StemCell Therapy

The Small Animal Imaging Equipment market report delivers an exhaustive analysis of this industry vertical and comprises of insights pertaining to the market tendencies including profits estimations, periodic deliverables, current revenue, industry share and remuneration estimations over the forecast period.

According to new latest Market Research Report on Small Animal Imaging Equipment Market size | Industry Segment by Applications (Cancer and Anti-cancer Drug Research, Immunology and Stem Cell Research, Pathological Mechanism and Virus Research, Gene Expression and Protein, Biophotonic Detection and Food Supervision and Environmental Supervision), by Type (Optical Imaging, Radionuclide Imaging, MRI, Computed Tomography Imaging and Ultrasound Imaging), Regional Outlook, Market Demand, Latest Trends, Infrared Temperature Measurement Instruments Industry Share & Revenue by Manufacturers, Company Profiles, Growth Forecasts 2025. Analyzes current market size and upcoming 5 years growth of this industry.

A summary of the performance evaluation of the Small Animal Imaging Equipment market is offered in the report. It also includes crucial information concerning to the key industry trends and projected growth rate of the said market. The study provides details regarding the growth avenues and hindering factors prevailing in the business space.

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Citing the regional scope of the Small Animal Imaging Equipment market:

Small Animal Imaging Equipment Market Segmentation:

An outlook of the data offered in the Small Animal Imaging Equipment market report:

A synopsis of the Small Animal Imaging Equipment market in terms of product spectrum and application terrain:

Product landscape:

Product types:

Vital data offered in the report:

Application Spectrum:

Application segmentation:

Details provided in the report:

Other parameters included in the report:

Some information concerning the competitive hierarchy of the Small Animal Imaging Equipment market:

Vendor base of Small Animal Imaging Equipment market:

Key parameters as per the report:

Key Market Benefits:

This report considers the below mentioned key questions:

Q.1. What are some of the most favorable, high-growth prospects for the global Small Animal Imaging Equipment market?

Q.2. Which products segments will grow at a faster rate throughout the forecast period and why?

Q.3. Which geography will grow at a faster rate and why?

Q.4. What are the major factors impacting market prospects? What are the driving factors, restraints, and challenges in this Small Animal Imaging Equipment market?

Q.5. What are the challenges and competitive threats to the market?

Q.6. What are the evolving trends in this Small Animal Imaging Equipment market and reasons behind their emergence?

Q.7. What are some of the changing customer demands in the Small Animal Imaging Equipment Industry market?

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Read more here:
Small Animal Imaging Equipment Market Trends, Growth, Scope, Size, Overall Analysis and Forecast by 2025 - Express Journal

Orian Research recently published a detailed market research study focused on the Regenerative Medicine Market across the global, regional and country level. The report provides 360 analysis of Regenerative Medicine Market from view of manufacturers, regions, product types and end industries. The research report analyses and provides the historical data along with current performance of the global Regenerative Medicine industry, and estimates the future trend of Regenerative Medicine market on the basis of this detailed study.

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The report covers projection as well as evaluation for the Regenerative Medicine market on a global as well as regional level. The study offers Regenerative Medicine historic information of 2017 in addition to a forecast from 2018 to 2023 based upon both quantity (Million Units) as well as revenue (USD Million). The research study includes chauffeurs and restraints for the Regenerative Medicine market along with the influence they carry the demand over the projection period. Additionally, the record includes the research of opportunities offered in the Regenerative Medicine market on a global level.

Complete report on Regenerative Medicine Market report spread across 152 pages, profiling 20 companies and supported with tables and figures available, Do Inquire more if any on this report @https://www.orianresearch.com/enquiry-before-buying/574056

Moreover, the report also offers key insights on the latest developments in the Regenerative Medicine Market that are transforming global industry. The report on the global Regenerative Medicine Market shows how the market performed in past and how it is expected to perform in the next few years.

The global Regenerative Medicine market is valued at 5350 million USD in 2017 and is expected to reach 19000 million USD by the end of 2023, growing at a CAGR of 23.5% between 2017 and 2023.

USA is the largest market of regenerative medicine, which occupies 51.09 percent of global regenerative medicine market share in 2015. It is followed by EU, which has around 16.66 percent of the global total industry. Other main regions which take important part in this industry include Japan and China.

Dominant Regenerative Medicine Market TOP Players: Competitive Insights

DePuy Synthes Medtronic ZimmerBiomet Stryker Acelity MiMedx Group Organogenesis UniQure Cellular Dynamics International Osiris Therapeutics Vcanbio Gamida Cell Golden Meditech Cytori Celgene Vericel Corporation Guanhao Biotech Mesoblast Stemcell Technologies Bellicum Pharmaceuticals

Global Regenerative Medicine Market report also includes Regenerative Medicine Market Business Overview. It also includes Regenerative Medicine Market by Applications and Type, Regenerative Medicine Revenue, Sales and Price and Regenerative Medicine Business Share. This report of Regenerative Medicine Market research also consists Global Regenerative Medicine Market Competition, by Regenerative Medicine market revenue of regions, sales and by Regenerative Medicine industry Competitive Players like.(2013-2018)

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Global Regenerative Medicine Market: Type Outlook:

Cell Therapy Tissue Engineering Biomaterial Other

Global Regenerative Medicine Market: Application Outlook:

Dermatology Cardiovascular CNS Orthopedic Others

Global Regenerative Medicine Market: Regional Outlook:

Europe Regenerative Medicine Market(Germany, France, Italy, Russia and UK)

North America Regenerative Medicine Market (Canada, USA and Mexico) Latin America Regenerative Medicine Market (Middle and Africa). Regenerative Medicine Market in Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa) Asia-Pacific Regenerative Medicine Market (South-east Asia, China, India, Korea and Japan).

Report on (2018-2023 Regenerative Medicine Market Report) mainly covers 15 sections acutely display the global Regenerative Medicine market:

Chapter 1: Describe Regenerative Medicine Introduction, product scope, market overview, market opportunities, market risk, and market driving force.Chapter 2: Analyze the top manufacturers of Regenerative Medicine, with sales, revenue, and price of Regenerative Medicine, in 2016 and 2017;Chapter 3: Display the competitive situation among the top manufacturers, with sales, revenue and market share in 2016 and 2017;Chapter 4: Show the global market by regions, with sales, revenue and market share of Regenerative Medicine, for each region, from 2013 to 2018;Chapter 5, 6, 7, 8 and 9: Analyze and talked about the key regions, with sales, revenue and market share by key countries in these regions.Chapter 10 and 11: Show the market by type and application, with sales market share and growth rate by type, application, from 2013 to 2018;Chapter 12: In Chapter Eleven Regenerative Medicine market forecast, by regions, type and application, with sales and revenue, from 2018 to 2023;Chapter 13, 14 and 15: Describe Regenerative Medicine sales channel, distributors, traders, dealers, appendix and data source.

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Regenerative Medicine Market 2020: Industry Share, Trends, SWOT Analysis by Top Vendors, Demand Outlook and Forecast Report to 2025 - Cole of Duty

A new research study has been presented by Dataintelo.com offering a comprehensive analysis on the Global Long Fibre Thermoplastics (LFT) Market where user can benefit from the complete market research report with all the required useful information about this market. This is a 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 is covered in the report. The report discusses all major market aspects with expert opinion on current market status along with historic data. This market report is a detailed study on the growth, investment opportunities, market statistics, growing competition analysis, major key players, industry facts, important figures, sales, prices, revenues, gross margins, market shares, business strategies, top regions, demand, and developments.

The Long Fibre Thermoplastics (LFT) Market report provides a detailed analysis of the global market size, regional and country-level market size, segment growth, market share, competitive landscape, sales analysis, impact of domestic and global market players, value chain optimization, trade regulations, recent developments, opportunity analysis, strategic market growth analysis, product launches, and technological innovations.

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Major Players Covered in this Report are: SabicSolvayCelanesePlastiCompQuadrantLanxessBASFDaicel PolymerAsahi Kasei PlasticsRTP

Global Long Fibre Thermoplastics (LFT) Market SegmentationThis market has been divided into Types, Applications, and Regions. The growth of each segment provides an accurate calculation and forecast of sales by Types and Applications, in terms of volume and value for the period between 2020 and 2026. This analysis can help you expand your business by targeting qualified niche markets. Market share data is available on the global and regional level. Regions covered in the report are North America, Europe, Asia Pacific, the Middle East & Africa, and Latin America. Research analysts understand the competitive strengths and provide competitive analysis for each competitor separately.

By Types:Long Glass Fibre Thermoplastic CompositesLong Carbon fibre Thermoplastic Composites

By Applications:AutomotiveConsumer GoodsSporting GoodsIndustrial Goods

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Global Long Fibre Thermoplastics (LFT) Market Regions and Countries Level AnalysisRegional analysis is a highly comprehensive part of this report. This segmentation sheds light on the sales of the Long Fibre Thermoplastics (LFT) on regional- and country-level. This data provides a detailed and accurate country-wise volume analysis and region-wise market size analysis of the global market.

The report offers an in-depth assessment of the growth and other aspects of the market in key countries including the US, Canada, Mexico, Germany, France, the UK, Russia, Italy, China, Japan, South Korea, India, Australia, Brazil, and Saudi Arabia. The competitive landscape chapter of the global market report provides key information about market players such as company overview, total revenue (financials), market potential, global presence, Long Fibre Thermoplastics (LFT) sales and revenue generated, market share, prices, production sites and facilities, products offered, and strategies adopted. This study provides Long Fibre Thermoplastics (LFT) sales, revenue, and market share for each player covered in this report for a period between 2016 and 2020.

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Table of Contents1. Executive Summary2. Assumptions and Acronyms Used3. Research Methodology4. Market Overview5. Global Market Analysis and Forecast, by Types6. Global Market Analysis and Forecast, by Applications7. Global Market Analysis and Forecast, by Regions8. North America Market Analysis and Forecast9. Latin America Market Analysis and Forecast10. Europe Market Analysis and Forecast11. Asia Pacific Market Analysis and Forecast12. Middle East & Africa Market Analysis and Forecast13. Competition Landscape

About DataIntelo:DATAINTELO has set its benchmark in the market research industry by providing syndicated and customized research report to the clients. The database of the company is updated on a daily basis to prompt the clients with the latest trends and in-depth analysis of the industry. Our pool of database contains various industry verticals that include: IT & Telecom, Food Beverage, Automotive, Healthcare, Chemicals and Energy, Consumer foods, Food and beverages, and many more. Each and every report goes through the proper research methodology, validated from the professionals and analysts to ensure the eminent quality reports.

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Long Fibre Thermoplastics (LFT) Market 2020 Global Market Size, Share, Trends, Manufacturers Analysis And Growth Forecast To 2026 - Latest Herald

Scientists at SN Bose National Centre for Basic Sciences, Kolkata (SNBNCBS) have developed a safe and cost-effective nanomedicine that promises treatment of a number of diseases by altering oxidative stress in the body. The research may provide a ray of hope in Indias fight against COVID-19, as the nanomedicine can decrease or increase reactive oxygen species in the body, depending on the situation and cure the disease.

The research on nanomedicines may be effective against viral infection. Recently, the institute has shown that the added oxidative stress upon administration of the nanomedicine can break down bilirubin that causes jaundice, providing a cure for this serious ailment.

In a trial on mice, the nanomedicine was found safe and swift, precisely bringing down bilirubin levels within two and a half hours. This ability of controlled enhancement of oxidative stress in mammals paves new potential for the application of nanomedicine in controlling virus infection, including COVID-19.

Link:
SNBNCBS develops nanomedicine to alter oxidative stress; may help in fight against COVID-19 - All India Radio

The Healthcare Nanotechnology Nanomedicine report provides independent information about the Healthcare Nanotechnology Nanomedicine industry supported by extensive research on factors such as industry segments size & trends, inhibitors, dynamics, drivers, opportunities & challenges, environment & policy, cost overview, porters five force analysis, and key companies profiles including business overview and recent development.

Healthcare Nanotechnology Nanomedicine MarketLatest Research Report 2020:

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In this report, our team offers a thorough investigation of Healthcare Nanotechnology Nanomedicine Market, SWOT examination of the most prominent players right now. Alongside an industrial chain, market measurements regarding revenue, sales, value, capacity, regional market examination, section insightful information, and market forecast are offered in the full investigation, and so forth.

Scope of Healthcare Nanotechnology Nanomedicine Market: Products in the Healthcare Nanotechnology Nanomedicine classification furnish clients with assets to get ready for tests, tests, and evaluations.

Major Company Profiles Covered in This Report

Abbott Laboratories, Combimatrix Corporation, GE Healthcare, Sigma-Tau Pharmaceuticals Inc., Johnson & Johnson, Mallinckrodt Plc, Merck & Company Inc., Nanosphere Inc., Pfizer, Inc., Celgene Corporation

Healthcare Nanotechnology Nanomedicine Market Report Covers the Following Segments:

Segment by Type:

BiochipImplant MaterialsMedical TextilesWound DressingOther

Segment by Application:

TherapeuticDiagnosticResearch

North America

Europe

Asia-Pacific

South America

Center East and Africa

United States, Canada and Mexico

Germany, France, UK, Russia and Italy

China, Japan, Korea, India and Southeast Asia

Brazil, Argentina, Colombia

Saudi Arabia, UAE, Egypt, Nigeria and South Africa

Market Overview:The report begins with this section where product overview and highlights of product and application segments of the global Healthcare Nanotechnology Nanomedicine Market are provided. Highlights of the segmentation study include price, revenue, sales, sales growth rate, and market share by product.

Competition by Company:Here, the competition in the Worldwide Healthcare Nanotechnology Nanomedicine Market is analyzed, By price, revenue, sales, and market share by company, market rate, competitive situations Landscape, and latest trends, merger, expansion, acquisition, and market shares of top companies.

Company Profiles and Sales Data:As the name suggests, this section gives the sales data of key players of the global Healthcare Nanotechnology Nanomedicine Market as well as some useful information on their business. It talks about the gross margin, price, revenue, products, and their specifications, type, applications, competitors, manufacturing base, and the main business of key players operating in the global Healthcare Nanotechnology Nanomedicine Market.

Market Status and Outlook by Region:In this section, the report discusses about gross margin, sales, revenue, production, market share, CAGR, and market size by region. Here, the global Healthcare Nanotechnology Nanomedicine Market is deeply analyzed on the basis of regions and countries such as North America, Europe, China, India, Japan, and the MEA.

Application or End User:This section of the research study shows how different end-user/application segments contribute to the global Healthcare Nanotechnology Nanomedicine Market.

Market Forecast:Here, the report offers a complete forecast of the global Healthcare Nanotechnology Nanomedicine Market by product, application, and region. It also offers global sales and revenue forecast for all years of the forecast period.

Research Findings and Conclusion:This is one of the last sections of the report where the findings of the analysts and the conclusion of the research study are provided.

About Us:

We publish market research reports & business insights produced by highly qualified and experienced industry analysts. Our research reports are available in a wide range of industry verticals including aviation, food & beverage, healthcare, ICT, Construction, Chemicals and lot more. Brand Essence Market Research report will be best fit for senior executives, business development managers, marketing managers, consultants, CEOs, CIOs, COOs, and Directors, governments, agencies, organizations and Ph.D. Students.

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Cover Corona Outbreak: Healthcare Nanotechnology Nanomedicine Market Size, Share & Trends Analysis Report By Product, By Technology, By...

By Nicole Bergot

A drug can prevent the virus responsible for the COVID-19 pandemic from replicating once inside an infected host, say researchers at the University of Alberta now searching for that magic bullet.

We aim to identify drugs that can be tested for effectiveness and safety in future trials, said Michael Woodside, a professor in the department of physics, using $370,700 in emergency funding from the Canadian Institutes of Health Research (CIHR) to find the elusive drug.

The plan is to screen first for drugs that are already approved for human use that could be repurposed to treat COVID-19 more quickly before broadening the search to potential drugs that are not currently approved.

Woodside explains that the genome of the novel coronavirus is made up of ribonucleic acid (RNA), not DNA so once inside an infected host, the virus inserts its RNA genome into the cell causing the creation of proteins the virus needs to replicate. And for all of this to occur, the novel coronavirus uses a process called programmed ribosomal frameshibing (PRF), a topic that Woodside, as a biophysicist, and his lab have been studying for years.

Researchers using laser tweezers to mimic what happens inside an infected cell were able to identify the mechanism through which PRF is triggered and now they can find molecular compounds to stop it from happening.

Most efforts to find drugs look for compounds that target the viral proteins directly, explains Woodside. Whats different about our approach is that we are targeting the virus through its RNA, rather than the proteins.

Woodside, inside the National Research Council of Canadas Nanotechnology Research Centre right here in Edmonton, is working closely with grad students, American counterparts, and Jack Tuszynski, a biophysics professor also in the department of physics, currently on secondment to the department of oncology in the faculty of medicine and dentistry.

Interdisciplinary research and scientific collaborations are essential to stopping the COVID-19 pandemic, said Woodside. Solutions have to engage expertise and approaches across a wide range of areas to understand the biophysics of the viral molecules, the biology of virus replication, the chemistry of drugs and their interactions with targets, the response of the immune system, the symptoms and epidemiology of the disease, and the response of patients to treatments.

Building and validating a model of the viral RNA for drug screening will occur over the next few months, with screening to identify approved drugs to follow before any potential candidates move toward preclinical tests.

Link:
'Laser tweezers' in nano lab used in search for drug to prevent COVID-19 replication - The Province

Advance Market Analyticsreleased the research report of Global Internet of Nano Things Market, offers a detailed overview of the factors influencing the global business scope.Global Internet of Nano Things Market research report shows the latest market insights with upcoming trends and breakdown of the products and services.The report provides key statistics on the market status, size, share, growth factors of the Global Internet of Nano Things.This Report covers the emerging players data, including: competitive situation, sales, revenue and global market share of top manufacturers are Honeywell International Inc. (United States), Intel Corporation (United States), Microsoft (United States), Apex Probes Ltd. (United Kingdom), Qualcomm Technologies, Inc. (United States), IBM (United States), Applied Nanodetectors Ltd. (United Kingdom), Siemens AG (Germany), Juniper Networks, Inc. (United States), Eutelsat (France), AT&T (United States), Huawei Technologies Co., Ltd. (China) and Kineis (France)

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The internet of nano things (IoNT) is an integrated system of miniaturized devices particularly nanosensors that are used to transfer data over the network connectivity. The various nanotechnologies integrated together into an IoNT system are used for a wide number of applications specifically a smart industry will use IoNT devices to monitor the temperature, humidity, and other environmental conditions. This technology is also widely used in the biomedical and healthcare sector for genetic engineering, health monitoring, etc. Many automobiles connected with those nanosensors or IoNT can help exchange data such as spatial information for improving the safety and accuracy of the automobile assistance systems.

Market Trend

Market Drivers

Opportunities

Restraints

Challenges

The Global Internet of Nano Thingsis segmented by following Product Types:

Application (Health Monitoring, Genetic Engineering, Environment Monitoring, Nuclear, Biological, and Chemical (NBC) Defenses, Food and Water Quality Control, Others), Components (Nano Nodes, Nano Routers, Nano Micro Interface Device, Gateway), Industry Verticals (Biomedical & Healthcare Industry, Transportation & Logistics Industry, Media & Entertainment Industry, Defense & Aerospace Industry, Manufacturing Industry, Energy & Utilities Industry, Retail Industry, Others)

Region Included are: North America, Europe, Asia Pacific, Oceania, South America, Middle East & Africa

Country Level Break-Up: United States, Canada, Mexico, Brazil, Argentina, Colombia, Chile, South Africa, Nigeria, Tunisia, Morocco, Germany, United Kingdom (UK), the Netherlands, Spain, Italy, Belgium, Austria, Turkey, Russia, France, Poland, Israel, United Arab Emirates, Qatar, Saudi Arabia, China, Japan, Taiwan, South Korea, Singapore, India, Australia and New Zealand etc.

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Strategic Points Covered in Table of Content of Global Internet of Nano Things Market:

Chapter 1: Introduction, market driving force product Objective of Study and Research Scope the Global Internet of Nano Things market

Chapter 2: Exclusive Summary the basic information of the Global Internet of Nano Things Market.

Chapter 3: Displayingthe Market Dynamics- Drivers, Trends and Challenges of the Global Internet of Nano Things

Chapter 4: Presenting the Global Internet of Nano Things Market Factor Analysis Porters Five Forces, Supply/Value Chain, PESTEL analysis, Market Entropy, Patent/Trademark Analysis.

Chapter 5: Displaying the by Type, End User and Region 2013-2018

Chapter 6: Evaluating the leading manufacturers of the Global Internet of Nano Things market which consists of its Competitive Landscape, Peer Group Analysis, BCG Matrix & Company Profile

Chapter 7: To evaluate the market by segments, by countries and by manufacturers with revenue share and sales by key countries in these various regions.

Chapter 8 & 9: Displaying the Appendix, Methodology and Data Source

Finally, Global Internet of Nano Things Market is a valuable source of guidance for individuals and companies.

Data Sources & Methodology

The primary sources involves the industry experts from the Global Internet of Nano Things Market including the management organizations, processing organizations, analytics service providers of the industrys value chain. All primary sources were interviewed to gather and authenticate qualitative & quantitative information and determine the future prospects.

In the extensive primary research process undertaken for this study, the primary sources Postal Surveys, telephone, Online & Face-to-Face Survey were considered to obtain and verify both qualitative and quantitative aspects of this research study. When it comes to secondary sources Companys Annual reports, press Releases, Websites, Investor Presentation, Conference Call transcripts, Webinar, Journals, Regulators, National Customs and Industry Associations were given primary weight-age.

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Thanks for reading this article; you can also get individual chapter wise section or region wise report version like North America, Europe or Asia.

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Advance Market Analytics is Global leaders of Market Research Industry provides the quantified B2B research to Fortune 500 companies on high growth emerging opportunities which will impact more than 80% of worldwide companies revenues.

Our Analyst is tracking high growth study with detailed statistical and in-depth analysis of market trends & dynamics that provide a complete overview of the industry. We follow an extensive research methodology coupled with critical insights related industry factors and market forces to generate the best value for our clients. We Provides reliable primary and secondary data sources, our analysts and consultants derive informative and usable data suited for our clients business needs. The research study enable clients to meet varied market objectives a from global footprint expansion to supply chain optimization and from competitor profiling to M&As.

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Internet of Nano Things Market Sees Slowest Growth on Consumption Slump - Latest Herald

Ongoing advancements in cancer research continue to lead to the introduction of newer and better treatment options including drug therapies. The provision of newer drugs and treatments is expected to improve the diagnostic and treatment rate for triple-negative breast cancer.

Some of the recent clinical efforts are being targeted at the molecular level characterization of triple-negative breast cancer across emerging therapeutic targets such as epigenetic proteins, PARP1, androgen receptors, receptor and non-receptor tyrosine kinases, and immune checkpoints.

Report Highlights:

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Company Profiles

These initiatives are anticipated to boost revenue growth of the triple-negative breast cancer treatment market. In a new research study, Persistence Market Research estimates the globaltriple-negative breast cancer treatment marketrevenue to cross US$ 720 Mn by 2026 from an estimated valuation of just under US$ 505 Mn in 2018. This is indicative of a CAGR of 4.7% during the period 2018 to 2026.

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Development of generics is another key opportunity area in the triple-negative breast cancer treatment market. With the rapidly expanding number of cancer cases across the world, there is a need for effective cancer management, including the provision of better and more efficient drugs.

Developing economies are faced with challenges on several fronts including paucity of funds and lack of proper treatment options, calling for more innovative approaches to affordable healthcare. The availability of biosimilars and affordable generic anti-cancer drugs in developing regions is expected to significantly reduce the burden of cancer care.

A projected cost reduction to the tune of more than 30% 40% and extended use of generic drugs is expected to reduce overall cancer treatment costs, thereby increasing the treatment rate for triple-negative breast cancer. This is further anticipated to create lucrative growth opportunities in the global triple-negative breast cancer treatment market.

Advances in Cancer Treatment and Introduction of Innovative Cancer Treatment Drugs to Boost Revenue Growth of the Triple-Negative Breast Cancer Treatment Market

Breast cancer is one of the most common types of cancer in women, and over the years, pharmaceutical and life sciences companies have been conducting advanced research and development activities to devise newer treatment options and drugs to treat breast cancer.

Several new drug formulations are currently in the pipeline in different stages of clinical development and this is expected to bode well for the triple-negative breast cancer treatment market. Innovation in oncology therapeutics has shifted focus towards an outcome based approach to cancer care, with an increasing emphasis on combination drugs and newer therapeutic modalities.

This is further likely to put the global triple-negative breast cancer treatment market on a positive growth trajectory in the coming years.

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Combination Therapy and Advancements in Nano Medicine Research Trending the Triple-Negative Breast Cancer Treatment Market

One of the biggest trends being observed in the global market for triple-negative breast cancer treatment is the shift towards combination therapy. Companies in the global triple-negative breast cancer treatment market are conducting clinical trials for combination therapies by collaborating with other players in the market.

Combination therapies are the latest innovation in the field of oncology and the combination of therapeutic drugs with chemotherapy is said to be an effective protocol for the treatment of triple-negative breast cancer.

Another huge trend in the triple-negative breast cancer treatment market is the emergence of nanotechnology as an efficient tool in the clinical management of critical diseases such as triple-negative breast cancer. It has been observed that the combination of gold nanoparticles and folic acid results in higher cell entry rate in both in-vitro and in-vivo models, indicative of the fact that folate receptors are effective targeted therapies for the treatment of triple-negative breast cancer.

Nanoparticles facilitate systematic and efficient delivery of drugs and agents to the site of the tumor. Advanced R&D in nanotechnology and nano medicine is one of the top trends likely to impact the global triple-negative breast cancer treatment market in the years to come.

Read the original here:
Triple Negative Breast Cancer Treatment Market to Grow at Stellar CAGR Double In% During the Forecast Period 2026 - Cole of Duty

Analysis Report on Nanomedicine Market

A report on global Nanomedicine market has hit stands. This study is based on different aspects like segments, growth rate, revenue, leading players, regions, and forecast. The overall market is getting bigger at an increased pace due to the invention of the new dynamism, which is making rapid progress.

The given report is an excellent research study specially compiled to provide latest insights into critical aspects of the Global Nanomedicine Market.

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Some key points of Nanomedicine Market research report:

Strategic Developments: The custom analysis gives the key strategic developments of the market, comprising R&D, new product launch, growth rate, collaborations, partnerships, joint ventures, and regional growth of the leading competitors operating in the market on a global and regional scale.

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

Analytical Tools: The Global Nanomedicine 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, feasibility study, and many other market research tools have been used to analyze the growth of the key players operating in the market.

COVID-19 Impact on Nanomedicine Market

Adapting to the recent novel COVID-19 pandemic, the impact of the COVID-19 pandemic on the global Nanomedicine market is included in the present report. The influence of the novel coronavirus pandemic on the growth of the Nanomedicine market is analyzed and depicted in the report.

The global Nanomedicine market segment by manufacturers include

market dynamics section of this report analyzes the impact of drivers and restraints on the global nanomedicine market. The impact of these drivers and restraints on the global nanomedicine market provides a view on the market growth during the course of the forecast period. Increasing research activities to improve the drug efficacy coupled with increasing government support are considered to be some of the major driving factors in this report. Moreover, few significant opportunities for the existing and new market players are detailed in this report.

Porters five forces analysis provides insights on the intensity of competition which can aid in decision making for investments in the global nanomedicine market. The market attractiveness section of this report provides a graphical representation for attractiveness of the nanomedicine market in four major regions North America, Europe, Asia-Pacific and Rest of the World, based on the market size, growth rate and industrial environment in respective regions, in 2012.

The global nanomedicine market is segmented on the basis of application and geography and the market size for each of these segments, in terms of USD billion, is provided in this report for the period 2011 2019. Market forecast for this applications and geographies is provided for the period 2013 2019, considering 2012 as the base year.

Based on the type of applications, the global nanomedicine market is segmented into neurological, cardiovascular, oncology, anti-inflammatory, anti-infective and other applications. Other applications include dental, hematology, orthopedic, kidney diseases, ophthalmology, and other therapeutic and diagnostic applications of nanomedicines. Nanoparticle based medications are available globally, which are aimed at providing higher bioavilability and hence improving the efficacy of drug. There have been increasing research activities in the nanomedicine filed for neurology, cardiovascular and oncology applications to overcome the barriers in efficient drug delivery to the target site. Moreover, the global nanomedicine market is also estimated and analyzed on the basis of geographic regions such as North America, Europe, Asia-Pacific and Rest of the World. This section describes the nanomedicine support activities and products in respective regions, thus determining the market dynamics in these regions.

The report also provides a few recommendations for the exisitng as well as new players to increase their market share in the global nanomedicine market. Some of the key players of this market include GE Healthcare, Mallinckrodt plc, Nanosphere Inc., Pfizer Inc., Merck & Co Inc., Celgene Corporation, CombiMatrix Corporation, Abbott Laboratories and others. The role of these market players in the global nanomedicine market is analyzed by profiling them on the basis of attributes such as company overview, financial overview, product portfolio, business strategies, and recent developments.

Moreover, the report highlighted revenue, sales, manufacturing cost, and product and the States that are most competitive in the lucrative market share idea. There is a discussion on the background and financial trouble in the global Nanomedicine economic market. This included the CAGR value during the outlook period leading to 2025.

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Addressing the potential impact of coronavirus disease (COVID-19) on Growth of Innovations in Nanomedicine Market by Major Players, Size, Industry...

Nanomedicine Marketwas valued US$ XX Bn in 2018 and is expected to reach US$ XX Bn by 2026, at CAGR of XX% during forecast period of 2019 to 2026.

The report study has analyzed revenue impact of covid-19 pandemic on the sales revenue of market leaders, market followers and disrupters in the report and same is reflected in our analysis.

Nanomedicine Market Drivers and Restrains:Nanomedicine is an application of nanotechnology, which are used in diagnosis, treatment, monitoring, and control of biological systems. Nanomedicine usages nanoscale manipulation of materials to improve medicine delivery. Therefore, nanomedicine has facilitated the treatment against various diseases. The nanomedicine market includes products that are nanoformulations of the existing drugs and new drugs or are nanobiomaterials. The research and development of new devices as well as the diagnostics will become, more effective, enabling faster response and the ability to treat new diseases are likely to boost the market growth.

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The nanomedicine markets are driven by factors such as developing new technologies for drug delivery, increase acceptance of nanomedicine across varied applications, rise in government support and funding, the growing need for therapies that have fewer side effects and cost-effective. However, long approval process and risks associated with nanomedicine (environmental impacts) are hampering the market growth at the global level. An increase in the out-licensing of nanodrugs and growth of healthcare facilities in emerging economies are likely to create lucrative opportunities in the nanomedicine market.

Nanomedicine Market Segmentation Analysis:Based on the application, the nanomedicine market has been segmented into cardiovascular, neurology, anti-infective, anti-inflammatory, and oncology. The oncology segment held the dominant market share in 2018 and is projected to maintain its leading position throughout the forecast period owing to the rising availability of patient information and technological advancements. However, the cardiovascular and neurology segment is projected to grow at the highest CAGR of XX% during the forecast period due to presence of opportunities such as demand for specific therapeutic nanovectors, nanostructured stents, and implants for tissue regeneration.

Nanomedicine Market Regional Analysis:Geographically, the Nanomedicine market has been segmented into North America, the Europe, Asia Pacific, Latin America, and Middle East & Africa. North America held the largest share of the Nanomedicine market in 2018 due to the rising presence of patented nanomedicine products, the availability of advanced healthcare infrastructure and the rapid acceptance of nanomedicine. The market in Asia Pacific is expected to expand at a high CAGR of XX% during the forecast period thanks to rise in number of research grants and increase in demand for prophylaxis of life-threatening diseases. Moreover, the rising investments in research and development activities for the introduction of advanced therapies and drugs are predicted to accelerate the growth of this region in the near future.

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Nanomedicine Market Competitive landscapeMajor Key players operating in this market are Abbott Laboratories, CombiMatrix Corporation, General Electric Company, Sigma-Tau Pharmaceuticals, Inc, and Johnson & Johnson. Manufacturers in the nanomedicine are focusing on competitive pricing as the strategy to capture significant market share. Moreover, strategic mergers and acquisitions and technological innovations are also the key focus areas of the manufacturers.

The objective of the report is to present a comprehensive analysis of Nanomedicine Market including all the stakeholders of the industry. The past and current status of the industry with forecasted market size and trends are presented in the report with the analysis of complicated data in simple language. The report covers all aspects of the industry with a dedicated study of key players that includes market leaders, followers and new entrants by region. PORTER, SVOR, PESTEL analysis with the potential impact of micro-economic factors by region on the market are presented in the report. External as well as internal factors that are supposed to affect the business positively or negatively have been analyzed, which will give a clear futuristic view of the industry to the decision-makers. The report also helps in understanding Nanomedicine Market dynamics, structure by analyzing the market segments and project the Nanomedicine Market size. Clear representation of competitive analysis of key players By Type, Price, Financial position, Product portfolio, Growth strategies, and regional presence in the Nanomedicine Market make the report investors guide.Scope of the Nanomedicine Market:

Nanomedicine Market by Modality:

Diagnostics TreatmentsNanomedicine Market by Diseases:

Oncological Diseases Infectious Diseases Cardiovascular Diseases Orthopedic Disorders Neurological Diseases Urological Diseases Ophthalmological Diseases Immunological DiseasesNanomedicine Market by Application:

Neurology Cardiovascular Anti-Inflammatory Anti-Infectives OncologyNanomedicine Market by Region:

Asia Pacific North America Europe Latin America Middle East AfricaNanomedicine Market Major Players:

Abbott Laboratories CombiMatrix Corporation General Electric Company Sigma-Tau Pharmaceuticals, Inc Johnson & Johnson Mallinckrodt plc. Merck & Company, Inc. Nanosphere, Inc. Pfizer, Inc. Teva Pharmaceutical Industries Ltd. Celgene Corporation UCB (Union Chimique Belge) S.A. AMAG Pharmaceuticals Nanospectra Biosciences, Inc. Arrowhead Pharmaceuticals, Inc. Leadiant Biosciences, Inc. Epeius Biotechnologies Corporation Cytimmune Sciences, Inc.

MAJOR TOC OF THE REPORT

Chapter One: Nanomedicine Market Overview

Chapter Two: Manufacturers Profiles

Chapter Three: Global Nanomedicine Market Competition, by Players

Chapter Four: Global Nanomedicine Market Size by Regions

Chapter Five: North America Nanomedicine Revenue by Countries

Chapter Six: Europe Nanomedicine Revenue by Countries

Chapter Seven: Asia-Pacific Nanomedicine Revenue by Countries

Chapter Eight: South America Nanomedicine Revenue by Countries

Chapter Nine: Middle East and Africa Revenue Nanomedicine by Countries

Chapter Ten: Global Nanomedicine Market Segment by Type

Chapter Eleven: Global Nanomedicine Market Segment by Application

Chapter Twelve: Global Nanomedicine Market Size Forecast (2019-2026)

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Nanomedicine Market : Industry Analysis and forecast 2026 - MR Invasion

The experiments took place in two plexiglass boxes connected by a tube. In one chamber, the team created a cloud of particles and blew them toward the tube, which was covered by different combinations of cloth. Mike Schmoldt and Greg Moss, environmental safety experts at Argonne who specialize in respirator testing and the effects of aerosol particles, used laboratory-grade scientific instruments to measured the number and size of particles in the chambers before and after passing through the fabric.

According to their results, one layer of a tightly woven cotton sheet, combined with two layers of polyester-based chiffona sheer fabric often used in evening gownsfiltered out the most aerosol particles (80% to 99%, depending on particle size). Substituting the chiffon with natural silk or a polyester-cotton flannel, or simply using a cotton quilt with cotton-polyester batting, produced similar results.

Though the study does not attempt to replicate real-world conditions, the findings are a useful guide. The researchers pointed out that tightly woven fabrics, such as cotton, can act as a mechanical barrier to particles; whereas fabrics that hold a static charge, like certain types of chiffon and natural silk, can serve as an electrostatic barrier. The electrostatic effect serves to suck in and hold the tiniest particles, which might otherwise slip through holes in the cotton. This is key to how N95 masks are constructed.

However, Guha added, even a small gap reduced the filtering efficiency of all masks by half or more, emphasizing the importance of a properly fitted mask.

Fabrics that did not do well included standard polyester and spandex with more open weave. In general, Guha said, fabric with tighter weaveswith fewer gaps between the strands of yarnworked better.

This is some of the first methodical data Ive seen on homemade masks. Its very helpful to have some idea of how the different types of fabric perform, said Emily Landon, executive medical director of infection prevention and control at the University of Chicago Medicine. I was also pleasantly surprised by how effective some of the homemade masks can be in the right conditions.

Landon noted that the advice to wear homemade masks while out in public is intended primarily to protect others from your own respiratory droplets, and that universal adoption of this recommendation will go a long way to make everyone safer.

In that case, any mask is better than none.

The first author on the study was Abhiteja Konda with Argonne National Laboratory. The other authors were Argonnes Abhinav Prakash as well as Pritzker School of Molecular Engineering graduate student Gregory Grant. The team used the U.S. Department of Energys Center for Nanoscale Materials user facility at Argonne National Laboratory.

Citation: Aerosol Filtration Efficiency of Common Fabrics Used in Respiratory Cloth Masks. Konda et al, ACS Nano, April 24, 2020. https://doi.org/10.1021/acsnano.0c03252

Funding: partly supported by the U.S. Department of Defense Vannevar Bush Fellowship

Read more:
Homemade masks made of silk and cotton may boost protection - UChicago News

The world is not only fighting a health pandemic but also an economic one, as the Novel Coronavirus (COVID 19) casts its long shadow over economies around the globe. The complete lockdown situation in several countries, has directly or indirectly impacted many industries causing a shift in activities like supply chain operations, vendor operations, product commercialization, etc. In the latest report on Nanomedicine Market, published by Market Research Intellect, numerous aspects of the current market scenario have been taken into consideration and a concise analysis has been put together to bring you with a study that has Pre- and Post-COVID market analysis. Our analysts are watching closely, the growth and decline in each sector due to COVID 19, to offer you with quality services that you need for your businesses. The report encompasses comprehensive information pertaining to the driving factors, detailed competitive analysis about the key market entities and relevant insights regarding the lucrative opportunities that lie in front of the industry players to mitigate risks in such circumstances.

It offers detailed research and analysis of key aspects of the global Nanomedicine market. The market analysts authoring this report has provided detailed information on growth drivers, restraints, challenges, trends, and opportunities to offer a complete analysis of the global Nanomedicine market. Market participants can use the market analysis to plan effective growth strategies and prepare for future challenges in advance. Each trend in the global Nanomedicine market is carefully analyzed and investigated by market analysts.

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The Major Players in Global Nanomedicine Market:

Global Nanomedicine Market Segmentation

This market was divided into types, applications and regions. The growth of each segment provides an accurate calculation and forecast of sales by type and application in terms of volume and value for the period between 2020 and 2026. This analysis can help you develop your business by targeting niche markets. Market share data are available at global and regional levels. The regions covered by the report are North America, Europe, the Asia-Pacific region, the Middle East, and Africa and Latin America. Research analysts understand the competitive forces and provide competitive analysis for each competitor separately.

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Nanomedicine Market Region Coverage (Regional Production, Demand & Forecast by Countries etc.):

North America (U.S., Canada, Mexico)

Europe (Germany, U.K., France, Italy, Russia, Spain etc.)

Asia-Pacific (China, India, Japan, Southeast Asia etc.)

South America (Brazil, Argentina etc.)

Middle East & Africa (Saudi Arabia, South Africa etc.)

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-> We will give you an assessment of the extent to which the market acquire commercial characteristics along with examples or instances of information that helps your assessment.

-> We will also support to identify standard/customary terms and conditions such as discounts, warranties, inspection, buyer financing, and acceptance for the Nanomedicine industry.

-> We will further help you in finding any price ranges, pricing issues, and determination of price fluctuation of products in Nanomedicine industry.

-> Furthermore, we will help you to identify any crucial trends to predict Nanomedicine market growth rate up to 2026.

-> Lastly, the analyzed report will predict the general tendency for supply and demand in the Nanomedicine market.

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Table of Contents:

Study Coverage: It includes study objectives, years considered for the research study, growth rate and Nanomedicine market size of type and application segments, key manufacturers covered, product scope, and highlights of segmental analysis.

Executive Summary: In this section, the report focuses on analysis of macroscopic indicators, market issues, drivers, and trends, competitive landscape, CAGR of the global Nanomedicine market, and global production. Under the global production chapter, the authors of the report have included market pricing and trends, global capacity, global production, and global revenue forecasts.

Nanomedicine Market Size by Manufacturer: Here, the report concentrates on revenue and production shares of manufacturers for all the years of the forecast period. It also focuses on price by manufacturer and expansion plans and mergers and acquisitions of companies.

Production by Region: It shows how the revenue and production in the global market are distributed among different regions. Each regional market is extensively studied here on the basis of import and export, key players, revenue, and production.

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Tags: Nanomedicine Market Size, Nanomedicine Market Growth, Nanomedicine Market Forecast, Nanomedicine Market Analysis

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Reinforcement Material Market report provide the COVID19 Outbreak Impact analysis of key factors influencing the growth of the market size (Production, Value and Consumption). This Reinforcement Material industry splits the breakdown (data status 2014-2019 and Six years forecast 2020-2026), by manufacturers, region, type and application. This study also analyses the Reinforcement Material market Status, Market Share, Growth Rate, Future Trends, Market Drivers, Opportunities and Challenges, Risks and Entry Barriers, Sales Channels, Distributors and Porters Five Forces Analysis.

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Reinforcement Material Market Taxonomy

On the basis of material, the global market is segmented into:

On the basis of end use industry, the global market is segmented into:

Reinforcement Material Market: Regional analysis includes:

Asia-Pacific (Vietnam, China, Malaysia, Japan, Philippines, Korea, Thailand, India, Indonesia, and Australia)

Europe (Turkey, Germany, Russia UK, Italy, France, etc.)

North America (the United States, Mexico, and Canada.)

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The report entitled Apoptosis Assays Market: Global Industry Analysis 2020-2029 is a comprehensive research study presenting significant data about the COVID 19 Impact On This Market By MarketResearch.Biz

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Becton, Bio-Rad Laboratories Inc, Creative Bioarray, Abcam plc, Promega Corporation, Sartorius AG, Dickinson and Company, Thermo Fisher Scientific Inc, R&D Systems Inc (A Subsidiary of Bio-Techne Corporation), Merck KGaA and Biotium Inc

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The report offers a multi-step view of the Global Apoptosis Assays Market. The first approach focuses through an impression of the market. This passage includes several definitions, arrangements, the chain assembly of the industry in one piece, and the various segmentation on the basis ofproduct type, detection technology, application, end user, and region along with different geographic regions for the global market. This part of the section also integrates an all-inclusive analysis of the different government strategies and enlargement plans that influence the market, its cost assemblies and industrialized processes. The second subdivision of the report includes analytics on the Global Apoptosis Assays Market based on its revenue size in terms of value and volume.

Apoptosis Assays Market Segmentation Analysis:-

Segmentation on The Basis of Product Type: Assay Kits, Reagents, Microplates, Instruments. Segmentation on the Basis of Detection Technology: Flow Cytometry, Cell Imaging & Analysis Systems, Spectrophotometry, Other Detection Technologies. Segmentation on the Basis of Application: Drug Discovery & Development, Clinical & Diagnostic Applications, Basic Research, Stem Cell Research. Segmentation on the Basis of End User: Pharmaceutical and Biotechnology Companies, Hospital and Diagnostic Laboratories, Academic and Research Institutes

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Apoptosis Assays Market Regional Analysis:-North America (United States, Canada),Europe (Germany, Spain, France, UK, Russia, and Italy),Asia-Pacific (China, Japan, India, Australia, and South Korea),Latin America (Brazil, Mexico, etc.),The Middle East and Africa (GCC and South Africa).

We have designed the Apoptosis Assays report with a group of graphical representations, tables, and figures which portray a detailed picture of Apoptosis Assays industry. Besides, the report has a clear objective to mark probable shareholders of the company. Highlighting business chain framework explicitly offers an executive summary of market evolution. Thus it becomes easy to figure out the obstacles and uplifting profit stats. In accordance with a competitive prospect, this Apoptosis Assays report dispenses a broad array of features essential for measuring the current Apoptosis Assays market performance along with technological advancements, business abstract, strengths and weaknesses of market position and hurdles crossed by the leading Apoptosis Assays market players to gain leading position.

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Report Table of Content Overview Gives Exact Idea About International Apoptosis Assays Market Report:

Chapter 1 describe Apoptosis Assays report important market inspection, product cost structure, and analysis, Apoptosis Assays market size and scope forecast From 2017 to 2026. Although, Apoptosis Assays market gesture, factors affecting the expansion of Apoptosis Assays business also deep study of arise and existing market holders.

Chapter 2 display top manufacturers of Apoptosis Assays market with sales and revenue and market share. Furthermore, Apoptosis Assays report analyses the import and export scenario of Apoptosis Assays industry, demand and supply ratio, labor cost, Apoptosis Assays raw material supply, production cost, marketing sources, and downstream consumers of Apoptosis Assays market.

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Apoptosis Assays Market Estimated CAGR, COVID 19 Impact Analysis Forecast To 2020-2029 Comprehensive Research By MarketResearch.Biz - Cole of Duty

Doctors are hoping stem cell therapy could be a weapon in the fight against coronavirus. On Friday, regenerative medicine company Mesoblast announced a 300-person trial to determine whether stem cell treatments will work in COVID-19 patients suffering from severe lung inflammation.

One hospital in New York tried it as an experiment with 12 patients, 10 of whom were able to come off of ventilators.

"What we saw in the very first patient was that within four hours of getting the cells, a lot of her parameters started to get better," Dr. Karen Osman, who led the team at Mount Sinai, told CBS News' Adriana Diaz.

The doctor said she was encouraged by the results, though she was hesitant to link the stem cell procedure to her patients' recovery.

"We don't know" if the 10 people removed from ventilators would not have gotten had they not gotten the stem cells, she said. "And we would never dare to claim that it was related to the cells."

She explained that only a "randomized controlled trial" would be the only way "to make a true comparison."

Luis Naranjo, a 60-year-old COVID-19 survivor, was one of Mount Sinai's stem cell trial success stories. He told Diaz in Spanish that he was feeling "much better."

Naranjo's daughter, Paola, brought him to the emergency room, fearful she would not see her father again. Like so many families struck by the coronavirus, she was not allowed inside with him.

"I forgot to tell him that I love him," she said. "All I said was go inside, I hope you feel better."

During his hospital stay, Naranjo was unconscious and on a ventilator for 14 days.

Doctors proposed giving him stem cells from bone marrow in hopes it would suppress the severe lung inflammation caused by the virus.

Now, Naranjo credits the doctors who treated him for his survival. Though income from his family's jewelry business has been cut off and they found themselves falling behind on rent, Naranjo said he is focused primarily on his recovery and regaining the 25 pounds he lost at the hospital.

Although stem cell treatment, usually reserved for other diseases like rheumatoid arthritis, might end up being another step toward helping coronavirus patients recover, Dr. Osman was quick to say it would not be a "miracle treatment."

"The miracle treatment will be a vaccine," she said.

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Coronavirus Doctors experiment with stem cell therapy on COVID-19 patients CBS News 9:39 AM - KTVQ Billings News

In the search for improved and high-throughput in vitro models, organoids have emerged as a promising 3D cell culture technology.1 Defined as a three-dimensional multicellular in vitro tissue construct, organoids are derived from cells that spontaneously self-organize into properly differentiated functional cell types to mimic at least some function of an organ.2 Organoid formation is driven by signaling cues in the extracellular matrix and medium, and is influenced by the particular cell types that are present.2 Compared with two-dimensional cultures, organoids incorporate more physiologically relevant cell-cell and cell-matrix interactions, and are a better reflection of the complex network found in vivo.With significant opportunities for studies of human-specific disease mechanisms, personalized medicine, drug discovery, pharmacokinetic profiling and regenerative medicine, organoids are being pursued across a range of disciplines. Many anticipate that these cell culture models will result in more efficient translation of research into clinical success. In this article, we explore the various types of organoids under development and shine a spotlight on some of the different approaches to organoids in cancer research.

Organoids can be derived from pluripotent stem cells (including embryonic stem cells or induced pluripotent stem cells) or neonatal or adult stem cells from healthy or diseased tissue.1,2 Cancer organoids have been generated from a range of human cancer tissues and cell lines including colon, pancreas, prostate, liver, breast, bladder and lung.6-12 This year, a research group led by Hongjun Song, Professor of Neuroscience at the Perelman School of Medicine at the University of Pennsylvania, published a report in Cell detailing methods for the rapid generation of patient-derived glioblastoma organoids.13Fresh tumor specimens were removed from 53 patient cases to produce microdissected tumor pieces that could survive, develop a spherical morphology and continuously grow in culture for at least two weeks (Figure 1). The production of glioblastoma organoids was achieved while maintaining a high level of similarity between the organoids and their parental tumors, with the expression levels of specific markers showing stability over long-term culture (48 weeks). Importantly, native cell-cell interactions were preserved by avoiding mechanical and enzymatic single-cell dissociation of the resected tumor. As Song explains, this was achieved on a clinically relevant timescale: Normally, the treatment for glioblastoma patients starts one month after surgery. The idea is that glioblastoma organoids can be generated within two weeks and subjected to testing of different treatment strategies to come up with the best option for a personalized treatment strategy.

Figure 1: Glioblastoma organoid generation, from fresh tumor pieces to frozen spherical organoids. Image used with permission from Jacob et al. 2020.One concern with organoid formation and expansion is the potential variability of the serum or Matrigel that can exist across batches and sources, creating variable exogenous factors that could cause the organoid to divert. This ultimately compromises reproducibility, a major bottleneck of current organoid systems.2,13 To avoid this source of error, Songs group used an optimized and defined medium devoid of variable factors that could contribute to the clonal selection of specific cell populations in culture.Glioblastoma is the most prevalent primary malignant brain tumor in adults,14 and having glioblastoma organoids available for research would present significant opportunities, explains Song: They can be used to test different drugs based on mutation profiles and to investigate mechanisms underlying tumor progression, drug sensitivity and resistance. While the accuracy of these predictions would need to be verified, researchers hope that patient-derived organoids will be used to help inform oncologists, accelerate drug discovery, and lead to better clinical trial design.Live-Cell Monitoring: Optimizing Workflows for Advanced Cell Models

As cell-based assays become technically more complex, the need to holistically capture dynamic and sometimes subtle cellular events becomes ever more important. By providing real-time imaging data of cellular events without disturbing the sample during the cell culture workflow, live-cell monitoring can support the optimization of these advanced models. Download this whitepaper to discover how live-cell monitoring can support such optimization, with a breadth of applications.

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For this to be achieved, techniques for the culture and genetic manipulation of primary human hepatocytes need to be refined. This has mostly been pursued through the culture of liver progenitors or fetal hepatocytes, which facilitate studies of liver cancers related to stem cells.16-18 To address the need for organoids derived from functional hepatocytes, researchers across 14 universities, research institutes and hospitals in China and Japan collaborated to genetically engineer reprogrammed human hepatocytes.18 The study, published in Nature Cell Biology, details the successful generation of organoids that represented two major types of liver cancer (hepatocellular carcinoma: HCC and intra-hepatic cholangiocarcinoma: ICC), derived from directly reprogrammed human hepatocytes (hiHeps).Lead author Lulu Sun, of the Shanghai Institute of Biochemistry and Cell Biology at the University of Chinese Academy of Sciences, provides an overview of how the liver cancer organoids were developed: Genomic aberrations begin to occur during cancer initiation, and the normal cells gradually became malignant. We modeled this process by introducing HCC/ICC-related oncogenes into the organoids with a lentivirus. Oncogenes were selected based on their mutation frequency and previous results in animals. Sun notes that gradual changes in cell and organoid morphology were observed in vitro, along with changes in the expression of HCC-related markers, before the organoids were transplanted to inspect their malignancy in vivo: We cultured these organoids in vitro for about two weeks and transplanted them into the liver lobule of immunodeficient mice. Six to eight weeks later, they formed features identical to HCCs.Even though numerous oncogenes have been identified through whole genome sequencing, it has been difficult to determine whether they can drive the initiation of human liver cancers. Ultrastructural analyses revealed that c-Myc, a well-known oncogene, induced HCC-initiation and a unique cellular phenotype in the hiHep organoids. In these cells, mitochondria were in unusually close contact with endoplasmic reticulum membranes. This excessive coupling between mitochondria and the endoplasmic reticulum (referred to as a MAM phenotype) was shown to facilitate HCC-initiation and when blocked, prevented the progression towards HCC, says Sun: Not only were the expression levels of HCC-related genes in organoids reduced, but significantly reduced cancers were formed in mice.Resolving these alterations in mitochondrial organization represents a new potential approach to liver cancer therapies, and possibly others, Sun explains: Restoration of a proper MAM interface may be a useful approach in preventing c-MYC-initiated HCCs. In addition, recently, an increasing number of works captured ultrastructural alterations, including MAMs, in the course of diseases including Alzheimer's disease and fatty liver diseases. Our results showed that the alterations between communications of organelles may also contribute to the cancer initiation process.All About Organoids

Organoids are 3D cell clusters with the structural and functional features of an organ, and can be generated from induced pluripotent stem cells (iPSCs) or adult stem cells acquired from a specific patient. Consequently, organoids make it possible to study the impact of a drug on a specific disease, even a persons own disease they are changing the face of research and medicine as we know it. Download this eBook to discover more about organoids including their analysis and how they are effecting personalized medicine.

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2. Huch, M., Knoblich, J. A., Lutolf, M. P, et al. (2017). The hope and the hype of organoid research. Development, 144(6), 938941. https://doi.org/10.1242/dev.150201

3. Hutchinson, L., & Kirk, R. (2011). High drug attrition ratesWhere are we going wrong? Nature Reviews Clinical Oncology, 8(4), 189190. https://doi.org/10.1038/nrclinonc.2011.34

4. Fan, H., Demirci, U., Chen, P. (2019). Emerging organoid models: Leaping forward in cancer research. Journal of Hematology & Oncology, 12(142). https://jhoonline.biomedcentral.com/articles/10.1186/s13045-019-0832-4

5. Drost, J., Clevers, H. (2018). Organoids in cancer research. Nature Reviews Cancer, 18(7), 407418. https://doi.org/10.1038/s41568-018-0007-6

6. van de Wetering, M., Francies, H. E., Francis, J. M., et al. (2015). Prospective Derivation of a Living Organoid Biobank of Colorectal Cancer Patients. Cell, 161(4), 933945. https://doi.org/10.1016/j.cell.2015.03.053

7. Boj, S. F., Hwang, C.-I., Baker, L. A., et al. (2015). Organoid Models of Human and Mouse Ductal Pancreatic Cancer. Cell, 160(12), 324338. https://doi.org/10.1016/j.cell.2014.12.021

8. Puca, L., Bareja, R., Prandi, D., et al. (2018). Patient derived organoids to model rare prostate cancer phenotypes. Nature Communications, 9(1), 2404. https://doi.org/10.1038/s41467-018-04495-z

9. Broutier, L., Mastrogiovanni, G., Verstegen, M. M., et al. (2017). Human primary liver cancerderived organoid cultures for disease modeling and drug screening. Nature Medicine, 23(12), 14241435. https://doi.org/10.1038/nm.4438

10. Sachs, N., de Ligt, J., Kopper, O., et al. (2018). A Living Biobank of Breast Cancer Organoids Captures Disease Heterogeneity. Cell, 172(12), 373-386.e10. https://doi.org/10.1016/j.cell.2017.11.010

11. Lee, S. H., Hu, W., Matulay, J. T., et al. (2018). Tumor Evolution and Drug Response in Patient-Derived Organoid Models of Bladder Cancer. Cell, 173(2), 515-528.e17. https://doi.org/10.1016/j.cell.2018.03.017

12. Kim, M., Mun, H., Sung, C. O., et al. (2019). Patient-derived lung cancer organoids as in vitro cancer models for therapeutic screening. Nature Communications, 10(1), 3991. https://doi.org/10.1038/s41467-019-11867-6

13. Jacob, F., Salinas, R. D., Zhang, D. Y., et al. (2020). A Patient-Derived Glioblastoma Organoid Model and Biobank Recapitulates Inter- and Intra-tumoral Heterogeneity. Cell, 180(1), 188-204.e22. https://doi.org/10.1016/j.cell.2019.11.03

14. Ostrom, Q. T., Gittleman, H., Truitt, G., et al. (2018). CBTRUS Statistical Report: Primary Brain and Other Central Nervous System Tumors Diagnosed in the United States in 20112015. Neuro-Oncology, 20(suppl_4), iv1iv86. https://doi.org/10.1093/neuonc/noy131

15. Bruix, J., Han, K.-H., Gores, G., et al. (2015). Liver cancer: Approaching a personalized care. Journal of Hepatology, 62(1), S144S156. https://doi.org/10.1016/j.jhep.2015.02.007

16. Hu, H., Gehart, H., Artegiani, B., et al. (2018). Long-Term Expansion of Functional Mouse and Human Hepatocytes as 3D Organoids. Cell, 175(6), 1591-1606.e19. https://doi.org/10.1016/j.cell.2018.11.013

17. Zhang, K., Zhang, L., Liu, W., et al. (2018). In Vitro Expansion of Primary Human Hepatocytes with Efficient Liver Repopulation Capacity. Cell Stem Cell, 23(6), 806-819.e4. https://doi.org/10.1016/j.stem.2018.10.018

18. Sun, L., Wang, Y., Cen, J., et al, (2019). Modelling liver cancer initiation with organoids derived from directly reprogrammed human hepatocytes. Nature Cell Biology, 21(8), 10151026. https://doi.org/10.1038/s41556-019-0359-5

19. Madhavan, M., Nevin, Z. S., Shick, H. E., et al. (2018). Induction of myelinating oligodendrocytes in human cortical spheroids. Nature Methods, 15(9), 700706. https://doi.org/10.1038/s41592-018-0081-4

20. Post, Y., Puschhof, J., Beumer, J., et al. (2020). Snake Venom Gland Organoids. Cell, 180(2), 233-247.e21. https://doi.org/10.1016/j.cell.2019.11.038

21. Calandrini, C., Schutgens, F., Oka, R., et al. (2020). An organoid biobank for childhood kidney cancers that captures disease and tissue heterogeneity. Nature Communications, 11(1), 1310. https://doi.org/10.1038/s41467-020-15155-6

22. Subramanian, A., Sidhom, E.-H., Emani, M., et al. (2019). Single cell census of human kidney organoids shows reproducibility and diminished off-target cells after transplantation. Nature Communications, 10(1), 5462. https://doi.org/10.1038/s41467-019-13382-0

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Organoids: Exploring Liver Cancer Initiation and the Possibilities of Personalized Glioblastoma Treatment - Technology Networks

Clockwise from top left, Dmitri Basov, Lawrence Goldstein, Terence Hwa, Clifford Kubiak, Kimberly Prather

The National Academy of Sciences elected five professors affiliated with the University of California San Diego to membership in the prestigious National Academy of Sciences, one of the highest honors bestowed on U.S. scientists and engineers.

UC San Diego faculty members Dmitri Basov, Lawrence Goldstein, Terence Hwa, Clifford Kubiak, and Kimberly Prather whose work spans fields ranging from medicine and biological sciences to atmospheric chemistry and physics were recognized Monday in recognition of their distinguished and continuing achievements in original research, according to the Academy. They were among 120 American scientists and 26 international members named this year.

For a young institution such as ours, having five professors inducted into the National Academy of Sciences speaks volumes of the innovative and visionary nature of this university and our well-respected and accomplished faculty, said UC San Diego Chancellor Pradeep K. Khosla. I am proud to see the career accomplishments of these five professors recognized on such a distinguished national platform, alongside the countrys other leading researchers.

This brings the total number of National Academy of Sciences members from UC San Diego to 86.

Dmitri Basov is an affiliated UC San Diego professor in the Department of Physics, where he served as chair between 2010 and 2015. He is also a Higgins professor in the Department of Physics at Columbia University, where he is the principal investigator of the Basov Infrared Laboratory, the director of the DOE Energy Frontiers Research Center on Programmable Quantum Materials and co-director of the Max Planck Society New York Center for Nonequilibrium Quantum Phenomena. His research interests include physics of quantum materials, superconductivity, two-dimensional materials and infrared nano-optics. Basov has received numerous prizes and awards including a Sloan Fellowship (1999), the Genzel Prize (2014), a Humboldt research award (2009), the Frank Isakson Prize, American Physical Society (2012), Moore Investigator (2014), the K.J. Button Prize (2019) and the Vannevar Bush Faculty Fellowship (U.S. Department of Defense, 2019).

Basov earned his PhD at the Lebedev Physical Institute of the Russian Academy of Sciences (1991). He served as postdoctoral research associate at McMaster University (1992-96) and as an assistant physicist at Brookhaven National Laboratory (1996) before joining UC San Diego.

Lawrence Goldstein, PhD, is Distinguished Professor in the Department of Cellular and Molecular Medicine and Department of Neurosciences in the UC San Diego School of Medicine. He founded and directed the UC San Diego Stem Cell Program and the Sanford Stem Cell Clinical Center at UC San Diego Health and is founding scientific director of the Sanford Consortium for Regenerative Medicine. He was instrumental in the development and passage of Proposition 71 in 2004, which created an unprecedented $3 billion fund and infrastructure for stem cell medical research in California.

For more than 25 years, Goldsteins research focus has been to unravel how molecular motors interact with and control the behavior of axonal vesicles in neurons, and how defects in these processes underlie neurological conditions, such as Alzheimers disease (AD).In 2012, his lab was the first to create stem cell-derived in vitro neurons of sporadic and hereditary AD, giving researchers a much-needed method for studying the diseases causes and pathologies and a new tool for developing and testing drugs to treat a disorder that afflicts 5.4 million Americans.

More recently, this work has led to the identification of new cellular targets in AD drug development and a deeper understanding of AD genetics and disease progression. He is among the nations leading scientific figures in promoting AD research and evidence-based treatments.

Terence Hwa is the Presidential Chair and Distinguished Professor in the Department of Physics with a joint appointment in the Division of Biological Sciences. Trained in theoretical physics, Hwa launched a biology wet-lab 15 years ago and developed a unique quantitative approach to studying bacterial physiology. During this time, the Hwa Research Group established a number of bacterial growth laws and formulated a principle of proteomic resource allocation. This line of study culminated in a theory of bacterial growth control, accurately predicting bacterial behaviors and gene expression for a variety of environmental and genetic perturbations, and resolving a number of long-standing mysteries in microbiology. Hwas research team continues to extend its quantitative approaches to characterize bacterial species singly and in consortium, to uncover underlying principles governing the spatiotemporal dynamics of microbial communities.

Hwa is a champion of interdisciplinary research. In 2001, he launched an extended program at the Kavli Institute of Theoretical Physics in Santa Barbara, which has been regarded as a watershed event in bringing physicists to post-genome biology. He is also the founder and co-director of the Quantitative Biology specialization program at UC San Diego. Hwa received fellowships and awards from the Sloan, Beckman, Guggenheim and Burroughs-Wellcome Foundations, and is a Fellow of the American Physical Society and the American Academy of Microbiology. Hwa received his PhD in physics from MIT. After postdoctoral research at Harvard University in condensed-matter physics, he joined UC San Diegos physics faculty in 1995.

Clifford Kubiak is a Distinguished Professor and former chair of the Department of Chemistry and Biochemistry, who holds the Harold C. Urey Chair in Chemistry. His Kubiak Research Group at UC San Diego is especially known for its work on developing catalysts for the electrochemical reduction of carbon dioxide. Kubiak is also a fellow of the American Academy of Arts and Sciences and the American Chemical Society (ACS). He has received several awards including the prestigious ACS Award in Organometallic Chemistry (2018), the Tolman Medal (2018), the Basolo Medal for Outstanding Research in Inorganic Chemistry (2015), the Inter-American Photochemical Society, Award in Photochemistry (2013) and the ACS Award in Inorganic Chemistry (2012). Kubiak has held visiting appointments at Tohoku University, University of Chicago and University of Erlangen, and he was a visiting associate in chemistry at the Joint Center for Artificial Photosynthesis at Caltech. He has served on the Editorial Advisory Boards of Accounts of Chemical Research, Inorganic Chemistry and Materials Science in Semiconductor Processing. He is the author of more than 290 scientific articles.

Before joining UC San Diego in 1998, Kubiak was a faculty member at Purdue University (1982-98). Before that he was a postdoctoral associate with Mark S. Wrighton at MIT (1980-81). He received his PhD in chemistry from the University of Rochester (1980), where he worked with Richard Eisenberg.

Kimberly Prather is a Distinguished Professor who holds a joint appointment between UC San Diegos Scripps Institution of Oceanography and the Department of Chemistry and Biochemistry. Prathers research focuses on understanding the influence of atmospheric aerosols on clouds, human health, and climate. Early in her career, she developed a technique known as aerosol time-of-flight mass spectrometry that is widely used in atmospheric field studies around the world to determine the origin and chemistry of aerosols. She is the founding director of the National Science Foundation Center for Aerosol Impacts on Chemistry of the Environment (CAICE), the largest federally funded center in the history of UC San Diego. CAICE researchers replicate ocean/atmosphere interactions in a laboratory setting to study the influence of ocean biology on atmospheric chemistry, clouds, and climate.

Prather joined UC San Diego in 2001. She was elected as a member of the American Academy of Arts and Sciences and a fellow of the American Geophysical Union in 2010. In 2019, she became the first woman at UC San Diego to be elected as a member of the National Academy of Engineering. Previously this year, she won the 2020 Frank H. Field and Joe L. Franklin Award for Outstanding Achievement in Mass Spectrometry from the American Chemical Society. She received her PhD in chemistry from the University of California, Davis.

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Five UC San Diego Professors Elected to National Academy of Sciences - UC San Diego Health

The Hemolung Respiratory Assist System is a minimally invasive device that does the work of the lungs by removing carbon dioxide directly from the blood.

A device designed at the University of Pittsburgh could help improve outcomes as a treatment for COVID-19 when used in conjunction with non-invasive or mechanical ventilation, and it recentlyreceived Emergency Use Authorization (EUA) from the U.S. Food and Drug Administration. Health records from a New York study showed that close to 90 percent of patients who were placed on mechanical ventilation did not survive. Some intensive care units are now considering mechanical ventilation as a last resort because of the complications and side effects associated with the process, and researchers believe this device could help.

The Hemolung Respiratory Assist System is a minimally invasive device that does the work of the lungs by removing carbon dioxide directly from the blood, much as a dialysis machine does the work of the kidneys. The device was developed by William Federspiel, PhD, professor of bioengineering at Pitts Swanson School of Engineering, and the Pittsburgh-based lung-assist device company ALung Technologies, co-founded by Federspiel.

A public health emergency related to COVID-19 was declared by the Secretary of Health and Human Services on February 4, 2020, and the FDA issued ALung the EUA to treat lung failure caused by the disease. Hemolung could help eliminate damage to the lungs caused by ventilators and does not require intubation or sedation, which allows patients to remain mobile during treatment.

Ventilation can cause serious issues in lungs that are already being damaged by the disease itself, said Federspiel. The Hemolung would allow the lung to rest and heal during the ventilation process by allowing for gentler ventilation. It could also prevent certain patients, who have less severe symptoms, from having to go on ventilation in the first place.

Mechanical ventilation requires patients to be sedated and intubated, and a myriad of complications can arise from the treatment, including collapsed lung, alveolar damage, and ventilator-associated pneumonia. For these more critically ill patients, the Hemolung could be used to help remove CO2, which would allow the mechanical ventilation process to be done more gently.

Before resorting to mechanical ventilation, less severe COVID-19 cases can use non-invasive ventilation, which uses a mask to help support breathing, but sometimes this treatment is not sufficient. In this case, the Hemolung device could be used to support the non-invasive methods and prevent mechanical ventilation altogether.

Peter M. DeComo, Chairman and CEO of ALung Technologies, stated, With published mortality rates as high as 90% for patients receiving invasive mechanical ventilation (IMV), we believe that the Hemolung can be a valuable tool for physicians to be used in conjunction with IMV, by reducing or eliminating the potential of further lung damage caused by high ventilator driving pressures, often referred to as Ventilator Induced Lung Injury. Many of the academic medical centers involved with our clinical trial have already requested the use of the Hemolung RAS for treatment of their COVID-19 patients.

Created to help chronic obstructive pulmonary disease (COPD) and acute respiratory distress syndrome (ARDS) patients, Hemolung has already been used on thousands of patients in Europe, where it was approved in 2013, and it is currently in clinical trials in the United States.

Since the onset of the pandemic, the device has been used on some COVID-19 patients with success; however, set-up of the Hemolung is not trivial. Medical professionals would need to be trained to use the technology, and it would take time to supply a significant number of devices.

Federspiel also holds appointments in the School of Medicine and the McGowan Institute for Regenerative Medicine (MIRM) at Pitt and is a Fellow of the National Academy of Inventors.

This technology developed by Dr. Federspiel and ALung Technologies is a perfect example of how collaborative research at the McGowan Institute can impact human lives, said William Wagner, director of MIRM and professor of surgery, bioengineering and chemical engineering at Pitt. A clinical viewpoint is necessary, but medical training doesnt give you an engineers perspective of design and manufacturing. You need a solid foot in both camps to make progress.

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Giving Distressed Lungs a Safer Fighting Chance - Global Health News Wire

EIB, kENUP Foundation and Pluristem Will Host Investor & Analyst Call

HAIFA, Israel, April 27, 2020 (GLOBE NEWSWIRE) -- Pluristem Therapeutics Inc. (Nasdaq:PSTI) (TASE:PSTI), a leading regenerative medicine company developing a platform of novel biological therapeutic products, cordially invites investors, the media, and the public to join a signing ceremony and analyst & investor call on Thursday, April 30, 2020.

Signing Ceremony: 10:00h CEST / 11:00 IDT/ 4:00 am EDT

Signing of a Memorandum of Understanding on Bio-Convergence in Health between the European Investment Bank and Israel Innovation Authority of the State of Israel

&

Signing of Finance Contract on Innovation Cell Therapies (EGFF) between the European Investment Bank and Pluristem.

Bio-Convergence Health is a collaboration between Israel and Europe to advance technological and investment alliances.

As previously announced, the European Investment Bank is providing a 50 million non-dilutive financing to Pluristem in support of the Companys research and development in the EU to further advance its regenerative cell therapy platform, and to assist moving the products in its pipeline to market, with a special focus on clinical development of PLX cells as a treatment for complications associated with COVID-19.

The half-hour signing ceremony will be live streamed at: https://signing-ceremony.eu/

Investor & Analyst Call: 15:00h CEST / 16:00h IDT / 09:00 am EDTThe European Investment Bank, kENUP Foundation and Pluristem will conduct a call to discuss the 50 million financing. Analysts are invited to ask questions during the Q&A session. The public is invited to listen to the call at: https://signing-ceremony.eu/

About the European Investment BankThe European Investment Bank (EIB) is the long-term lending institution of the European Union, owned by its Member States. It makes long-term finance available for sound investment in order to contribute towards EU policy goals.

Investment Plan for EuropeThe Investment Plan for Europe (the Juncker Plan) is one of the EU's key actions to boost investment in Europe, thereby creating jobs and fostering growth. To this end, smarter use will be made of new and existing financial resources. The EIB Group, consisting of the European Investment Bank and the European Investment Fund, is playing a vital role in this investment plan. With guarantees from the European Fund for Strategic Investments (EFSI), the EIB and EIF are able to take on a higher share of project risk, encouraging private investors to participate in the projects. In addition to EFSI, the new European Investment Advisory Hub (EIAH) helps public and private sector project promoters to structure investment projects more professionally. The projects and agreements approved under EFSI (European Fund for Strategic Investments) so far are expected to mobilise almost 466 billion of investments and will benefit over 1 million start-ups and SMEs (Small Medium Enterprises) in the 27 Member States.

About kENUP FoundationkENUP is a global partnership in innovation, promoting research based innovation for Europe with public and societal benefit. kENUP develops projects to pursue market-leading positions for European innovation businesses. In this capacity, kENUP is supporting the execution of the European Fund for Strategic Investments (EFSI, the so-called Juncker Plan), alongside its successor EFSI 2.0 and of the current InvestEU Fund. kENUP is a not-for-profit organization established as a foundation in the Republic of Malta by Public Deed on November 6, 2014. kENUPs activities are published in the European Transparency Register.

About Pluristem TherapeuticsPluristem Therapeutics Inc. is a leading regenerative medicine company developing novel placenta-based cell therapy product candidates. The Company has reported robust clinical trial data in multiple indications for its patented PLX cell product candidates and is currently conducting late stage clinical trials in several indications. PLX cell product candidates are believed to release a range of therapeutic proteins in response to inflammation, ischemia, muscle trauma, hematological disorders and radiation damage. The cells are grown using the Company's proprietary three-dimensional expansion technology and can be administered to patients off-the-shelf, without tissue matching. Pluristem has a strong intellectual property position; a Company-owned and operated GMP-certified manufacturing and research facility; strategic relationships with major research institutions; and a seasoned management team.

Safe Harbor StatementThis press release contains express or implied forward-looking statements within the Private Securities Litigation Reform Act of 1995 and other U.S. Federal securities laws. For example, Pluristem is using forward-looking statements when it discusses its expectation to receive the financing from the EIB, the belief that the financing will support its research and development in the EU to further advance its regenerative cell therapy platform, to assist moving the products in its pipeline to market, with a special focus on clinical development of PLX cells as a treatment for complications associated with COVID-19. These forward-looking statements and their implications are based on the current expectations of the management of Pluristem only, and are subject to a number of factors and uncertainties that could cause actual results to differ materially from those described in the forward-looking statements. The following factors, among others, could cause actual results to differ materially from those described in the forward-looking statements: changes in technology and market requirements; Pluristem may encounter delays or obstacles in launching and/or successfully completing its clinical trials; Pluristems products may not be approved by regulatory agencies, Pluristems technology may not be validated as it progresses further and its methods may not be accepted by the scientific community; Pluristem may be unable to retain or attract key employees whose knowledge is essential to the development of its products; unforeseen scientific difficulties may develop with Pluristems process; Pluristems products may wind up being more expensive than it anticipates; results in the laboratory may not translate to equally good results in real clinical settings; results of preclinical studies may not correlate with the results of human clinical trials; Pluristems patents may not be sufficient; Pluristems products may harm recipients; changes in legislation may adversely impact Pluristem; inability to timely develop and introduce new technologies, products and applications; loss of market share and pressure on pricing resulting from competition, which could cause the actual results or performance of Pluristem to differ materially from those contemplated in such forward-looking statements. Except as otherwise required by law, Pluristem undertakes no obligation to publicly release any revisions to these forward-looking statements to reflect events or circumstances after the date hereof or to reflect the occurrence of unanticipated events. For a more detailed description of the risks and uncertainties affecting Pluristem, reference is made to Pluristem's reports filed from time to time with the Securities and Exchange Commission.

Contact:Dana RubinDirector of Investor Relations972-74-7107194danar@pluristem.com

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The European Investment Bank (EIB), EU Delegation to Israel, the Israel Innovation Authority, and Pluristem Cordially Invite the Public to an Online...

HAIFA, Israel, April 24, 2020 (GLOBE NEWSWIRE) -- Pluristem Therapeutics Inc. (Nasdaq:PSTI) (TASE:PSTI), a leading regenerative medicine company developing a platform of novel biological therapeutic products, announced today that the European Investment Bank (EIB) has approved a 50 million non-dilutive financing for the Company (the Approved Financing). This Approved Financing, once received, will support Pluristems research and development in the EU to further advance its regenerative cell therapy platform, and to assist moving the products in its pipeline to market, with a special focus on clinical development of PLX cells as a treatment for complications associated with COVID-19. The Approved Financing will be deployed in three tranches, subject to the achievement of certain clinical, regulatory and scaling up milestones, with the first tranche consisting of 20 million. The expected signing date of the financing agreement relating to the Approved Financing is April 30, 2020.

Pluristem recently formed a wholly-owned subsidiary in Berlin, Germany, underscoring the Companys commitment to having a physical presence in Europe to advance research and development, and to prepare for commercialization, for its product candidates.

The Approved Financing is backed by a guarantee from the European Fund for Strategic Investments (EFSI), the financial pillar of the Investment Plan for Europe, under which the EIB and the European Commission are working together as strategic partners to boost Europes economic competitiveness. The transaction has been initiated by kENUP Foundation, a global partnership in innovation, promoting research-based innovation for Europe with public and societal benefit.

The Approved Financing, once granted, will not be secured and will be payable to the EIB in a single payment following five years from the disbursement of the first and second tranches and in two annual payments starting on the fourth year from disbursement of the third tranche, with each tranche having an interest rate of between 3% to 4%. The Approved Financing will support up to 50% of Pluristems R&D project cost. In addition, the EIB would be entitled to receive royalties from future revenues for a period of seven years starting 2024, at a rate of 0.2% to 2.3%, pro-rated to the amounts that the Company received from the Approved Financing.

We are extremely honored to have been selected by the EIB for this prestigious financing. We believe that this financing will allow us to significantly advance the clinical development of our lead product candidates, which if successful we expect will improve the quality of life for millions of patients around the world. Having established research partnerships with leading European institutions such as Charit University of Medicine Berlin, BIH Center for Regenerative Therapy (BCRT) and the Berlin Center for Advanced Therapies (BeCAT), as well as formed a subsidiary in Berlin, we understand the importance of having a physical presence in key markets, stated Pluristem CEO and President, Yaky Yanay. As we move forward into a multinational clinical trial for PLX cells to treat patients suffering from complications associated with COVID-19, we expect this EIB financing will accelerate our path to approval and to making a potentially effective COVID-19 treatment available worldwide.

About the European Investment Bank The European Investment Bank (EIB) is the long-term lending institution of the European Union, owned by its Member States. It makes long-term finance available for sound investment in order to contribute towards EU policy goals.

Investment Plan for Europe The Investment Plan for Europe (the Juncker Plan) is one of the EU's key actions to boost investment in Europe, thereby creating jobs and fostering growth. To this end, smarter use will be made of new and existing financial resources. The EIB Group, consisting of the European Investment Bank and the European Investment Fund, is playing a vital role in this investment plan. With guarantees from the European Fund for Strategic Investments (EFSI), the EIB and EIF are able to take on a higher share of project risk, encouraging private investors to participate in the projects. In addition to EFSI, the new European Investment Advisory Hub (EIAH) helps public and private sector project promoters to structure investment projects more professionally. The projects and agreements approved under EFSI (European Fund for Strategic Investments) so far are expected to mobilise almost 466 billion of investments and will benefit over 1 million start-ups and SMEs (Small Medium Enterprises) in the 27 Member States.

About Pluristem TherapeuticsPluristem Therapeutics Inc. is a leading regenerative medicine company developing novel placenta-based cell therapy product candidates. The Company has reported robust clinical trial data in multiple indications for its patented PLX cell product candidates and is currently conducting late stage clinical trials in several indications. PLX cell product candidates are believed to release a range of therapeutic proteins in response to inflammation, ischemia, muscle trauma, hematological disorders and radiation damage. The cells are grown using the Company's proprietary three-dimensional expansion technology and can be administered to patients off-the-shelf, without tissue matching. Pluristem has a strong intellectual property position; a Company-owned and operated GMP-certified manufacturing and research facility; strategic relationships with major research institutions; and a seasoned management team.

Safe Harbor Statement This press release contains express or implied forward-looking statements within the Private Securities Litigation Reform Act of 1995 and other U.S. Federal securities laws. For example, Pluristem is using forward-looking statements when it discusses its expectation that it will execute a definitive agreement for the Approved Financing and the proposed terms of such Approved Financing, the belief that the Approved Financing will support its research and development in the EU to further advance its regenerative cell therapy platform, to assist moving the products in its pipeline to market, with a special focus on clinical development of PLX cells as a treatment for complications associated with COVID-19, that such Approved Financing will allow it to significantly advance its clinical development of its lead product candidates which it expects will improve the quality of life for millions of patients around the world and the expectation that the Approved Financing will accelerate its path to approval of its COVID-19 multinational clinical trial and to making a potentially effective COVID-19 treatment available worldwide. While the EIB has announced the approval of the Approved Financing, there is no guarantee that the Company and the EIB will execute the definitive agreement on April 30, 2020, if at all, or that it will achieve the milestones necessary to receive any or all of the three tranches. These forward-looking statements and their implications are based on the current expectations of the management of Pluristem only, and are subject to a number of factors and uncertainties that could cause actual results to differ materially from those described in the forward-looking statements. The following factors, among others, could cause actual results to differ materially from those described in the forward-looking statements: changes in technology and market requirements; Pluristem may encounter delays or obstacles in launching and/or successfully completing its clinical trials; Pluristems products may not be approved by regulatory agencies, Pluristems technology may not be validated as it progresses further and its methods may not be accepted by the scientific community; Pluristem may be unable to retain or attract key employees whose knowledge is essential to the development of its products; unforeseen scientific difficulties may develop with Pluristems process; Pluristems products may wind up being more expensive than it anticipates; results in the laboratory may not translate to equally good results in real clinical settings; results of preclinical studies may not correlate with the results of human clinical trials; Pluristems patents may not be sufficient; Pluristems products may harm recipients; changes in legislation may adversely impact Pluristem; inability to timely develop and introduce new technologies, products and applications; loss of market share and pressure on pricing resulting from competition, which could cause the actual results or performance of Pluristem to differ materially from those contemplated in such forward-looking statements. Except as otherwise required by law, Pluristem undertakes no obligation to publicly release any revisions to these forward-looking statements to reflect events or circumstances after the date hereof or to reflect the occurrence of unanticipated events. For a more detailed description of the risks and uncertainties affecting Pluristem, reference is made to Pluristem's reports filed from time to time with the Securities and Exchange Commission.

Contact:Dana RubinDirector of Investor Relations+972-74-7107194danar@pluristem.com

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Pluristem Secures 50 Million Non-Dilutive Financing from the European Investment Bank to Support its COVID-19 Project and Phase III StudiesEXPECTED...