of today's protective gear is made of multiple layers of different materials, which makes it incredibly heavy to the point that it severely limits the wearer's mobility.

RELATED: HONG KONG RIOT POLICE REPORTEDLY BUY ROBO COP-STYLE BODY ARMOUR FROM CHINA

In order to tackle this problem, Harvard University researchers, in collaboration with the U.S. Army and West Point, have developed a lightweight, multifunctional nanofiber material that can protect wearers from both extreme temperatures and ballistic threats, such as bullets and shrapnel.

Kevlar and Twaron are two commercially available products that are used extensively in protective gear. They can bothprovide either ballistic or thermal protection, depending on how they are manufactured.

Woven Kevlar's highly aligned crystalline structure, for example, means that it is used in protective bulletproof vests. Porous Kevlar aerogels, meanwhile, have been shown to be highly protective against heat.

Our idea was to use this Kevlar polymer to combine the woven, ordered structure of fibers with the porosity of aerogels to make long, continuous fibers with porous spacing in between, Gonzalez said in a Harvardpress release. In this system, the long fibers could resist a mechanical impact while the pores would limit heat diffusion.

The team from Harvard, led by senior author,Kit Parker, the Tarr Family Professor of Bioengineering and Applied Physics at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) and a lieutenant colonel in the United States Army Reserve, usedimmersion Rotary Jet-Spinning (iRJS), a technique developed by Parkers Disease Biophysics Group, to manufacture their fibers.

While there are improvements that could be made, we have pushed the boundaries of whats possible and started moving the field towards this kind of multifunctional material, said Gonzalez.

The ultimate goal was to design a multifunctional material that would be able to protect people working in extreme environments, such as astronauts or soldiers.

Weve shown that you can develop highly protective textiles for people that work in harms way, said Parker. Our challenge now is to evolve the scientific advances to innovative products for my brothers and sisters in arms.

Harvards Office of Technology Development has filed a patent application for the technology and has started seeking commercialization opportunities for the nanofiber.The team's researchis published in the journal Matter.

More here:
New Nanofiber Could Be Used to Protect Astronauts and Soldiers - Interesting Engineering

Chitin Market 2020: Latest Analysis

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COVID-19 impact on Chitin Market Share, Size, Revenue, Gross Margin and Growth Rate Analysis 2020-2026

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Global Chitin Market (Impact of COVID-19) Research Report 2020| Key Players, Growth Factors, Regions and Applications, Industry Forecast To 2025 | FMC...

The ongoing multi-country and multi-crop initiative advances Fluences and the greater horticultural industrys understanding of the interaction between light and life

AUSTIN, Texas Fluence by OSRAM (Fluence), a leading global provider of energy-efficient LED lighting solutions for commercial cannabis and agriculture production, has expanded its global photobiology research program, which encompasses studies on multiple vine crops, leafy greens and medical cannabis in the United States, Canada, Germany, Belgium and the Netherlands.

Tapping into a global network of trusted research institutions

Fluence leverages a network of leading research institutions and partners for its program, including Wageningen University & Research (WUR) for tomatoes; Proefstation voor de Groenteteelt (Proefstation) to study cucumbers; Harrow Research and Development Centre for peppers; The Technical University of Munichs Greenhouse Lab Centre for lettuce; Wageningen Plant Researchs Greenhouse Horticulture business unit and Compassionate Cultivation for medical cannabis.

The latest studies utilized Fluences VYPR Series top light and expanded PhysioSpec spectra offeringwhich features four spectra and market-leading efficacies up to 3.8 mol/Jin a randomized block design with triple replicates during a winter growing season. A leader in global horticultural research, WUR explored the impact of each spectrum on Merlice and Brioso tomato cultivars.

Traditionally, tomato plants are grown under high-pressure sodium lights, where only one spectrum is available to growers, said Ep Heuvelink, associate professor of horticulture and product physiology at WUR. Given the efficacy of Fluences LED solutions and the companys spectra options, its critical to understand how various tomato cultivars perform under LEDs and diversified spectra.

Featuring a 1.3-hectare greenhouse with 38 independent compartments, Proefstations facility brings more than 50 years of experience in research on the cultivation of greenhouse and field vegetables.

Light spectra have an important impact on plant and fruit quality, and weve found that LEDs provide a more optimal, precise spectrum than HPS, said Jonas De Win, lead cucumber researcher at Proefstation. This research is critical for our growers who frequently ask which spectra is best for their greenhouse and crop variety. Our goal is to act as the bridge between cucumber growers and the latest scientific research, enabling cultivators to enhance their environments and ultimately become more profitable.

Crop-based research results inform unique lighting strategies

LED lighting is a proven, viable option for global crop growers, said David Cohen, CEO of Fluence. Our exploration of the impact of light quality on plant development is driving a deeper conversation about efficacy, yield and quality between growers and their partners. Our commitment to leading cross-geography, multi-crop research will help guide growers in building a supplemental lighting strategy tailored to their unique business goals.

Fluence will distribute research results throughout the year, uncovering how the optimal lighting strategy varies by crop, species and environment. Results from Fluences cucumber trial with Proefstation will be previewed on July 15, 2020 on a webinar hosted by Leo Lansbergen, Fluences horticulture service specialist and expert in cucumber cultivation.

There is no one-size-fits-all approach to determining your lighting strategy, said David Hawley, Ph.D., Fluences senior scientist. Exploring how to manipulate LED technology presents a world of opportunity for us as scientists, but ultimately benefits growers looking to customize their cultivation environments. Insights derived from each study will help growers understand how various spectra impact harvests and plant quality, including factors ranging from nutrition and flavor to shelf life.

For more information about Fluence and its ongoing research initiatives, visit http://www.fluence.science.

About Fluence by OSRAM

Fluence Bioengineering, Inc., a wholly-owned subsidiary of OSRAM, creates powerful and energy-efficient LED lighting solutions for commercial crop production and research applications. Fluence is a leading LED lighting supplier in the global cannabis market and is committed to enabling more efficient crop production with the worlds top vertical farms and greenhouse produce growers. Fluence global headquarters are based in Austin, Texas, with its EMEA headquarters in Rotterdam, Netherlands. For more information about Fluence, visit http://www.fluence.science.

Link to high resolution pictures: http://www.fluence.science/press-links

View source version on businesswire.com: https://www.businesswire.com/news/home/20200708005470/en/

Contacts

Media Contact: For North America, Emma Chase emma@redfancommunications.com Phone: 512-917-4319

For EMEA, Silvia Nagyova s.nagyova@osram.com Phone: +49 (89) 6213-3939

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Fluence Leads Global Research Initiative to Study Impact of Light Quality on Plant Development, Yield and Crop Quality - Financial Post

Saba Ale Ebrahim,1,* Amirhossein Ashtari,2,* Maysam Zamani Pedram,3 5,* Nader Ale Ebrahim,6,* Amir Sanati-Nezhad4,5,*

1School of Electrical Engineering, Iran University of Science and Technology, Tehran, Iran; 2Department of Electrical Engineering, Politecnico di Milano, Milan, Italy; 3Faculty of Electrical Engineering, K. N. Toosi University of Technology, Tehran, Iran; 4Department of Mechanical and Manufacturing Engineering, University of Calgary, Calgary, Alberta T2N 1N4, Canada; 5Center for Bioengineering Research and Education, Biomedical Engineering Program, University of Calgary, Calgary, Alberta T2N 1N4, Canada; 6Research and Technology Department, Alzahra University, Vanak, Tehran, Iran

*These authors contributed equally to this work

Correspondence: Maysam Zamani Pedram; Amir Sanati-Nezhad Email mzpedram@kntu.ac.ir; amir.sanatinezhad@ucalgary.ca

Background: Exosomes are small vesicles produced by almost all cells in the body and found in all biofluids. Cancer cell-derived exosomes are known to have distinct, measurable signatures, applicable for early cancer diagnosis. Despite the present bibliometric studies on Cancer detection and Nanoparticles, no single study exists to deal with Exosome bibliometric study.Methods: This bibliometric work investigated the publication trends of Exosomes nanoparticles and its application in cancer detection, for the literature from 2008 to July 2019. The data were collected from the Web of Science Core Collection. There were variant visual maps generated to show annual publication, most- relevant authors, sources, countries, topics and keywords. The network analysis of these studies was investigated to evaluate the research trends in the field of exosomes. In addition, the data were qualitatively analyzed according to 22 top-cited articles, illustrating the frequently used subjects and methods in exosomes research area.Results: The results showed that the documents in this field have improved the citation rate. The top-relevant papers are mostly published in Scientific Reports journal which has lost its popularity after 2017, while today, Analytical Chemistry is leading in publishing the most articles related to exosomes. The documents containing keywords of plasma, cells, cancer, biomarkers, and vesicles as keywords plus, are more likely to be published in PLoS One journal. The clustering of the keywords network showed that the keyword theme of extracellular vesicles has the highest centrality rate. In global research, USA is the most corresponding country, followed by China, Korea and Australia. Based on the qualitative analysis, the published documents with at least 50 citations have used exosome release, cargo, detection, purification and secretion, as their targets and applied cell culture or isolation as their methods.Conclusion: The bibliometric study on exosomes nanoparticles for cancer detection provides a clear vision of the future research direction and identifies the potential opportunities and challenges. This may lead new researchers to select the proper subfields in exosome-related research fields.

Keywords: exosomes, cancer detection, nanoparticles, microvesicles, bibliometrics, research productivity

This work is published and licensed by Dove Medical Press Limited. The full terms of this license are available at https://www.dovepress.com/terms.php and incorporate the Creative Commons Attribution - Non Commercial (unported, v3.0) License.By accessing the work you hereby accept the Terms. Non-commercial uses of the work are permitted without any further permission from Dove Medical Press Limited, provided the work is properly attributed. For permission for commercial use of this work, please see paragraphs 4.2 and 5 of our Terms.

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Publication Trends in Exosomes Nanoparticles for Cancer Detection | IJN - Dove Medical Press

The C3.ai Digital Transformation Institute has awarded six UC Berkeley faculty funding to use AI to mitigate the threat of COVID-19. Top row, from left: Stefano Bertozzi, Alberto Sangiovanni-Vincentelli and Gerbrand Ceder. Bottom row, from left: Karen Chapple, Teresa Head-Gordon and Jennifer Listgarten.

Six UC Berkeley-led projects have won funding from the recently launched C3.ai Digital Transformation Institute to harness the power of artificial intelligence (AI) to combat the spread of COVID-19 and other emerging diseases.

These wide-ranging research projects will use AI and machine learning tools to understand and reduce the threat posed by the SARS-CoV-2 virus in a variety of ways, from tracking the transmission dynamics of the virus in Mexico to speeding the discovery of small molecules that could one day serve as pharmaceutical treatments for the disease.

The C3.ai Digital Transformation Institute, a research consortium established in March by enterprise AI software company C3.ai and headquartered at Berkeley and the University of Illinois at Urbana-Champaign, aims to mobilize AI, machine learning and the Internet of Things to transform societal-scale systems.

The six Berkeley-led projects are among 26 projects awarded a total of $5.4 million by the institute to accelerate AI research for COVID-19 mitigation through advances in medicine, urban planning and public policy.

Stefano Bertozzi, dean emeritus and professor of health policy and management, will lead a project using data from the Mexican Social Security Institute to determine possible clinical, individual, facility and structural determinants of exposure and susceptibility to SARS-CoV-2, in hopes of better guiding prevention efforts and finding mechanisms that might improve COVID-19 patient outcomes.

A project led by Alberto Sangiovanni-Vincentelli, a professor of electrical engineering and computer sciences, will develop algorithms for AI that will help health care institutions better detect and contain emerging diseases like COVID-19.

Gerbrand Ceder, Chancellors Professor in the Department of Materials Science and Engineering, will head a project harnessing natural language processing techniques to scan and synthesize information in tens of thousands of emergent research articles, patents and clinical trials on COVID-19 to facilitate the formulation of actionable insights and new knowledge.

Karen Chapple, professor and chair of city and regional planning, will lead an interdisciplinary project to track housing evictions during and after the outbreak in an effort to better understand housing precarity and to inform public policy regarding U.S. housing inequality.

Teresa Head-Gordon, Chancellors Professor of chemistry, bioengineering and chemical and biomolecular engineering, will use machine learning techniques inspired by physics to speed the discovery of small molecules that could bind and disable the SARS-CoV-2 virus, leading to future drugs to treat the disease.

A project headed by Jennifer Listgarten, professor of electrical engineering and computer sciences, will draw upon techniques such as reinforcement learning, robust uncertainty estimation and probabilistic modeling to develop new and trustworthy methods for therapeutic drug discovery for COVID-19.

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Six UC Berkeley-led projects win funding to combat COVID-19 with AI - UC Berkeley

As the economic and health risks of the COVID-19 pandemic are predicted to persist into next year, there are growing reservations about society returning to normal.

The impacts of COVID-19, like the 2008 financial crisis and the 2001 September 11th attacks before, are changing global consciousness and reopening uncertainties about security, privacy and public health.

Unfortunately, like 9/11 and the 2001 anthrax attacks, the current COVID-19 pandemic reveals systemic infrastructural and security deficiencies that rendered countries like the United States powerless. This could have been avoided with better preparedness. However, preparedness requires maximum co-operation and transparency between government, researchers and industry.

As countries experience the ongoing economic and public health shocks caused by COVID-19, rogue actors seeking to take advantage of the pandemic may use bioweapons to similar effect.

Read more: Coronavirus is not a bioweapon but bioterrorism is a real future threat

Like the current pandemic, any biosecurity threat or epidemic could easily become a global concern. Pathogens do not recognize borders and will spread indiscriminately, ultimately disproportionately affecting poorer nations.

Globalization which is being analyzed as a contributor to the spread of COVID-19 could also help thwart the spread of man-made or naturally occurring diseases, provided multilateral co-operation remains intact.

Read more: Global urbanization created the conditions for the current coronavirus pandemic

The response has to be global because pandemics and terror attacks have persisting and grave effects, not tied specifically to a single state and its economy.

Governments must take a proactive stance against the growth and development of deadly pathogens (engineered or naturally occurring), which might require an overhaul of the socioeconomic and political relationships that govern health and our shared environments.

The most crucial response is intergovernmental collaboration and compliance with medical experts. This would involve the sharing of information and effective mitigation strategies against bioterrorism. The remarkable and unprecedented global unity today is demonstrated by scientists freely sharing information related to COVID-19 to speed up the development of a vaccine.

Governments and their collaborators must also stop the spread of disinformation to quell panic and alleviate the publics fears. This includes maintaining public trust in experts which must be differentiated from popular and political opinions that have led to chemical poisoning.

This has also been exacerbated with ongoing distrust for WHO officials as false claims and pandering to China has led to failures in the initial response to COVID-19 including indecision within the scientific community.

Terrorist organizations will undoubtedly use the spread of bioweapons to create civil turmoil and instability, reinvigorating or inciting national contentions such as scarcity, ethnic tension or religious infighting. This applies to countries already destabilized by entrenched conflicts, which can rapidly metastatize through competition and inequality already present in developing countries.

Overcoming pandemics and terrorism will inevitably rely on national infrastructure such as employing the military, which the Canadian government has done to supplement medical resources. Deploying a nations armed forces has the potential to apply the vast resources, equipment and labour that an organized and skilled military maintains.

Countries like Taiwan and Singapore managed the pandemic by implementing protocols that served to protect their citizens. These included analytic technologies to screen and isolate persons suspected of or confirmed to be infected with COVID-19. In South Korea, over 20,000 people were tested daily to track and treat cases. Medical supplies were stockpiled and temporary hospital units were established to prevent scarcity and minimize black-marketeering.

However, medical equipment cannot be kept indefinitely and replenishment will likely require unconventional methods to fulfil the demand. Canadian universities have helped address the scarcities of medical equipment by employing 3D printers to produce masks and other supplies.

The Canadian government is also investing in novel detection and management technologies, which could be re-purposed to detect bioweapons. This also includes vaccine and antiviral development that can proactively work against future disease outbreaks.

The Canadian government has also increased funding for coronavirus-related projects.

Preventing the bioengineering, emergence, release and spread of pathogens will require aggressive strategies. These include implementing regulations against the mistreatment and harvesting of wild and domestic animals to prevent their mixing and the unintentional mixing of viruses and infectious diseases. Managing land reclamation and protecting habitats can prevent biodiversity loss and reduce human contact with pathogenic viruses.

Other technologies in the fight against bioterrorism or pandemics include heightened surveillance and tracking in the form of smartphones and drones. Deployable 3D isolation units repurposed as mobile laboratories could also quickly respond to bioweapons threat.

To guarantee safety, the public has to be willingly compliant with government policies. In Canada, closing the national border and enacting quarantine Laws mitigated the spread of COVID-19, but the publics co-operation was essential to the public good.

Recommendations from health-care professionals and epidemiologists must be implemented at every stage, and directed by governments. The consequences of neglecting to act expeditiously are apparent in the United States, which has been marred by bureaucratic red tape, equipment scarcity and vacillating in leadership responses.

Lessons from previous pandemics can prepare us for both future inevitable global outbreaks and possible bioterrorist attacks.

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The COVID-19 pandemic can prepare us for future outbreaks and bioterrorism - The Conversation CA

The Green Solvents market report is a most important research for who looks for complete information on the Green Solvents market. The report covers all information on the global and regional markets including historic and future trends for market demand, size, trading, supply, competitors, and prices as well as global predominant vendors information. The forecast market information, SWOT analysis, Green Solvents market scenario, and feasibility study are the vital aspects analysed in this report.

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Top Leading Companies of Global Green Solvents Market are STEPAN CO.NOVAMONTINTREXON CORP.SUN CHEMICAL CORP.GREEN BIOLOGICS INC.PFIZER INC.INKEMIA GREEN CHEMICALSSYMRISE AGAKZO NOBELGODAVARI BIOREFINERIESTEVA PHARMACEUTICAL INDUSTRIESBASFL'ORAL INTERNATIONALManufacturers and Suppliers of Green Solvents and MaterialsFLORIDA CHEMICAL CO.FLORACHEM CORP.Global Bio-chemical Technology GroupPROCTER & GAMBLE CO.KERLEY INKCROPENERGIES AGYANCHENG HONGTAI BIOENGINEERING CO. LTD.GALACTIC S.A.P&G CHEMICALSPENTA MANUFACTURING CO.PETROBRASZHENGZHOU YIBANG INDUSTRY & COMMERCE CO. LTD.CHANGZHOU COMWIN FINE CHEMICALS CO LTD.CYTOCULTURE INTERNATIONAL INC.TOYO INK AMERICA, LLCCOSMAXTOKYO CHEMICAL INDUSTRY CO., LTD.JINDAN LACTIC ACIDCORBIONCJ CHEILJEDANG CORP.3MSHISEIDOAUROBINDO PHARMA LTD.ROCHELIBERTY CHEMICALS SRLSOLVAYPPG INDUSTRIES INC.GRAHAM CHEMICAL CORP.CYMER LLCUNILEVER UK LTD.FLINT GROUPNIHON KOLMAR CO., LTD.CARGILLVERTEC BIOSOLVENTS INC.GC INNOVATION AMERICAARCHER DANIELS MIDLAND CO.VERSALIS S.P.A.SANOFIHUADE BIOLOGICAL ENGINEERINGPOET, LLCMUSASHINO CHEMICAL LABORATORY, LTD.

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The leading players of Green Solvents industry, their market share, product portfolio, company profiles are covered in this report. The leading market players are analyzed on the basis of production volume, gross margin, market value, and price structure. The competitive market scenario among Green Solvents players will help the industry aspirants in planning their strategies. The statistics offered in this report will be precise and useful guide to shape the business growth.

Global Green Solvents Market Split by Product Type and Applications:

This report segments the global Green Solvents market on the basis ofTypesare:Bio-based Alcohols, Diols (Glycols) and Triols (Glycerol)Bio-based AlcoholsBio-based Diols/Bio-based GlycolsBio-based Triols/GlycerolD-limoneneLactate EstersFatty Acid Methyl EstersOthers

On the basis of Application, the Global Green Solvents market is segmented into:CosmeticsPaints and CoatingsPrinting InksCleaningOthers

Regional Analysis for Green Solvents Market:

For comprehensive understanding of market dynamics, the global Green Solvents market is analyzed across key geographies namely United States, Europe, China, Japan, Southeast Asia, India, Central & South America. Each of these regions is analyzed on basis of market findings across major countries in these regions for a macro-level understanding of the market.

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Crucial Elements from the Table of Contents of Global Green Solvents Market:

Green Solvents Market Overview Global Green Solvents Market Competition, Profiles/Analysis, Strategies Global Green Solvents Capacity, Production, Revenue (Value) by Region (2015-2020) Global Green Solvents Supply (Production), Consumption, Export, Import by Region (2015-2020) Global Green Solvents Market Regional Highlights Industrial Chain, Sourcing Strategy and Downstream Buyers Marketing Strategy Analysis, Distributors/Traders Market Effect Factors Analysis Market Decisions with respect to present scenario Global Green Solvents Market Forecast (2020-2026) Case Studies Research Findings and Conclusion

The research includes historic data from 2015 to 2020 and forecasts until 2026 which makes the report an invaluable resource for industry executives, marketing, sales and product managers, consultants, analysts and stakeholders looking for key industry data in readily accessible documents with clearly presented tables and graphs.

Finally, Green Solvents Market report is the believable source for gaining the market research that will exponentially accelerate your business. The report gives the principle locale, economic situations with the item value, benefit, limit, generation, supply, request and market development rate and figure and so on. Green Solvents industry report additionally Present new task SWOT examination, speculation attainability investigation, and venture return investigation.

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Green Solvents Market Along With COVID-19 Impact Analysis, Advancement and Outlook 2026 - Cole of Duty

D-Ribose Market research report provides an actual industry viewpoint, future trends and dynamics for market growth rate, market size, trading and key players of the industry with forecast period of 2026. This comprehensive research report is titled D-Ribose Market with Industry Analysis and Opportunity Assessment and it comprises a whole market scenario along with the dynamics affecting it.

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The report presents the market competitive landscape and a corresponding detailed analysis of the major vendor/key players in the market. Top Companies in the Global D-Ribose Market: Shandong DepuTuoyangAnsun BioengineeringShanghai Acebright Pharmaceuticals GroupZhengzhou Tuoyang IndustrialManus Aktteva BiopharmaChengzhi Life ScienceShandong Bangao

and others.

Global D-Ribose Market Split by Product Type and Applications:

This report segments the global D-Ribose market on the basis ofTypesare:Food Grade D-RibosePharmaceutical Grade D-Ribose

On the basis of Application, the Global D-Ribose market is segmented into:Pharmaceutical IntermediateFood AdditivesHealth Products

Regional Analysis For D-Ribose Market:

North America (United States, Canada and Mexico)Europe (Germany, France, UK, Russia and Italy)Asia-Pacific (China, Japan, Korea, India and Southeast Asia)South America (Brazil, Argentina, Colombia etc.)Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa)

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Key Market Features: The report evaluated key market features, including revenue, price, capacity, capacity utilisation rate, gross, production, production rate, consumption, import/export, supply/demand, cost, market share, CAGR, and gross margin. In addition, the study offers a comprehensive study of the key market dynamics and their latest trends, along with pertinent market segments and sub-segments.

Analytical Tools: The Global D-Ribose Market report includes the accurately studied and assessed data of the key industry players and their scope in the market by means of a number of analytical tools. The analytical tools such as Porters five forces analysis, SWOT analysis, feasibility study, and investment return analysis have been used to analyse the growth of the key players operating in the market.

Customisation of the Report: This report can be customised as per your needs for additional data up to 3 companies or countries or 40 analyst hours.

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Market Intelligence Data provides syndicated market research on industry verticals including Healthcare, Information and Communication Technology (ICT), Technology and Media, Chemicals, Materials, Energy, Heavy Industry, etc.Market Intelligence Data provides global and regional market intelligence coverage, a 360-degree market view which includes statistical forecasts, competitive landscape, detailed segmentation, key trends, and strategic recommendations.

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D-Ribose Market 2020 Global Trend, Segmentation and Opportunities Forecast To 2026 (Based on 2020 COVID-19 Worldwide Spread) - Cole of Duty

The report on the Industrial Grade Fumaric Acid market provides a birds eye view of the current proceeding within the Industrial Grade Fumaric Acid market. Further, the report also takes into account the impact of the novel COVID-19 pandemic on the Industrial Grade Fumaric Acid market and offers a clear assessment of the projected market fluctuations during the forecast period. The different factors that are likely to impact the overall dynamics of the Industrial Grade Fumaric Acid market over the forecast period (2019-2029) including the current trends, growth opportunities, restraining factors, and more are discussed in detail in the market study.

As per the presented market report, the global Industrial Grade Fumaric Acid market is projected to attain a CAGR growth of ~XX% during the assessment period and surpass a value of ~US$XX by the end of 20XX. Further, the report suggests that the growth of the Industrial Grade Fumaric Acid market hinges its hope on a range of factors including, emphasis on innovation by market players, surge in the investments pertaining to R&D activities, and favorable regulatory policies among others.

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Competition Landscape

The report provides critical insights related to the business operations of prominent companies operating in the Industrial Grade Fumaric Acid market. The revenue generated, market presence of different companies, product range, and the financials of each company is included in the report.

Regional Landscape

The regional landscape section of the report provides resourceful insights related to the scenario of the Industrial Grade Fumaric Acid market in the key regions. Further, the market attractiveness of each region provides players a clear understanding of the overall growth potential of the Industrial Grade Fumaric Acid market in each region.

End-User Analysis

The report provides a detailed analysis of the various end-users of the Industrial Grade Fumaric Acid along with the market share, size, and revenue generated by each end-user.

The following manufacturers are covered in this report:Bartek IngredientsPolynt GroupThirumalai ChemicalIsegenFuso ChemicalsNippon ShokubaiYantai Hengyuan BioengineeringJiangsu Jiecheng BioengineeringChangzhou Yabang ChemicalAnhui Sealong BiotechnologyChangmao Biochemical EngineeringSuzhou Youhe Science and TechnologyZhejiang Dongda Biological TechnologyChina Blue Star Harbin PetrochemicalJiangsu Suhua GroupJiaoda Rising Weinan ChemicalChina BBCA GroupJiangsu Sanmu Group

Industrial Grade Fumaric Acid Breakdown Data by TypePurity: 98.5%Purity: 99%

Industrial Grade Fumaric Acid Breakdown Data by ApplicationUnsaturated ResinOrganic SynthesisOthers

Industrial Grade Fumaric Acid Production Breakdown Data by RegionNorth AmericaEuropeChinaJapan

Industrial Grade Fumaric Acid Consumption Breakdown Data by RegionNorth AmericaUnited StatesCanadaMexicoEuropeGermanyFranceUKItalyRussiaAsia-PacificChinaJapanSouth KoreaIndiaAustraliaIndonesiaThailandMalaysiaPhilippinesVietnamCentral & South AmericaBrazilMiddle East & AfricaTurkeyGCC CountriesEgyptSouth Africa

The study objectives are:To analyze and research the global Industrial Grade Fumaric Acid capacity, production, value, consumption, status and forecast;To focus on the key Industrial Grade Fumaric Acid manufacturers and study the capacity, production, value, market share and development plans in next few years.To focuses on the global key manufacturers, to define, describe and analyze the market competition landscape, SWOT analysis.To define, describe and forecast the market by type, application and region.To analyze the global and key regions market potential and advantage, opportunity and challenge, restraints and risks.To identify significant trends and factors driving or inhibiting the market growth.To analyze the opportunities in the market for stakeholders by identifying the high growth segments.To strategically analyze each submarket with respect to individual growth trend and their contribution to the market.To analyze competitive developments such as expansions, agreements, new product launches, and acquisitions in the market.To strategically profile the key players and comprehensively analyze their growth strategies.

In this study, the years considered to estimate the market size of Industrial Grade Fumaric Acid :History Year: 2014-2018Base Year: 2018Estimated Year: 2019Forecast Year 2019 to 2025For the data information by region, company, type and application, 2018 is considered as the base year. Whenever data information was unavailable for the base year, the prior year has been considered.

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Assessing the Fallout From the Coronavirus Pandemic Industrial Grade Fumaric Acid Projected to be Resilient During 2019-2026 - Farmers Ledger

While baseless, the theory gained such prominence that social media platforms were forced to take action to stop its spread after a string of cell towers were set on fire. The US Federal Emergency Management Agency responded to the rumor saying, "5G technology does NOT cause coronavirus," and UK government officials called it a "crackpot conspiracy."

The theory attempting to link the pandemic to 5G is nonsensical. Covid-19 is caused by a contagious virus, and it's spreading in areas of the world that don't yet have 5G technology.

But such theories are not new; concerns about 5G's effects on health were spreading even before coronavirus. Experts say these fears, too, are unfounded.

"Is there anything to worry about? The short answer is no," said Chris Collins, a professor and research director in the radiology department at the New York University School of Medicine.

"If people are not worried about current cell phone technology, they should be worried even less about 5G."

What is 5G?

To understand why a small group of people are freaking out about it, it's time for a little gobbledygook: At its core, 5G is a set of technical specifications which a section of the radio frequency spectrum wireless devices use to communicate with the cell network. It's the same way 3G and 4G worked only, with 5G devices can access a wider range of radio frequency waves than before, allowing for improvements to speed and bandwidth.

There are three different types of 5G networks: networks that use the low-band, mid-band and high-band of the radio frequency spectrum. Low-band networks provide wide coverage but only mild improvements to speed, mid-band networks balance speed and coverage and high-band networks provide superfast speeds but signals don't travel very far.

Eventually, low- and mid-band networks are expected to cover much of the country. High-band networks will be built mostly in cities because they require installing multiple small cell sites in a given area to make up for the fact that signals struggle to travel.

Debunking 5G fears

Many conspiracy theories about the dangers of 5G focus on the radio frequencies that signals travel over. But experts point out that low-band and mid-band 5G networks operate at largely the same frequencies as existing networks.

"There's nothing different in terms of exposure," said Kenneth Foster, professor of bioengineering at the University of Pennsylvania, whose research focuses on the health and safety aspects of electromagnetic fields interacting with human bodies.

Major advancements from 5G will come as a result of high-band networks, where signals travel over millimeter wave frequencies.

But millimeter wave frequencies should prompt even less concern, NYU's Collins said, because they can't penetrate surfaces such as walls, trees or human skin (that's one of the reasons they don't travel well).

"It's a little ironic that there's all this worry about 5G, because the difference is that 5G is going to operate at higher frequencies," Collins said. "It will actually not penetrate as deep into the body ... it really doesn't get past the skin."

Millimeter wave frequencies are already used in other technologies people are familiar with, including airport security scanners.

"If you think about these airport scanners, that's using mmWave energy," Collins said. "You know it doesn't penetrate the body, because all you see in the image on the screen is the outer surface of the body."

Like FM radio waves and visible light, radio frequency waves are a form of "non-ionizing" radiation, which means they don't have enough energy to damage the DNA inside of cells and cause cancer, unlike X-rays, for example. Decades of research suggest that the only way wireless technologies could interact with the body is by heating the skin, but power levels are so low that's not a problem, experts say.

What are governments doing?

The US Federal Communications Commission, like government agencies elsewhere, regulates radio frequency exposure levels from wireless devices like cell phones. Exposure levels from 5G radio frequencies fall well below the agency's limits.

"The weight of scientific evidence has not effectively linked exposure to radio frequency energy from mobile devices with any known health problems," the FCC notes on its website.

Still, some critics argue that too few studies have been done on the potential effects of 5G. In response, most government agencies have stressed that they will continue to track research on 5G as network infrastructure expands.

"We first need to see how this new technology will be applied and how the scientific evidence will evolve," Vytenis Andriukaitis, head of the European Commission's Cabinet said in a 2017 response to critics that asked the Commission to put the 5G rollout on hold over fears about possible health effects.

"Rest assured that the Commission will keep abreast of future developments in view of safeguarding the health of the European citizens at the highest level possible," Andriukaitis said.

Foster said such a response is the best possible course of action in response to fears over 5G.

"We can only protect against dangers that we know exist," Foster said. "The EU's approach is as good as you can get if something indicates a problem that is reasonable, well then we'll look at the literature."

Now, more than ever, the world needs trustworthy reportingbut good journalism isnt free.Please support us by subscribing or making a contribution today.

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Why conspiracy theorists think 5G is bad for your health and why experts say not to worry - Gwinnettdailypost.com

The Global Bioreactors and Fermenters Market report gives all the essential information about the market and the aspects related to it in detail. There are different marketing strategies that every marketer looks up to in order to ace the competition in the Global market. Some of the primary marketing strategies that is needed for every business to be successful are Passion, Focus, Watching the Data, Communicating the value To Your Customers, Your Understanding of Your Target Market. There is a target set in market that every marketing strategy has to reach. So basically the Global Bioreactors and Fermenters Market report is deep study of the present market dynamics.

This study covers following key players:By CompanySartorius AG ?BBI?Thermo FisherMerck KGaAGE HealthcareDanaher (Pall)Eppendorf AGPraj Hipurity SystemsPierre Guerin (DCI-Biolafitte)ZETAApplikon BiotechnologyBioengineering AGInfors HTSolaris

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The Global Bioreactors and Fermenters Market is a highly competitive market with a huge number of vendors. Out of these number, there are some players that has been in this game for quite a time now and made it big for themselves. Whereas, there are many new startups as well who are coming up well. To standout in such a competitive landscape it is very important for vendors to adopt new innovative ideas or trends. To identify what makes the business stand out and to take the chance to gain advantage from these findings, SWOT analysis is used by marketers. Whereas PESTEL analysis is the study concerning Economic, Technological, legal political, social, environmental matters. For the analysis of market on the terms of research strategies, these techniques are helpful. A significant development has been recorded by the market of Bioreactors and Fermenters, in past few years.

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Market segment by Type, the product can be split intoBy TypeSingle-use BioreactorsMultiple-use Bioreactors

Market segment by Application, split intoBy ApplicationBiopharmaceutical CompaniesCROsAcademic and Research InstitutesOthers

It is also for it to grow further. Various important factors such as market trends, revenue growth patterns market shares and demand and supply are included in almost all the market research report for every industry. A systematized methodology is used to make a Report on the Global Bioreactors and Fermenters Market. For the analysis of market on the terms of research strategies, these techniques are helpful. All the information about the Products, manufacturers, vendors, customers and much more is covered in research reports.

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Global Bioreactors and Fermenters Market Research Report 2020 (Covid-19 Version) Market Drivers, End Users, Regions and Revenue Gross till 2025 -...

LOS ANGELES, United States:QY Research has recently published a report, titled Global Baropodometry Plateforms Market Research Report 2020-2026.The research report provides an in-depth explanation of the various factors that are likely to drive the market. It discusses the future of the market by studying the historical details. Analysts have studied the ever-changing market dynamics to evaluate their impact on the overall market. In addition, the Baropodometry Plateforms report also discusses the segments present in the market. Primary and secondary research methodologies have been used to provide the readers with an accurate and precise understanding of the overall Baropodometry Plateforms market. Analysts have also given readers an unbiased opinion about the direction companies will take during the forecast period.

The research report also includes the global Baropodometry Plateforms market figures that provide historical data as well as estimated figures. It gives a clear picture of the growth rate of the market during the forecast period. The Baropodometry Plateforms report aims to give the readers quantifiable data that is collected from verified data. The report attempts to answer all the difficult questions such as market sizes and company strategies.

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The vendor landscape and competitive scenarios of the global Baropodometry Plateforms market are broadly analyzed to help market players gain competitive advantage over their competitors. Readers are provided with detailed analysis of important competitive trends of the global Baropodometry Plateforms market. Market players can use the analysis to prepare themselves for any future challenges well in advance. They will also be able to identify opportunities to attain a position of strength in the global Baropodometry Plateforms market. Furthermore, the analysis will help them to effectively channelize their strategies, strengths, and resources to gain maximum advantage in the global Baropodometry Plateforms market.

Key Players Mentioned in the Global Baropodometry Plateforms Market Research Report: alFoots, Am Cube, Bauerfeind, BTS Bioengineering, Caporon Podologie, Diasu Health Technologies, DIFRS International, DIERS International, Eloi Podologie, Namrol, Noraxon, Novel, Podotech, Rsscan International, Synapsys, Tekscan, Xsensor, Zebris Medical, Biodex, Sani, Bauerfeund

Global Baropodometry Plateforms Market Segmentation by Product: Portable Type, Fixed Type

Global Baropodometry Plateforms Market Segmentation by Application: Hospital, Clinics, Others

The report comes out as an accurate and highly detailed resource for gaining significant insights into the growth of different product and application segments of the global Baropodometry Plateforms market. Each segment covered in the report is exhaustively researched about on the basis of market share, growth potential, drivers, and other crucial factors. The segmental analysis provided in the report will help market players to know when and where to invest in the global Baropodometry Plateforms market. Moreover, it will help them to identify key growth pockets of the global Baropodometry Plateforms market.

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Table of Content

1 Study Coverage1.1 Baropodometry Plateforms Product Introduction1.2 Key Market Segments in This Study1.3 Key Manufacturers Covered: Ranking of Global Top Baropodometry Plateforms Manufacturers by Revenue in 20191.4 Market by Type1.4.1 Global Baropodometry Plateforms Market Size Growth Rate by Type1.4.2 Portable Type1.4.3 Fixed Type1.5 Market by Application1.5.1 Global Baropodometry Plateforms Market Size Growth Rate by Application1.5.2 Hospital1.5.3 Clinics1.5.4 Others1.6 Coronavirus Disease 2019 (Covid-19): Baropodometry Plateforms Industry Impact1.6.1 How the Covid-19 is Affecting the Baropodometry Plateforms Industry1.6.1.1 Baropodometry Plateforms Business Impact Assessment Covid-191.6.1.2 Supply Chain Challenges1.6.1.3 COVID-19s Impact On Crude Oil and Refined Products1.6.2 Market Trends and Baropodometry Plateforms Potential Opportunities in the COVID-19 Landscape1.6.3 Measures / Proposal against Covid-191.6.3.1 Government Measures to Combat Covid-19 Impact1.6.3.2 Proposal for Baropodometry Plateforms Players to Combat Covid-19 Impact1.7 Study Objectives1.8 Years Considered

2 Executive Summary2.1 Global Baropodometry Plateforms Market Size Estimates and Forecasts2.1.1 Global Baropodometry Plateforms Revenue Estimates and Forecasts 2015-20262.1.2 Global Baropodometry Plateforms Production Capacity Estimates and Forecasts 2015-20262.1.3 Global Baropodometry Plateforms Production Estimates and Forecasts 2015-20262.2 Global Baropodometry Plateforms Market Size by Producing Regions: 2015 VS 2020 VS 20262.3 Analysis of Competitive Landscape2.3.1 Manufacturers Market Concentration Ratio (CR5 and HHI)2.3.2 Global Baropodometry Plateforms Market Share by Company Type (Tier 1, Tier 2 and Tier 3)2.3.3 Global Baropodometry Plateforms Manufacturers Geographical Distribution2.4 Key Trends for Baropodometry Plateforms Markets & Products2.5 Primary Interviews with Key Baropodometry Plateforms Players (Opinion Leaders)

3 Market Size by Manufacturers3.1 Global Top Baropodometry Plateforms Manufacturers by Production Capacity3.1.1 Global Top Baropodometry Plateforms Manufacturers by Production Capacity (2015-2020)3.1.2 Global Top Baropodometry Plateforms Manufacturers by Production (2015-2020)3.1.3 Global Top Baropodometry Plateforms Manufacturers Market Share by Production3.2 Global Top Baropodometry Plateforms Manufacturers by Revenue3.2.1 Global Top Baropodometry Plateforms Manufacturers by Revenue (2015-2020)3.2.2 Global Top Baropodometry Plateforms Manufacturers Market Share by Revenue (2015-2020)3.2.3 Global Top 10 and Top 5 Companies by Baropodometry Plateforms Revenue in 20193.3 Global Baropodometry Plateforms Price by Manufacturers3.4 Mergers & Acquisitions, Expansion Plans

4 Baropodometry Plateforms Production by Regions4.1 Global Baropodometry Plateforms Historic Market Facts & Figures by Regions4.1.1 Global Top Baropodometry Plateforms Regions by Production (2015-2020)4.1.2 Global Top Baropodometry Plateforms Regions by Revenue (2015-2020)4.2 North America4.2.1 North America Baropodometry Plateforms Production (2015-2020)4.2.2 North America Baropodometry Plateforms Revenue (2015-2020)4.2.3 Key Players in North America4.2.4 North America Baropodometry Plateforms Import & Export (2015-2020)4.3 Europe4.3.1 Europe Baropodometry Plateforms Production (2015-2020)4.3.2 Europe Baropodometry Plateforms Revenue (2015-2020)4.3.3 Key Players in Europe4.3.4 Europe Baropodometry Plateforms Import & Export (2015-2020)4.4 China4.4.1 China Baropodometry Plateforms Production (2015-2020)4.4.2 China Baropodometry Plateforms Revenue (2015-2020)4.4.3 Key Players in China4.4.4 China Baropodometry Plateforms Import & Export (2015-2020)4.5 Japan4.5.1 Japan Baropodometry Plateforms Production (2015-2020)4.5.2 Japan Baropodometry Plateforms Revenue (2015-2020)4.5.3 Key Players in Japan4.5.4 Japan Baropodometry Plateforms Import & Export (2015-2020)

5 Baropodometry Plateforms Consumption by Region5.1 Global Top Baropodometry Plateforms Regions by Consumption5.1.1 Global Top Baropodometry Plateforms Regions by Consumption (2015-2020)5.1.2 Global Top Baropodometry Plateforms Regions Market Share by Consumption (2015-2020)5.2 North America5.2.1 North America Baropodometry Plateforms Consumption by Application5.2.2 North America Baropodometry Plateforms Consumption by Countries5.2.3 U.S.5.2.4 Canada5.3 Europe5.3.1 Europe Baropodometry Plateforms Consumption by Application5.3.2 Europe Baropodometry Plateforms Consumption by Countries5.3.3 Germany5.3.4 France5.3.5 U.K.5.3.6 Italy5.3.7 Russia5.4 Asia Pacific5.4.1 Asia Pacific Baropodometry Plateforms Consumption by Application5.4.2 Asia Pacific Baropodometry Plateforms Consumption by Regions5.4.3 China5.4.4 Japan5.4.5 South Korea5.4.6 India5.4.7 Australia5.4.8 Taiwan5.4.9 Indonesia5.4.10 Thailand5.4.11 Malaysia5.4.12 Philippines5.4.13 Vietnam5.5 Central & South America5.5.1 Central & South America Baropodometry Plateforms Consumption by Application5.5.2 Central & South America Baropodometry Plateforms Consumption by Country5.5.3 Mexico5.5.3 Brazil5.5.3 Argentina5.6 Middle East and Africa5.6.1 Middle East and Africa Baropodometry Plateforms Consumption by Application5.6.2 Middle East and Africa Baropodometry Plateforms Consumption by Countries5.6.3 Turkey5.6.4 Saudi Arabia5.6.5 U.A.E

6 Market Size by Type (2015-2026)6.1 Global Baropodometry Plateforms Market Size by Type (2015-2020)6.1.1 Global Baropodometry Plateforms Production by Type (2015-2020)6.1.2 Global Baropodometry Plateforms Revenue by Type (2015-2020)6.1.3 Baropodometry Plateforms Price by Type (2015-2020)6.2 Global Baropodometry Plateforms Market Forecast by Type (2021-2026)6.2.1 Global Baropodometry Plateforms Production Forecast by Type (2021-2026)6.2.2 Global Baropodometry Plateforms Revenue Forecast by Type (2021-2026)6.2.3 Global Baropodometry Plateforms Price Forecast by Type (2021-2026)6.3 Global Baropodometry Plateforms Market Share by Price Tier (2015-2020): Low-End, Mid-Range and High-End

7 Market Size by Application (2015-2026)7.2.1 Global Baropodometry Plateforms Consumption Historic Breakdown by Application (2015-2020)7.2.2 Global Baropodometry Plateforms Consumption Forecast by Application (2021-2026)

8 Corporate Profiles8.1 alFoots8.1.1 alFoots Corporation Information8.1.2 alFoots Overview and Its Total Revenue8.1.3 alFoots Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.1.4 alFoots Product Description8.1.5 alFoots Recent Development8.2 Am Cube8.2.1 Am Cube Corporation Information8.2.2 Am Cube Overview and Its Total Revenue8.2.3 Am Cube Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.2.4 Am Cube Product Description8.2.5 Am Cube Recent Development8.3 Bauerfeind8.3.1 Bauerfeind Corporation Information8.3.2 Bauerfeind Overview and Its Total Revenue8.3.3 Bauerfeind Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.3.4 Bauerfeind Product Description8.3.5 Bauerfeind Recent Development8.4 BTS Bioengineering8.4.1 BTS Bioengineering Corporation Information8.4.2 BTS Bioengineering Overview and Its Total Revenue8.4.3 BTS Bioengineering Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.4.4 BTS Bioengineering Product Description8.4.5 BTS Bioengineering Recent Development8.5 Caporon Podologie8.5.1 Caporon Podologie Corporation Information8.5.2 Caporon Podologie Overview and Its Total Revenue8.5.3 Caporon Podologie Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.5.4 Caporon Podologie Product Description8.5.5 Caporon Podologie Recent Development8.6 Diasu Health Technologies8.6.1 Diasu Health Technologies Corporation Information8.6.2 Diasu Health Technologies Overview and Its Total Revenue8.6.3 Diasu Health Technologies Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.6.4 Diasu Health Technologies Product Description8.6.5 Diasu Health Technologies Recent Development8.7 DIFRS International8.7.1 DIFRS International Corporation Information8.7.2 DIFRS International Overview and Its Total Revenue8.7.3 DIFRS International Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.7.4 DIFRS International Product Description8.7.5 DIFRS International Recent Development8.8 DIERS International8.8.1 DIERS International Corporation Information8.8.2 DIERS International Overview and Its Total Revenue8.8.3 DIERS International Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.8.4 DIERS International Product Description8.8.5 DIERS International Recent Development8.9 Eloi Podologie8.9.1 Eloi Podologie Corporation Information8.9.2 Eloi Podologie Overview and Its Total Revenue8.9.3 Eloi Podologie Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.9.4 Eloi Podologie Product Description8.9.5 Eloi Podologie Recent Development8.10 Namrol8.10.1 Namrol Corporation Information8.10.2 Namrol Overview and Its Total Revenue8.10.3 Namrol Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.10.4 Namrol Product Description8.10.5 Namrol Recent Development8.11 Noraxon8.11.1 Noraxon Corporation Information8.11.2 Noraxon Overview and Its Total Revenue8.11.3 Noraxon Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.11.4 Noraxon Product Description8.11.5 Noraxon Recent Development8.12 Novel8.12.1 Novel Corporation Information8.12.2 Novel Overview and Its Total Revenue8.12.3 Novel Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.12.4 Novel Product Description8.12.5 Novel Recent Development8.13 Podotech8.13.1 Podotech Corporation Information8.13.2 Podotech Overview and Its Total Revenue8.13.3 Podotech Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.13.4 Podotech Product Description8.13.5 Podotech Recent Development8.14 Rsscan International8.14.1 Rsscan International Corporation Information8.14.2 Rsscan International Overview and Its Total Revenue8.14.3 Rsscan International Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.14.4 Rsscan International Product Description8.14.5 Rsscan International Recent Development8.15 Synapsys8.15.1 Synapsys Corporation Information8.15.2 Synapsys Overview and Its Total Revenue8.15.3 Synapsys Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.15.4 Synapsys Product Description8.15.5 Synapsys Recent Development8.16 Tekscan8.16.1 Tekscan Corporation Information8.16.2 Tekscan Overview and Its Total Revenue8.16.3 Tekscan Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.16.4 Tekscan Product Description8.16.5 Tekscan Recent Development8.17 Xsensor8.17.1 Xsensor Corporation Information8.17.2 Xsensor Overview and Its Total Revenue8.17.3 Xsensor Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.17.4 Xsensor Product Description8.17.5 Xsensor Recent Development8.18 Zebris Medical8.18.1 Zebris Medical Corporation Information8.18.2 Zebris Medical Overview and Its Total Revenue8.18.3 Zebris Medical Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.18.4 Zebris Medical Product Description8.18.5 Zebris Medical Recent Development8.19 Biodex8.19.1 Biodex Corporation Information8.19.2 Biodex Overview and Its Total Revenue8.19.3 Biodex Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.19.4 Biodex Product Description8.19.5 Biodex Recent Development8.20 Sani8.20.1 Sani Corporation Information8.20.2 Sani Overview and Its Total Revenue8.20.3 Sani Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.20.4 Sani Product Description8.20.5 Sani Recent Development8.21 Bauerfeund8.21.1 Bauerfeund Corporation Information8.21.2 Bauerfeund Overview and Its Total Revenue8.21.3 Bauerfeund Production Capacity and Supply, Price, Revenue and Gross Margin (2015-2020)8.21.4 Bauerfeund Product Description8.21.5 Bauerfeund Recent Development

9 Production Forecasts by Regions9.1 Global Top Baropodometry Plateforms Regions Forecast by Revenue (2021-2026)9.2 Global Top Baropodometry Plateforms Regions Forecast by Production (2021-2026)9.3 Key Baropodometry Plateforms Production Regions Forecast9.3.1 North America9.3.2 Europe9.3.3 China9.3.4 Japan

10 Baropodometry Plateforms Consumption Forecast by Region10.1 Global Baropodometry Plateforms Consumption Forecast by Region (2021-2026)10.2 North America Baropodometry Plateforms Consumption Forecast by Region (2021-2026)10.3 Europe Baropodometry Plateforms Consumption Forecast by Region (2021-2026)10.4 Asia Pacific Baropodometry Plateforms Consumption Forecast by Region (2021-2026)10.5 Latin America Baropodometry Plateforms Consumption Forecast by Region (2021-2026)10.6 Middle East and Africa Baropodometry Plateforms Consumption Forecast by Region (2021-2026)11 Value Chain and Sales Channels Analysis11.1 Value Chain Analysis11.2 Sales Channels Analysis11.2.1 Baropodometry Plateforms Sales Channels11.2.2 Baropodometry Plateforms Distributors11.3 Baropodometry Plateforms Customers12 Market Opportunities & Challenges, Risks and Influences Factors Analysis12.1 Market Opportunities and Drivers12.2 Market Challenges12.3 Market Risks/Restraints12.4 Porters Five Forces Analysis13 Key Finding in The Global Baropodometry Plateforms Study14 Appendix14.1 Research Methodology14.1.1 Methodology/Research Approach14.1.2 Data Source14.2 Author Details14.3 Disclaimer

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Baropodometry Plateforms Market Size, Analytical Overview, Growth Factors, Demand, Trends and Forecast to 2026| alFoots, Am Cube, Bauerfeind, BTS...

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The applications of QDs are as myriad as the spectrum of light. QDs have seen applications in lasers,2 quantum computing,3 medical imaging,4 inkjet printing,5 gene delivery,6 and solar cells.7 Commercially, however, many of these QDs are cadmium-selenide (CdSe) based. CdSe-based QDs pose a number of risks for human health. After UV-radiation or oxidation, CdSe-based QDs can release free cadmium ions,8 causing cell death. Other generations of CdSe-based QDs can induce the formation of reactive oxygen species that harm biological molecules.9

To combat this problem, UbiQD, a New Mexico-based tech company, has developed copper indium disulfide/zinc sulfide QDs. UbiQDs products are safe and eco-friendly, while also maintaining stability to moisture and elevated temperatures. Because these QDs are sold as dry powders, they can easily be dispersed in non-polar solvents.

Beyond the traditional capabilities and features of QDs, the products at UbiQD have been highlighted for their use in agriculture and near-IR utility.10 Over the next two blogs in this series, well provide a discussion of UbiQD and demonstrate what makes these QDs superior. You can see the QDs we offer in collaboration with UbiQD below.

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An overview of quantum dots and UbiQD - Cambridge Network

The way human body parts communicate with each other, especially when it comes to disease, is a still mystery. Its a puzzle Stephen Chan has been trying to solve.

We primarily define diseases based on where the originating events are occurring. For example, if someone is having a heart attack, you most often presume the problem is the heart, said Chan, director of the Vascular Medicine Institute at the University of Pittsburgh. But we are still learning about many different and surprising ways that separate body parts communicate with one another. So, signals from very separate and distinct organs of the body could in fact be the root causes of diseases of the heart and lung.

For more than a decade, unproven theories have percolated about tiny molecules called microRNAs that circulate in the bloodstream. Proof has been elusive as to whether they can act as long-range messengers between organ systems in living subjects and control important processes of human health and disease.

However, Chan and his team at Pitt and France have confirmed that hypothesis with a paper published today in the latest print issue of Circulation Research. Chan, a professor of medicine, is also director of the Center for Pulmonary Vascular Biology and Medicine.

The team tracked microRNA movement among blood systems in mice and showed that they can travel long distances throughout the body to influence disease development. Namely, Chans team found that microRNAs formed out of bone marrow and were transported to the inner lining of the blood vessels of the lung, promoting pulmonary hypertensiona deadly disease that currently has no cure.

We found definitive proof that microRNAs can function very much like hormones in our bloodstream, Chan said. It opens the door to a whole new way of looking at how the body senses and communicates.

For pulmonary hypertension, Chan said that doctors can now potentially develop treatment strategies aimed at tracking and modulating microRNAs in the blooda part of the body much more accessible than trying to deliver therapies to the lung.

But the studys implications go far beyond this single disease.

Perhaps this is also how the body talks to tumors in cancer or how the brain converses with the heart, Chan posits.

This study achieves importance as it has broad applicability to a great number of other disease states where endocrine delivery of microRNAs has been suggested to be the linchpin mechanism, said Jane Leopold, associate professor of medicine at Harvard Medical School and author of the papers editorial. She was part of the journals committee who reviewed the paper.

Chan also said he is interested in studying circulating microRNAs in physiological functions, such as exercise.

Exercise is the ultimate example of how all parts of the body must sense and work together intimately and in sync. MicroRNAs circulating in our blood could serve as the conduit that binds it all together.

Other Pitt researchers directly involved with the study include Partha Dutta, assistant professor of medicine in cardiology division; Prithu Sundd, assistant professor of medicine and bioengineering; Michael Risbano, assistant professor of medicine and director of the Advanced Cardiopulmonary Exercise Testing (ACPET) Program; and Seyed Nouraie, associate professor of medicine. In France, Thomas Bertero acted as a principal investigator at Universit Cte d'Azur.

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New Research Sheds Light on how Body Parts 'Talk' to Each Other - UPJ Athletics