A UB-led research team has discovered a technique that could help increase the effectiveness of vaccines against the novel coronavirus, the virus that causes COVID-19.

Jonathan F. Lovell, associate professor in the Department of Biomedical Engineering, is the primary investigator on the research, titled SARS-CoV-2 RBD Neutralizing Antibody Induction is Enhanced by Particulate Vaccination, which was published online today in Advanced Materials.

COVID-19 has caused a disruptive global pandemic, infecting at least 40 million worldwide and causing more than 220,000 deaths in the United States alone. Since it began spreading in early 2020, biomedical researchers have been in active pursuit of an effective vaccine.

According to Lovell, one answer might lie in designing vaccines that partially mimic the structure of the virus. One of the proteins on the virus located on the characteristic COVID spike has a component called the receptor-binding domain, or RBD, which is its Achilles heel. That is,he says, antibodies against this part of the virus have the potential to neutralize the virus.

It would be appealing if a vaccine could induce high levels of antibodies against the RBD, Lovell says. One way to achieve this goal is to use the RBD protein itself as an antigen; that is, the component of the vaccine that the immune response will be directed against.

The team hypothesized that by converting the RBD into a nanoparticle (similar in size to the virus itself) instead of letting it remain in its natural form as a small protein, it would generate higher levels of neutralizing antibodies and its ability to generate an immune response would increase.

Lovells team had previously developed a technology that makes it easy to convert small, purified proteins into particles through the use of liposomes, or small nanoparticles formed from naturally occurring fatty components. In the new study, the researchers included within the liposomes a special lipid called cobalt-porphyrin-phospholipid, or CoPoP. That special lipid enables the RBD protein to rapidly bind to the liposomes,forming more nanoparticles that generate an immune response, Lovell explains.The team observed that when the RBD was converted into nanoparticles, it maintained its correct, three-dimensional shape and the particles were stable in incubation conditions similar to those in the human body. When laboratory mice and rabbits were immunized with the RBD particles, high antibody levels were induced. Compared to other materials that are combined with the RBD to enhance the immune response, only the approach with particles containing CoPoP gave strong responses.

Other vaccine adjuvant technology does not have the capacity to convert the RBD into particle-form, Lovell notes.

We think these results provide evidence to the vaccine-development community that the RBD antigen benefits a lot from being inparticle format, he says. This could help inform future vaccine design that targets this specific antigen.

Lovells co-authors on the study include Wei-Chiao Huang, Shiqi Zhou, Xuedan He and Moustafa T. Mabrouk, all from the UB Department of Biomedical Engineering; Kevin Chiem and Luis Martinez-Sobrido, both from Texas Biomedical Research Institute; Ruth H. Nissly, Ian M. Bird and Suresh V. Kuchipudi, all from the Animal Diagnostic Laboratory, Department of Veterinary and Biomedical Sciences at Pennsylvania State University; Mike Strauss and Joaquin Ortega from the Department of Anatomy and Cell Biology at McGill University; Suryaprakash Sambhara from the Immunology and Pathogenesis Branch of the U.S. Centers for Disease Control and Prevention; Elizabeth A. Wohlfert from the UB Department of Microbiology and Immunology; and Bruce A. Davidson from the Department of Anesthesiology and the Department of Pathology and Anatomical Sciences at UB.

Lovell founded the Lovell Lab at UB in 2012. It is focused on developing novel nanomedicine approaches to meet unmet needs in treating and preventing disease. He is also a co-founder of POP Biotechnologies Inc., a preclinical stage biotechnology company developing next-generation drug and vaccines products.

The study was supported by the U.S. National Institutes of Health and the Facility for Electron Microscopy Research (FEMR) at McGill University. FEMR is supported by the Canadian Foundation for Innovation, Quebec Government and McGill.

Read the original:
Transforming coronavirus protein into a nanoparticle could be key to effective COVID-19 vaccine - UB Now: News and views for UB faculty and staff -...

The global Nanomedicine Market Reports review the latest Nanomedicine market trends with a perceptive attempt to disclose the near-future growth prospects. An in-depth analysis on a geographic basis provides strategic business intelligence for particular sector investments. the study reveals profitable investment strategies for Nanomedicine companies, business executives, product marketing managersand new business investors..

report evaluates the key opportunities in the market and outlines the factors that are and will be driving the growth of the industry. global Nanomedicine Market Growth has also been forecasted for the period 2020-2025, compelling into consideration the previous growth patterns, the growth drivers and the current and future trends.

Get a Sample Copy of the Report at-https://www.absolutereports.com/enquiry/request-sample/15462802

The global Nanomedicine market consists of a number of players. The company outlining of the below market players has been done in the report consisting of their business overview, financial overview and the business strategies adopted by the companies.

Nanomedicine Market Report Highlights key Market Dynamics of sector, Various definitions and classification of applications of the Nanomedicine market industry and Chain structure with Upstream Raw Materials, Sourcing Strategy and Downstream Buyers are given. Additionally, prime strategical activities in the market, which includes Nanomedicine market share, product developments, mergers and acquisitions, partnerships, etc., are discussed.

Key Companies

Market Segmentation of Nanomedicine market

Market by Application

Market by Type

Inquire Or Share Your Questions If Any Before The Purchasing This Report https://www.absolutereports.com/enquiry/pre-order-enquiry/15462802

By Region

Key Topic Covered in Nanomedicine Market Report

Answered to the Frequently Asked Questions

WHAT IS THE SCOPE OF THE REPORT?

This market study covers the global and regional market with an in-depth analysis of the overall growth prospects in the market. Furthermore, it sheds light on the comprehensive competitive landscape of the global market. The report further offers a dashboard overview of leading companies encompassing their successful marketing strategies, market contribution, recent developments in both historic and present contexts.

WHAT ARE THE KEY SEGMENTS IN THE MARKET?

WHICH MARKET DYNAMICS AFFECTS THE BUSINESS?

The report provides a detailed evaluation of the market by highlighting information on different aspects which include drivers, restraints, opportunities, and threats. This information can help stakeholders to make appropriate decisions before investing.

Purchase This Report (Price 4500 USD for single user license) https://www.absolutereports.com/purchase/15462802

Detailed Table of Content of Global Nanomedicine Market 2020-2025

Table of ContentsPart 1 Market Overview1.1 Market Definition1.2 Market Development1.3 By TypeTable Type of NanomedicineFigure Global Nanomedicine Market Share by Type in 20201.4 By ApplicationTable Application of NanomedicineFigure Global Nanomedicine Market Share by Application in 20201.5 Region OverviewTable Region of NanomedicineFigure Global Nanomedicine Market Share by Region in 2020Part 2 Global Market Status and Future Forecast2.1 Global Market by RegionTable Global Nanomedicine Market by Region, 2015-2019 (Million USD)Figure Global Nanomedicine Market Share by Region in 2020 (Million USD)Table Price List by Region, 2015-20192.2 Global Market by CompanyTable Global Nanomedicine Market by Company, 2015-2019 (Million USD)Figure Global Nanomedicine Market Share by Company in 2020 (Million USD)Table Price List by Company, 2015-20192.3 Global Market by TypeTable Global Nanomedicine Market by Type, 2015-2019 (Million USD)Figure Global Nanomedicine Market Share by Type in 2020 (Million USD)Table Price List by Type, 2015-20192.4 Global Market by ApplicationTable Global Nanomedicine Market by Application, 2015-2019 (Million USD)Figure Global Nanomedicine Market Share by Application in 2020 (Million USD)Table Price List by Application, 2015-20192.5 Global Market by ForecastFigure Global Nanomedicine Market Forecast, 2020-2024 (Million USD)Part 3 Asia-Pacific Market Status and Future Forecast3.1 Asia-Pacific Market by CompanyTable Asia-Pacific Nanomedicine Market by Company, 2015-2019 (Million USD)Figure Asia-Pacific Nanomedicine Market Share by Company in 2020 (Million USD)Table Price List by Company, 2015-20193.2 Asia-Pacific Market by TypeTable Asia-Pacific Nanomedicine Market by Type, 2015-2019 (Million USD)Figure Asia-Pacific Nanomedicine Market Share by Type in 2020 (Million USD)Table Price List by Type, 2015-20193.3 Asia-Pacific Market by ApplicationTable Asia-Pacific Nanomedicine Market by Application, 2015-2019 (Million USD)Figure Asia-Pacific Nanomedicine Market Share by Application in 2020 (Million USD)Table Price List by Application, 2015-2019

.And Many more.

For Detail TOC Click Here

Contact Info:

Name: Ajay More

Email: [emailprotected]

Organization: Absolute Reports

Phone: +14242530807/+44203239 8187

Our Other report :Motion Tracker Market Potential Growth, Share, Demand and Analysis of Key Players- Research Forecasts to 2026

Global Underwater Exploration Robots Market 2024: Size, Key Companies, Trends, Growth and Regional Forecasts Research

Osteotomy Plates Market 2020 Capacity Production Overview, Market Share Analysis, Demand Overview, Import Export Consumption

COVID-19 Outbreak- Global Bacterial Diagnostics in Aquaculture Market 2020 Key Players, Industry Overview, Supply Chain and Analysis to 2025

Global Permanent Magnetic Material Market Growth Factors, Product Types and Application by Regions Analysis & Forecast by 2026

Worldwide Phthalate Plasticizers Market Outlook to 2025: Emerging Trends and Will Generate New Growth Opportunities Status

Global Benazepril Market 2021: Overview, Manufacturing Cost Structure Analysis, Growth Opportunities Forecaste 2025

Global Tire Release Agents Market Outlook 2025: Top Companies, Trends and Future Prospects Details for Business Development

Global Cosmetic Nonsurgical Surgery and Procedure Market 2021: Boosting the growth Worldwide: Market dynamics and trends, efficiencies Forecast 2025

Global Radiation Cure Coatings Sales Market 2021: Market Growth, Trends, Revenue, Share and Demands Research Report|Coronavirus Impact

Global Recombinant Protein Vaccine Market 2020: Market Size, Share, Growth, Sales and Drivers Analysis Research Report 2024 with

Global Field-Mount Temperature Transmitters Sales Market 2026: Size, Key Companies, Trends, Growth and Regional Forecasts Research|Coronavirus Impact

Global High Performance Biomaterials Sales Market 2021: Industry Size, Outlook, Share, Demand, Manufacturers and 2026 Forecast Researchs|Coronavirus Impact

https://murphyshockeylaw.net/

Follow this link:
Nanomedicine Market Analysis and Forecast to 2025 by Recent Trends, Developments in Manufacturing Technology and Regional Growth Overview Murphy's...

IMAGE:Representative maximum-intensity projection PET images of a healthy human volunteer injected with 64Cu-NOTA-EB-RGD at 1, 8, and 24 hours after injection. Axial MRI and PET slices of glioblastoma patient injectedview more

Credit: Jingjing Zhang et al., Peking Union Medical College Hospital, Beijing, China/Xiaoyuan Chen et al., Laboratory of Molecular Imaging and Nanomedicine, NIBIB/NIH, Bethesda, USA

A first-in-human study presented at the Society of Nuclear Medicine and Molecular Imaging 2020 Annual Meeting has demonstrated the safety, favorable pharmacokinetic and dosimetry profile of 64Cu-EBRGD, a new, relatively long-lived PET tracer, in patients with glioblastomas. The radiotracer proved to be a superior, high-contrast imaging diagnostic in patients, visualizing tumors that express low or moderate levels of v3 integrin with high sensitivity.

Glioblastoma is the most common and most aggressive primary malignant brain tumor in adults, with 17,000 diagnoses annually. It is a highly diffuse and invasive disease that is personally devastating and virtually incurable. Once diagnosed, most patients survive less than 15 months, and fewer than five percent survive five years.

The 64Cu-EBRGD radiotracer presented in this study has several unique qualities. The peptide sequence Arg-Gly-Asp (RGD) specifically targets the cell surface receptor v3 integrin, which is overexpressed in glioblastomas. To slow clearance, Evans Blue (EB) dye, which reversibly binds to circulating albumin, is bound to RGD, significantly enhancing target accumulation and retention. The addition of the 64Cu label to EBRGD provides persistent, high-contrast diagnostic images in glioblastoma patients.

This first-in-human, first-in-class study included three healthy volunteers who underwent whole-body 64Cu-EBRGD PET/CT. Safety dataincluding vital signs, physical examination, electrocardiography, laboratory parameters and adverse eventswere collected after one day and after one week. Regions of interest were drawn, time-activity curves were obtained and dosimetry was calculated. Two patients with recurrent glioblastoma also underwent 64Cu-EBRGD PET/CT. Seven sets of brain PET and PET/CT scans were obtained over two consecutive days. Tumor-to-background ratios were calculated for the target tumor lesion and normal brain tissue. One week after radiotracer administration, the patient underwent surgical treatment, and immunohistochemical staining of tumor samples was performed.

64Cu-EBRGD was well-tolerated in patients with no adverse symptoms immediately or up to one week after administration. The mean effective dose of 64Cu-EBRGD was very similar to the effective dose of an 18F-FDG scan. Injection of 64Cu-EBRGD to the patients with recurrent glioblastoma showed high accumulation at the tumor with continuously increased tumor-to-background contrast over time. Post-operative pathology revealed World Health Organization grade IV glioblastoma, and immunohistochemical staining showed moderate expression of the v3 integrin.

In this study, we have demonstrated a potential radiotheranostic agent that is safe, sensitive and highly selective in humans, which infers a future diagnostic tool and breakthrough targeted radiotherapy for glioblastoma patients, said Jingjing Zhang, MD, PhD, of Peking Union Medical College Hospital, Beijing, China. We believe this innovative use of 64Cu-EBRGD will significantly improve therapeutic efficacy and patient outcomes.

64Cu-labeled EBRGD represents a viable model compound for therapeutic applications since 177Lu, 90Y or 225Ac can be substituted for 64Cu, said Deling Li, MD, of Beijing Tiantan Hospital, Capital Medical University, Beijing, China. We are currently studying the 177Lu homolog to treat glioblastoma and other v3 integrin expressing cancers, including non-small cell lung, melanoma, renal and bone, and hope to build on the current wave of radiotherapies like 177Lu-DOTATATE.

###

Abstract 349. First-in-Human Study of a 64Cu-Labeled Long-acting Integrin v3 Targeting Molecule 64Cu-NOTA-EB-RGD in Healthy Volunteers and GBM Patients, Jingjing Zhang, Department of Nuclear Medicine, Peking Union Medical College Hospital, Chinese Academy of Medical Sciences, Beijing, China, and THERANOSTICS Center for Radiomolecular Precision Oncology, ENETS Center of Excellence, Zentralklinik Bad Berka, Bad Berka, Germany; Deling Li, Department of Neurosurgery Beijing, Tiantan Hospital, Beijing City, China; Gang Nu, National Institute of Biomedical Imaging and Bioengineering (NIBIB), National Institutes of Health (NIH), Bethesda, Maryland; Richard Baum, THERANOSTICS Center for Radiomolecular Precision Oncology, ENETS Center of Excellence, Zentralklinik Bad Berka, Bad Berka, Germany; Zhaohui Zhu, Department of Nuclear Medicine, Peking Union Medic, Beijing, China; and Xiaoyuan Chen, NIBIB/NIH, Bethesda, Maryland. SNMMIs 67th Annual Meeting, July 11-14, 2020.

Molecular Targeting Technologies, Inc., received an exclusive worldwide commercialization license from NIH for rights that, in part, cover EBRGD radiotherapeutics using various radionuclides. Glioblastoma treatment is among its potential uses.

All 2020 SNMMI Annual Meeting abstracts can be found online at http://jnm.snmjournals.org/content/61/supplement_1.toc.

About the Society of Nuclear Medicine and Molecular Imaging

The Society of Nuclear Medicine and Molecular Imaging (SNMMI) is an international scientific and medical organization dedicated to advancing nuclear medicine and molecular imaging, vital elements of precision medicine that allow diagnosis and treatment to be tailored to individual patients in order to achieve the best possible outcomes.

SNMMIs members set the standard for molecular imaging and nuclear medicine practice by creating guidelines, sharing information through journals and meetings and leading advocacy on key issues that affect molecular imaging and therapy research and practice. For more information, visit http://www.snmmi.org.

Read the original here:
Report: New PET radiotracer proven safe and effective in imaging malignant brain tumors - Tdnews

The potential of Nanomedicine: why is small different?

Nanomedicine is the application of nanotechnology to achieve innovation in healthcare. It uses the properties developed by a material at its nanometric scale 10-9 m which often differ in terms of physics, chemistry or biology from the same material at a bigger scale.

Moreover, the nanometric size is also the scale of many biological mechanisms in the human body allowing nanoparticles and nanomaterials to potentially cross natural barriers to access new sites of delivery and to interact with DNA or small proteins at different levels, in blood or within organs, tissues or cells.

At the nano-scale, the surface-to-volume ratio is such that the surface properties are becoming an intrinsic parameter of the potential actions of a particle or material. Coating of the particles and functionalization of their surfaces (even on multiple levels) are in this way extremely common to increase the biocompatibility of the particle and its circulation time in the blood, as well as to ensure a highly selective binding to the desired target.

Nanomedicine has the potential to enable early detection and prevention and to drastically improve diagnosis, treatment and follow-up of many diseases including cancer but not only. Overall, Nanomedicine has nowadays hundreds of products under clinical trials, covering all major diseases including cardiovascular, neurodegenerative, musculoskeletal and inflammatory. Enabling technologies in all healthcare areas, Nanomedicine is already accounting for approximatively 80 marketed products, ranging from nano-delivery and pharmaceutical to medical imaging, diagnostics and biomaterials.

Visit link:
What is nanomedicine? | ETPN

Inigo Charola, CEO EthicaMeat

Ethicameat is the cultivated meat brand of Biotech Foods, a pioneering Spanish company that says it is driving a revolution in the global food market; natural slaughter-free animal meat. Ethicameat says it is addressing the high demand for animal-based protein and reducing the current impact of the production process on the environment through sustainable solutions.

We were pleased to speak with Iigo Charola, CEO of Biotech Foods about their brand EthicaMeat, the future of protein and the role in which cultured meat will play.

Who is the team behind Ethica Meat?The company comprises a diverse team of experts in biomedicine, specialising in tissue regeneration and nanomedicine, which covers process engineering and pharmacology and biotechnology, in combination with a deep understanding of the food market.

Mercedes Vila is our Co-Founder and CTO of Ethicameat. She has a PhD in Materials Physics from the Autonoma University of Madrid-CSIC, and more than 16 years of experience in the design and application of materials in biomedicine and the understanding of surface interactions between cells and materials. In 2010 she was awarded the LORAL-UNESCO For Women in Science Prize in recognition of her scientific career. In 2012 she was appointed Distinguished Researcher through the I3 Programme of the Spanish Ministry of Science and Technology and she has been awarded three times the Marie-Sklodowska Curie Action of the European Commission.

Since the beginning of her career Vila has worked on the possibilities offered by tissue engineering and nanomedicine in the field of regeneration and treatment of the human body. In 2017 Vila cofounded BioTech Foods, the company that produces Ethicameat, the cultivated meat brand of Biotech Foods.

Iigo Charola is CEO and Co-Founder of BioTech Foods. He has a degree in Business Administration from the University of Wales, a Masters in Marketing Management from the prestigious ESIC Business & Marketing School and an MBA from the University of Deusto, as well as numerous leadership programs in Business Administration. He has developed his career as business director in several industries, including food technology, for more than 20 years.

Why cultured meat, and why now?Factory farming meat production model is developed on an unsustainable scale for a depleted planet. Today, factory farming accounts for 25% of the land and water use on the planet and 15% of greenhouse gas emissions. Sustained development of this model is threatening the existing and long-term capacity of the Earths resources. We are therefore facing the challenge of an unsustainable model in the long-term.

Global demand for protein currently stands at 202 million tonnes a year. This includes all types of meat and fish. This demand is forecast to increase to 1000 million tonnes by 2050, according to the latest data from the Food and Agriculture Organization (FAO) of the United Nations. This means that it is essential to find a sustainable alternative that, combining the most advanced technology with environmental protection, meets future demand.

Cultivated meat production uses much fewer resources: 99% less land, 75% less water and 90% fewer greenhouse gas emissions than similar meat products.

What is your company mission and how do you hope to achieve it?The mission of BioTech Foods is to commit to the construction of a world in which anyone who wants to eat meat can do so without killing an animal. A world where animal welfare, food safety and innovation would be the values that drive our species out to a more sustainable planet.

What will your portfolio be and when will the products be available?BioTech Foods works on pork meat and have plans to expand to poultry after that. We are currently developing our product offering for the consumer. Biotech Foods is collaborating with meat processing companies to obtain the final format of Ethicameat products, that will be launched in a range of consumer products such as sausages, ham and nuggets. The selected species give us a huge variety of potential products. Ethicameat is currently in the production scaling and regulation stage, before starting with the commercialization.

Where will your products be on sale, in which markets?Biotech Foods is collaborating with meat processing companies to obtain the final format of Ethicameat products that will be launched initially in the EU and in the US after first market introduction.

Are you seeking partners? We are very proud of the fact that our company already has raised over 2.5 million euros and our plan is to reach our short-term goals. We think collaboration is key to bring this new products into the market, so we keep collaborations in all parts of the value chain and we expect to keep growing those collaborations.

What are your plans for 2020 and the next few years?We now have the technology developed and we are now in the scale up process to bring cultivated meat to industrial production.

In the long term, we want to become a consumer alternative to traditional meat, a means to a much more important goal: sustainability between meat consumption, respect for animal welfare and the environment.

How do you foresee the future of the meat industry and which part will cultivated meat play? Are people ready for it in 2020? There are different forecasts about how protein consumption is going to evolve. What all of them have in common is that they predict a decrease of consumption of factory farming meat and plant bases and cultivated meat to be a substantial part of the proteins we consume. Some reports estimate this trend will keep rising to 2040, when cultivated meat will have a 35% share of all protein consumption.

Both production methods will undoubtedly co-exist because the consumer will demand it, but there seems to be no doubt that the overall production model will benefit.

Related

Here is the original post:
EthicaMeat: Committed to Constructing a "World in Which Anyone Who Wants to Eat Meat Can do so Without Killing an Animal" - vegconomist -...

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.

For Better Understanding, Download Sample PDF Copy of Nanomedicine Market Research Report @ https://www.marketresearchintellect.com/download-sample/?rid=201321&utm_source=LHN&utm_medium=888

**Our SAMPLE COPY of the report gives a brief introduction of the Nanomedicine market, Detailed TOC, key players of the market, list of tables and figures and comprising key countries regions.**

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.

To get Incredible Discounts on this Premium Report, Click Here @ https://www.marketresearchintellect.com/ask-for-discount/?rid=201321&utm_source=LHN&utm_medium=888

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.)

Some Notable Report Offerings:

-> 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.

Have Any Query? Ask Our Expert@ https://www.marketresearchintellect.com/need-customization/?rid=201321&utm_source=LHN&utm_medium=888

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.

About Us:

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

Contact Us:

Mr. Steven Fernandes

Market Research Intellect

New Jersey ( USA )

Tel: +1-650-781-4080

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

Our Trending Reports

Commercial Greenhouse Market Size, Growth Analysis, Opportunities, Business Outlook and Forecast to 2026

Deep Learning Market Size, Growth Analysis, Opportunities, Business Outlook and Forecast to 2026

Digital Out Of Home Market Size, Growth Analysis, Opportunities, Business Outlook and Forecast to 2026

See original here:
Nanomedicine Market Overview, Top Companies, Region, Application and Global Forecast by 2026 - Latest Herald

Short Name: Nanomed Meeting 2017

Theme: Challenges and Innovations in next generation medicine

Website: http://www.meetingsint.com/pharma-conferences/nanomedicine-nanotechnology

Registration Link: http://www.meetingsint.com/pharma-conferences/nanomedicine-nanotechnology/registration

Nanomed Meeting 2017 Organizing Committee invites you to attend the largest assemblage of Nanomedicine and Nanotechnology researchers from around the globe during November 23-24, 2017 at Dubai, UAE.

Nanomed Meeting 2017 is a global annual event. This International Conference and Exhibition on Nanomedicine and Nanotechnology brings together scientists, researchers, business development managers, CEOs, directors, IP Attorneys, Regulatory Officials and CROs from around the world. The passage of Nanomed Meeting 2017 through a decade at Asia finds much requirement for discussion also focusing the latest developments in the field of Nanomedicine and Nanotechnology.

Why attend?

Join your peers around the world focused on learning about Nanomedicine and Nanotechnology related advances, which is your single best opportunity to reach the largest assemblage of participants from the Nanomedicine and Nanotechnology community, conduct demonstrations, distribute information, meet with current and potential professionals, make a splash with a new research works, and receive name recognition at this 2-day event. World-renowned speakers, the most recent research, advances, and the newest updates in Nanomedicine and Nanotechnology are hallmarks of this conference.

Like what you just read? You can find similar content on the communities below.

To personalize the content you see on Technology Networks homepage, Log In or Subscribe for Free

Read more:
International Conference and Exhibition on Nanomedicine and Nanotechnology - Technology Networks

Researchers at the University of Calgary say their work in the field of "nanomedicine"could lead to cures for Type 1 diabetes, multiple sclerosis and many more diseases.

Dr. Pere Santamaria said the process involves "nanoparticles" thousands of times smaller than a typicalhuman cell that could be used to stop the body from attacking itself.

That, he said, could potentially lead to cures for autoimmunedisorders.

"There are no drugs that can do that today,"said Santamaria, aprofessor ofimmunology at the University of Calgary.

"Other drugs that are being used to treat chronic inflammatory disorders impair the ability of the immune system to do its job, so there are secondary effects and longterm complications our drugs don't do that."

Pharmaceutical company Novartis has partnered with Santamaria's own company, Parvus Therapeutics, to work on developing the nanomedicines and take the drugs to market.

Now with support and funding, Santamariasaid the new drug"has the potential to revolutionizemedicine" if the drugs pass clinical testing.

Santamariasaid autoimmune disordersarecaused by white blood cells attacking the tissues in a person'sown body.

Pharmaceutical company Novartis has partnered with Dr. Santamaria's Parvus Therapeutics to work on developing nanomedicines to cure autoimmune disorders and take the drugs to market. (CBC)

Type 1 diabetesis treatable with insulin, but there is no cure. It's the same for many other diseases.

"Our drugs aim to resolve the inflammation of the tissue, the attack of the tissue, and resolve that process altogether," Santamaria said.

He said the nanoparticles could halt disorders without impairing the rest of the immune system.

"So we can reset the immune system to its steady state that means the healthy state without impairing the ability of our immune system to protect us against infections and cancer,"Santamariasaid.

Santamaria said the nanoparticleswere discovered during an experiment years ago, and the initialtestresults"made nosensewhatsoever." Since that day, the nanomedicines havebeen in development and he credits the progress to curiosity.

"We almost shoved them under the rug," Santamaria said."We didn't do that. Fortunately, we were pursued wth curiosity of researching."

Santamaria said the process of taking a discovery from the research laboratory to the marketplace is enormously complex and the drug has yet to go through preclinical trials.

Because nanomedicine is such a new field of research, there is no firm timeline on when the medicinescould be available if they pass human trials.

"Our nanomedicineis a new class of drug ... so we're basically blazing the trail," Santamaria said.

"We hope that we can carry that torch and be an example for all the investigators that might follow suit, that may run into discoveries such as the ones that we've made and hopefully they can follow in our footsteps."

View original post here:
'Blazing the trail': University of Calgary research could lead to cures for autoimmune diseases - CBC.ca

JavaScript is disabled on your browser. Please enable JavaScript to use all the features on this page.Abstract

Successfully translating anti-cancer nanomedicines from pre-clinical proof of concept to demonstration of therapeutic value in the clinic is challenging. Having made significant advances with drug delivery technologies, we must learn from other areas of oncology drug development, where patient stratification and target-driven design have improved patient outcomes. We should evolve our nanomedicine development strategies to build the patient and disease into the line of sight from the outset. The success of small molecule targeted therapies has been significantly improved by employing a specific decision-making framework, such as AstraZeneca's 5R principle: right target/efficacy, right tissue/exposure, right safety, right patient, and right commercial potential. With appropriate investment and collaboration to generate a platform of evidence supporting the end clinical application, a similar framework can be established for enhancing nanomedicine translation and performance. Building informative data packages to answer these questions requires the following: (I) an improved understanding of the heterogeneity of clinical cancers and of the biological factors influencing the behaviour of nanomedicines in patient tumours; (II) a transition from formulation-driven research to disease-driven development; (III) the implementation of more relevant animal models and testing protocols; and (IV) the pre-selection of the patients most likely to respond to nanomedicine therapies. These challenges must be overcome to improve (the cost-effectiveness of) nanomedicine development and translation, and they are key to establishing superior therapies for patients.

Nanomedicine

EPR effect

Clinical translation

Pre-clinical models

Industry

Companion diagnostics

Patient pre-selection

Recommended articlesCiting articles (0)

2016 The Author(s). Published by Elsevier B.V.

Go here to see the original:
Challenges and strategies in anti-cancer nanomedicine ...

Targeted Nanomedicine Treats Advanced-stage Ovarian Cancer
Rutgers University scientists have utilized a targeted nanomedicine approach to deliver small molecule medicationss and successfully treat mice with deadly a...

By: EmpoweredDoctor

See more here:
Targeted Nanomedicine Treats Advanced-stage Ovarian Cancer - Video

Ethical, Legal, Social and Economic Aspects of Nanomedicine
Lecture of Dr. Klaus-Michael Weltring, Chair of WG Eyhics in ETPN. The lecture was performed at the Training Workshop on Ethical Issues in Nanomedicine, the ...

By: Michael Beigel

See the original post here:
Ethical, Legal, Social and Economic Aspects of Nanomedicine - Video

Share

Share

Email

Nanomedicine and drug delivery systems are at the forefront of modern healthcare. These systems offer a new platform for drug delivery that can greatly increase the targeting and effectiveness of therapy.

Over the last twenty years, great strides have been made in cancer nanomedicine and tissue repair using targeted drug delivery systems. In this field, the goal is to take advantage of the unique properties of a material on the nanoscale to minimize toxicity in healthy organs by specifically targeting cancerous cells. Our research group has sought to develop safer and more efficacious therapies in order to advance patient care and clinical outcomes.

Concerning nanomedicine, the focus of our research has been to improve the treatment of different types of cancer, among them lymphoma and glioma. We have developed polymeric and lipid nanoparticles loaded with different antitumor agents, such as edelfosine, which presents the singular characteristic of not targeting the cells DNA but the cell membrane and the apoptotic machinery of the cancer cell. These nanosystems were able to cross the blood-brain barrier, and furthermore, in the case of lymphoma models, they were found to successfully inhibit not only the primary tumor, but also its spread to other parts of the body when administered orally.

More recently, our attention has been centered on the use of nanotechnology for the treatment of pediatric cancers, particularly osteosarcoma, which is the most frequently observed primary malignant bone tumor in the pediatric population. We have shown that our nanomedicines decreased the toxicity of the entrapped edelfosine, and that this treatment slowed the progression of the primary tumor growth in orthotopic osteosarocoma animal models, successfully preventing the metastatic spread of the osteosarcoma cells from the primary tumor to the lungs these findings were significant as it is assumed that 80% of patients with osteosarcoma present non-detectable micrometastases at diagnosis. The nanomedicines we have developed, and more specifically lipid based nanosystems entrapping edelfosine, could provide a more effective and safer alternative to conventional treatments for different types of cancers.

Regenerative medicine has also been of great interest to us. It is an interdisciplinary field that promotes regeneration of tissue or organs damaged by disease, which contrasts with traditional strategies that focus primarily on treating symptoms. In this sense, our focus has been the development of novel drug delivery systems to provide better treatment for brain and cardiac diseases. A large number of the projects carried out by our group have been done in collaboration with clinicians, pharmaceutical scientists, material engineers, and veterinarians, leading to novel delivery systems in key areas of unmet medical needs such as Parkinsons disease and myocardial infarction.

Specifically, our biomaterials can solve one of the greatest issues associated with biotherapeutic formulation and delivery, which is their fast degradation. In order to overcome this challenge, we have designed various microparticle-based technologies which we are able to protect biomolecules from degradation in biological environments. Our technique avoids shear stress and preserves the proteins from degradation during the manufacture process.

We have demonstrated that the injection of microparticles loaded with glial cell line-derived neurotrophic factor (GDNF) one of the most promising candidates for the treatment of Parkinsons disease within the brain of animals with severe nigrostriatal degeneration achieved long-term improvement in motor function, which was associated with the restoration of the dopaminergic function.

Similar to the positive results observed in the treatment of Parkinsons disease, we also observed improved cardiac recovery after myocardial infarction after treatment with neuregulin or fibroblast growth factor loaded microparticles. Interestingly, these microparticles modulated the inflammatory process towards a reparative response. However, we are only starting to obtain a glimpse into the crucial role of the inflammatory response for tissue repair. More studies addressing the contribution of different macrophage subsets to the reparative process are mandatory to fully understand the therapeutic potential of modulating the inflammatory response, as therapeutic treatment not only for myocardial infarction, but also for several other diseases, including cancer.

Beyond assessing the efficacy of microencapsulated biotherapeutics, microparticle optimization has also been a regular topic of discussion in the research group. The hydrophilic polymer coating, poly (ethylene glycol) (PEG), is well-known to increase the half-life of biotherapeutics and to reduce particle clearance in the blood, but the same strategy has not proven effective in reducing particle elimination in the heart. PEG decreases particle clearance in the blood by blocking opsonins, macromolecules that bind particles and mark them to be eliminated by phagocytes. However, in the cardiac tissue, particle clearance may not be dependent on opsonins which would explain why PEG failed to improve microparticle bioavailability in the heart.

Mirco- and nanoparticle-based drug delivery systems combined with cell therapy can achieve a more complete and potent regenerative response. Indeed, biomimetic biomaterials with tunable properties can be tailored to influence the fate of transplanted cells and to improve current cell delivery strategies. Within this framework, the use of microparticles as delivery vehicles for stem cells and human cardiomyocytes has proven to maximize the efficacy of cell therapy by dramatically enhancing cell survival in the heart. Cutting-edge areas such as non-invasive intravenous delivery of cardioprotective nanomedicines or extracellular vesicle-based therapies are also currently being explored.

Despite increased efforts made to improve current strategies in the above mentioned diseases, there are still aspects that limit the transfer of drug delivery systems to clinical practice, including the standardization of criteria and validated methods to characterize these novel systems of drug administration, large scale-manufacturing, the use of animal models that better simulate the pathophysiological aspects of the diseases and government regulations. An additional issue that could influence their clinical translation is the overall cost-effectiveness in comparison to current therapies.

In any case it is clear that the advances achieved in nanomedicine and drug delivery technologies offer huge potential for novel therapeutic approaches to unmet medical needs such as cancer, as well as cardiovascular and neurodegenerative diseases.

Written by: Mara Blanco-Prieto [1]

[1] Department of Pharmacy and Pharmaceutical Technology, Universidad de Navarra

Reference: Elisa Garbayo, et al. Nanomedicine and drug delivery systems in cancer and regenerative medicine. WIREs Nanomedicine and Nanobiotechnology (2020). DOI: 10.1002/wnan.1637

Read the original:
Nanomedicine and drug delivery systems: The cutting edge of modern healthcare - Advanced Science News

Nanomedicine Presentation

By: Radiological Technologies University (RTU)

See the original post:
Nanomedicine Presentation - Video

This summer, the Koch Institute for Integrative Cancer Research at MIT marks the first anniversary of the launch of the Marble Center for Cancer Nanomedicine, established through a generous gift from Kathy and Curt Marble 63.

Bringing together leading Koch Institute faculty members and their teams, the Marble Center for Cancer Nanomedicine focuses on grand challenges in cancer detection, treatment, and monitoring that can benefit from the emerging biology and physics of the nanoscale.

These challenges include detecting cancer earlier than existing methods allow, harnessing the immune system to fight cancer even as it evolves, using therapeutic insights from cancer biology to design therapies for previously undruggable targets, combining existing drugs for synergistic action, and creating tools for more accurate diagnosis and better surgical intervention.

Koch Institute member Sangeeta N. Bhatia, the John J. and Dorothy Wilson Professor of Health Sciences and Technology and Electrical Engineering and Computer Science, serves as the inaugural director for the center.

A major goal for research at the Marble Center is to leverage the collaborative culture at the Koch Institute to use nanotechnology to improve cancer diagnosis and care in patients around the world, Bhatia says.

Transforming nanomedicine

The Marble Center joins MITs broader efforts at the forefront of discovery and innovation to solve the urgent global challenge that is cancer. The concept of convergence the blending of the life and physical sciences with engineering is a hallmark of MIT, the founding principle of the Koch Institute, and at the heart of the Marble Centers mission.

The center galvanizes the MIT cancer research community in efforts to use nanomedicine as a translational platform for cancer care, says Tyler Jacks, director of the Koch Institute and a David H. Koch Professor of Biology. Its transformative by applying these emerging technologies to push the boundaries of cancer detection, treatment, and monitoring and translational by promoting their development and application in the clinic.

The centers faculty six prominent MIT professors and Koch Institute members are committed to fighting cancer with nanomedicine through research, education, and collaboration. They are:

Sangeeta Bhatia (director), the John J. and Dorothy Wilson Professor of Health Sciences and Technology and Electrical Engineering and Computer Science;

Daniel G. Anderson, the Samuel A. Goldblith Professor of Applied Biology in the Department of Chemical Engineering and the Institute for Medical Engineering and Science;

Angela M. Belcher, the James Mason Crafts Professor in the departments of Biological Engineering and Materials Science and Engineering;

Paula T. Hammond, the David H. Koch Professor of Engineering and head of the Department of Chemical Engineering;

Darrell J. Irvine, professor in the departments of Biological Engineering and Materials Science and Engineering; and

Robert S. Langer, the David H. Koch Institute Professor.

Extending their collaboration within the walls of the Institute, Marble Center members benefit greatly from the support of the Peterson (1957) Nanotechnology Materials Core Facility in the Koch Institutes Robert A. Swanson (1969) Biotechnology Center. The Peterson Facilitys array of technological resources and expertise is unmatched in the United States, and gives members of the center, and of the Koch Institute, a distinct advantage in the development and application of nanoscale materials and technologies.

Looking ahead

The Marble Center has wasted no time getting up to speed in its first year, and has provided support for innovative research projects including theranostic nanoparticles that can both detect and treat cancers, real-time imaging of interactions between cancer and immune cells to better understand response to cancer immunotherapies, and delivery technologies for several powerful RNA-based therapeutics able to engage specific cancer targets with precision.

As part of its efforts to help foster a multifaceted science and engineering research force, the center has provided fellowship support for trainees as well as valuable opportunities for mentorship, scientific exchange, and professional development.

Promotingbroader engagement, the Marble Center serves as a bridge to a wide network of nanomedicine resources, connecting its members to MIT.nano, other nanotechnology researchers, and clinical collaborators across Boston and beyond. The center has also convened a scientific advisory board, whose members hail from leading academic and clinical centers around the country, and will help shape the centers future programs and continued expansion.

As the Marble Center begins another year of collaborations and innovation, there is a new milestone in sight for 2018.Nanomedicine has been selected as the central theme for the Koch Institutes 17th Annual Cancer Research Symposium. Scheduled for June 15, 2018, the event will bring together national leaders in the field, providing an ideal forum for Marble Center members to share the discoveries and advancements made during its sophomore year.

Having next years KI Annual Symposium dedicated to nanomedicine will be a wonderful way to further expose the cancer research community to the power of doing science at the nanoscale, Bhatia says. The interdisciplinary approach has the power to accelerate new ideas at this exciting interface of nanotechnology and medicine.

To learn more about the people and projects of the Koch Institute Marble Center for Cancer Nanomedicine, visit nanomedicine.mit.edu.

See the original post here:
Converging on cancer at the nanoscale - The MIT Tech

Written by AZoNanoJul 10 2017

The Koch Institute for Integrative Cancer Research at MIT will soon be reaching the first anniversary of the launch of the Marble Center for Cancer Nanomedicine, founded through a generous gift from Kathy and Curt Marble 63.

The Marble Center for Cancer Nanomedicines faculty is made up of Koch Institute members who are committed to fighting cancer with nanomedicine through research, education, and collaboration. Top row (l-r) Sangeeta Bhatia, director; Daniel Anderson; and Angela Belcher. Bottom row: Paula Hammond; Darrell Irvine; and Robert Langer. (Photo: Koch Institute Marble Center for Cancer Nanomedicine)

Bringing together leading Koch Institute faculty members and their teams, the Marble Center for Cancer Nanomedicine focuses on huge challenges in cancer detection, treatment and monitoring that can profit from the latest physics and biology of the nanoscale.

These challenges include spotting cancer earlier than present techniques allow, harnessing the immune system to combat cancer even as it progresses, using therapeutic insights from cancer biology to design therapies for formerly undruggable targets, integrating current drugs for synergistic action, and developing tools for more accurate diagnosis and improved surgical intervention.

Koch Institute member Sangeeta N. Bhatia, the John J. and Dorothy Wilson, Professor of Health Sciences and Technology and Electrical Engineering and Computer Science, serves as the Inaugural Director of the center.

A major goal for research at the Marble Center is to leverage the collaborative culture at the Koch Institute to use nanotechnology to improve cancer diagnosis and care in patients around the world.

Sangeeta N. Bhatia, Koch Institute Member

Transforming nanomedicine

The Marble Center joins MITs larger efforts at the forefront of discovery and advancement to solve the critical global challenge that is cancer. The concept of convergence the combination of the life and physical sciences with engineering is a trademark of MIT, the founding principle of the Koch Institute, and at the heart of the Marble Centers mission.

The center galvanizes the MIT cancer research community in efforts to use nanomedicine as a translational platform for cancer care. Its transformative by applying these emerging technologies to push the boundaries of cancer detection, treatment, and monitoring and translational by promoting their development and application in the clinic.

Tyler Jacks, Director of the Koch Institute and a David H. Koch Professor of Biology

The centers faculty six renowned MIT Professors and Koch Institute Members are committed to combating cancer with nanomedicine through research, education and partnership. They are, Sangeeta Bhatia (director), the John J. and Dorothy Wilson Professor of Health Sciences and Technology and Electrical Engineering and Computer Science; Daniel G. Anderson, the Samuel A. Goldblith Professor of Applied Biology in the Department of Chemical Engineering and the Institute for Medical Engineering and Science; Angela M. Belcher, the James Mason Crafts Professor in the departments of Biological Engineering and Materials Science and Engineering; Paula T. Hammond, the David H. Koch Professor of Engineering and head of the Department of Chemical Engineering; Darrell J. Irvine, Professor in the departments of Biological Engineering and Materials Science and Engineering; and Robert S. Langer, the David H. Koch Institute Professor.

Extending their partnership within the walls of the Institute, members of the Marble Center profit greatly from the support of the Peterson (1957) Nanotechnology Materials Core Facility in the Koch Institutes Robert A. Swanson (1969) Biotechnology Center. The Peterson Facilitys array of technological resources and know-how is unparalleled in the United States, and gives members of the center and of the Koch Institute, a distinctive advantage in the development and application of materials and technologies at the nanoscale.

Looking ahead

The Marble Center made the most of its first year, and has provided backing for advanced research projects including theranostic nanoparticles that can both detect and treat cancers, real-time imaging of interactions between cancer and immune cells to properly understand reaction to cancer immunotherapies, and delivery technologies for a number of powerful RNA-based therapeutics capable of engaging specific cancer targets with precision.

As part of its efforts to help adopt a multifaceted science and engineering research force, the center has offered fellowship support for trainees as well as valuable opportunities for scientific exchange, mentorship and professional development.

Promoting wider engagement, the Marble Center serves as a bridge to a broad network of nanomedicine resources, linking its members to MIT.nano, other Nanotechnology Researchers, and Clinical Partners across Boston and beyond. The center has also set up a scientific advisory board, whose members come from leading clinical and academic centers around the country, and will assist in shaping the centers future programs and continued development.

As the Marble Center enters another year of partnerships and innovation, there is a new landmark in sight for 2018. Nanomedicine has been chosen as the main theme for the Koch Institutes 17th Annual Cancer Research Symposium. The event is scheduled for June 15th, 2018, and will bring together national domain experts, providing a perfect forum for Marble Center members to share the discoveries and progresses made during its sophomore year.

Having next years KI Annual Symposium dedicated to nanomedicine will be a wonderful way to further expose the cancer research community to the power of doing science at the nanoscale. The interdisciplinary approach has the power to accelerate new ideas at this exciting interface of nanotechnology and medicine.

Sangeeta N. Bhatia, Koch Institute Member

Read the original here:
Koch Institute's Marble Center for Cancer Nanomedicine Brings Together Renowned Faculty to Combat Cancer - AZoNano

The global Nanomedicine in Central Nervous System Injury and Repair Market size is projected to grow from USD XX million in 2020 to USD XX million by 2027, at a CAGR of XX%. Increasing awareness towards strict government regulations on emission control is an opportunity for the growth of the market. However, owing to COVID-19, the sales have declined, resulting in reduced demand.

Get sample copy of this reporthttps://www.infinitybusinessinsights.com/request_sample.php?id=472769

Historical and future availability, market share, prices, trade, competition, and value chain dynamics are among the topics covered in the study. Analysts spoke to CEOs, advertisers, brand owners, vice presidents, and sales and marketing managers during the primary study. Analysts also highlighted the changing business scenario based on evidence gathered from interviews with credible sources.

Forecast period:- 2020-2025.Base year :- 2019Estimation period :-2020-2025.

Top key players: bbott, Ablynx N.V, California Life Sciences Association, CELGENE CORPORATION, Teva Pharmaceutical Industries Limited, GENERAL ELECTRIC COMPANY, Merck Sharp & Dohme Corp (a subsidiary of Merck & Co., Inc), Pfizer Inc, Nanosphere Inc, Johnson & Johnson Private Limited and BD among other domestic and global players. Get Up to 20% Discount on this Premium Report https://www.infinitybusinessinsights.com/ask_for_discount.php?id=472769

The report offers an up-to-date analysis regarding the current global market scenario, latest trends and drivers, and the overall market environment. The market is driven by the increasing demand. This market research report provides a complete competitive landscape and an in-depth vendor selection methodology and analysis using qualitative and quantitative research to forecast an accurate market growth.

Reasons Why You Should Buy This Report:

It gives a forward-looking viewpoint on changed variables driving or controlling business sector development. It gives an eight-year conjecture surveyed based on how the market is anticipated to develop. It helps in understanding the key item sections and their future. It gives pin point investigation of changing rivalry elements and keeps you in front of contenders. It helps in settling on educated business choices by having total bits of knowledge of market and by making inside and out investigation of market sections.

The report relies upon to help the clients in the market by giving them the nearest approximations of revenue, calculative risk and value of the market and its sections. Further it is likewise expected to assist with getting an improved comprehension of the serious scene of the market, acquire bits of knowledge to advance the situation of the organizations, and make reasonable go-to-market methodologies after the pandemic is over.

Inquiry Before Buying This Report https://www.infinitybusinessinsights.com/enquiry_before_buying.php?id=472769

The report further elaborates with a SWOT analysis of the market, an investment viability analysis, and an investment return analysis and lays a strategic outlook for the pandemic.

Scope of the report:- Addressing customers issues with the product or service. Assessing requirements for introducing innovation. Surveying success rate of innovation in market, including market testing.

The report further elaborates with a SWOT analysis of the market, an investment viability analysis, and an investment return analysis and lays a strategic outlook for the pandemic.

If you need anything more than these then let us know and we will prepare the report according to your requirement.

FAQs: What is the extent of the Nanomedicine in Central Nervous System Injury and Repair Market ?

What is the yearly development of Nanomedicine in Central Nervous System Injury and Repair Market ?

What are the best regions to put resources into?

What is the COVID 19 Nanomedicine in Central Nervous System Injury and Repair Market examination?

Which are the critical makers in the Nanomedicine in Central Nervous System Injury and Repair Market ?

About Us

Infinity Business Insights is a market research company that offers market and business research intelligence all around the world. We are specialized in offering the services in various industry verticals to recognize their highest-value chance, address their most analytical challenges, and alter their work.We attain particular and niche demand of the industry while stabilize the quantum of standard with specified time and trace crucial movement at both the domestic and universal levels. The particular products and services provided by Infinity Business Insights cover vital technological, scientific and economic developments in industrial, pharmaceutical and high technology companies.

Contact Us:Amit JSales Coordinator+1-518-300-3575amit@infinitybusinessinsights.com

https://mobile.twitter.com/IBInsightsLLP

https://facebook.com/Infinity-Business-Insights-352172809160429

https://www.linkedin.com/company/infinity-business-insights/

Read the original here:
Global Nanomedicine in Central Nervous System Injury and Repair Market Research Report, Growth Trends and Competitive Analysis 2021-2027 KSU | The...

AZoNano speaks to Dr. Zahra Rattray about the impact of the new Multiscale Metrology Suite (MMS) on thedevelopment of the field of nanomedicine. Continue readingfor an insight into how this new, multidisciplinaryfacility is at the forefront of utilizing nanotechnology for pharmaceutical research.

My name is Zahra Rattray, and I am a Chancellors Research Fellow in Translational Pharmaceutics at the University of Strathclyde Institute of Pharmacy and Biomedical Sciences. What inspired me to pursue a career in nanotechnology for health was working within the drug discovery sector and seeing how many promising candidate compounds would fail at later development stages due to formulation challenges or their safety profile.

Using nanotechnology, we could salvage the therapeutic potential of these compounds and ultimately develop life-saving drugs. Since then, I have become very interested in researching the biological performance of nanotechnology drugs or developing new strategies such as targeting ligands to enable drug delivery.

My involvement started during graduate school, where I studied endogenous ligands such as transferrin with a view to harnessing their potential for drug delivery. Following this, I have been involved in pharmaceutical industry pipeline projects developing nanomedicine products; my research team studies the development of bioanalytical pipelines to analyze nanotechnologies.

The widespread use of mRNA lipid nanoparticle vaccines during the COVID-19 pandemic has demonstrated the need for the rapid deployment of nanotechnology for areas of unmet clinical need. The nanotechnology sector has an opportunity to use such momentum and lessons learned from the pandemic and apply this to other therapeutic areas such as oncology.

Image Credit:Viacheslav Lopatin/Shutterstock.com

The Multiscale Metrology Suite will enable the comprehensive physicochemical analysis of novel nanomaterials and their interactions with biomacromolecules contained within biological fluids such as blood. Areas benefiting from this work the most will be novel nanomaterials requiring a comprehensive understanding of product parameters or the impact of the manufacturing process on product characteristics.

Using a data-driven approach, their clinical and commercial translation timelines can be accelerated through deeper product understanding.

In addressing the translational obstacles to nanotechnology implementation in health, we can look to other disciplines for technological solutions or bringing a new perspective to solving existing challenges. The insights and perspectives a multidisciplinary approach delivers can provide transformative and disruptive solutions to some of the grand challenges we face.

A good example is how field flow fractionation (FFF) entered the arena in the 1960s with a limited range of researcher groups investing in this technology. It is only in the past few years that FFF implementation in the bio- and nanotechnology sectors entered a rapid growth phase.

The Multiscale Metrology Suite (MMS) facility will collaborate with academics, industry, and government bodies to ensure its strategic relevance to drug discovery. The MMS will remain world-leading and competitive through incorporating new technological advancements in the analytical and nanotechnology sectors.

Image Credit: FGC/Shutterstock.com

Some of the major obstacles nanotechnology faces is the clinical translation of these products. These obstacles can range from the unknown biological performance of new chemistries to the reproducible manufacture of nanomedicines with consistent key critical quality attributes. The more understanding we can develop about a product and process from the early development stage, the more likely the risk of late-stage pipeline attrition can be mitigated.

I believe that by using a team-based, interdisciplinary approach, we can tackle the grand challenges facing nanomedicine translation. By working across traditional discipline boundaries, we can better understand the biology being targeted, which product attributes are suitable for the biological target, and how we can control these through process design.

Image Credit:Anucha Cheechang/Shutterstock.com

The Multiscale Metrology Suite (MMS) is a unique, bespoke setup that will combine electric, centrifugal and asymmetric field-flow fractionation modes with a range of physical and chemical detectors.

Using this suite, we will be able to measure solution-phase properties of nanomaterial prototypes dispersed in their formulation vehicle or probe their interactions with biomacromolecules in blood components. This will provide information on formulation attributes and the early assessment of interactions with biological fluids. Some examples of parameters we are particularly interested in multiplexing the high-resolution analyses of size, charge, and shape factor (rg/rh) with changes occurring in the chemistry of nanoparticles using Raman analysis or inductively-coupled plasma mass spectrometry.

The MMS will also explore multiplexation with other detectors such as mass spectrometry for proteomics analysis of the nanoparticle corona proteome and high-resolution analysis of particle concentrations using nanoparticle tracking analysis (NTA).

In the era of precision medicine, the ability to fuse large clinical datasets with advanced bioanalytical tools will be transformative in nanomedicine design and selection for patients. Developing a deeper understanding of how nanomedicines interact with biological moieties enabled through advances in analytical technologies will provide the opportunity for us to reverse-engineer new prototypes for optimal safety and efficacy in areas of unmet clinical need.

We will work with our partners and collaborators to harmonize protocols and methods for the analysis of nanomedicine prototypes in an attempt to achieve consistency in the measurement and reporting of nanomedicine attributes.

https://gtr.ukri.org/projects?ref=EP%2FV028960%2F1

Dr. Zahra Rattray is a Chancellors Research Fellow in Translational Pharmaceutics at the Strathclyde Institute of Pharmacy and Biomedical Sciences in Glasgow.

Dr. Rattray is an interdisciplinary translational pharmaceutical scientist with over 10 years experience of working in the academic, industry, and clinic sectors developing a diverse molecule portfolio. Zahra received her PhD in Drug Delivery from the University of Manchester in 2013, and completed a postdoctoral research position at Manchester, developing new analytical pipelines for profiling antibody drug product stability.

Zahra has significant formulation experience from her time at AstraZeneca Pharmaceuticals as both a pre-clinical and late-stage formulation scientist. Zahra completed a postdoctoral research position at the Yale School of Medicine in partnership with Patrys Ltd where she explored cell-penetrating autoantibodies as DNA damage repair agents for the treatment of glioblastoma, and as targeting ligands for drug and gene delivery systems.

Since fall 2018, Dr Rattray has been a Chancellors Research Fellow at the University of Strathclyde. Her team explores the development of bioanalytical measurements for profiling the nanoparticle protein corona and the role of nuclear import in cancer progression.

Disclaimer: The views expressed here are those of the interviewee and do not necessarily represent the views of AZoM.com Limited (T/A) AZoNetwork, the owner and operator of this website. This disclaimer forms part of the Terms and Conditions of use of this website.

Link:
Manifesting Multidisciplinary Nanomedicine Research with the MMS - AZoNano

The existence of microbial antigens and other impurities mistakenly introduced during the development and purification of bionanopharmaceutical devices can stimulate the innate immune system, as described in a paper published in the journal Molecules.

An immediate but largely non-specific local immune reaction including both biochemical and molecular components initiates the body's first "innate" defense against foreign armies.

Trained immunity is anon-specific, T-cell self-sufficient innate immunity that relies primarily on macrophage activation and pro-inflammatory cytokine secretion for long-term functional reconfiguration of the innate immune cell response instead of the epigenetic hybridization required by innate and adaptive immunity.

Due tothe high financial and social expenses of medicine development, research, and approval, it iscritical that any prospective product "failure" is not caused by the accidental inclusion of innate immunity modulating impurities IIMIs

Activated phagocytes produce simultaneously stimulatory as well as inhibitory cytokines in the influence of IIMIs to stimulate and control the immune response.

Chemokines are the most diversified family of cytokines, with roles ranging from cell migratory regulation (e.g., recruiting and activation of local neutrophils and basophils to the infection site) through embryogenesis, innate and adaptive body's immune function and structure, and cancer metastasis.

In most cases, cytokine-driven immunostimulation is beneficial, such as when it is activated by adjuvants to boost vaccine effectiveness.

Immunological stimulation that is unanticipated or uncontrolled, particularly in the presence of therapeutic substances, causes unwanted cellular immune responses and antibody formation in reaction to the medicinal product.

Immunotoxicity is defined as "any unfavorable effect on the structure or function of the immune mechanism, or other systems influenced by the same biologic mediatorsas a result of immune response malfunction."

It is further divided into three categories based on the intensity of the response: non-specific immunostimulation, uncontrolled hypersensitivity that causes tissue injury, and immunosuppression.

Impurities in drug products trigger innate cellular responses and produce biomarkers for bioassay detection and Quantification. Currently, only -glucans and endotoxins can be detected and quantified directly using specialized assays. The remaining population of impurities must instead be detected and quantified indirectly using downstream biomarkers (e.g., proteins, peptides, and nucleic acids) and immune cell activation as hallmarks of contamination. Image Credit:Holley, C., and Dobrovolskaia, M.

When compared to classically formulated variants of such prescription medications, the use of nanotechnology is becoming a popular method for reducing drug immunotoxicity whilst also improving medicinal solubility, biodistribution, and cell-specific distribution. However, several nanocarriers have been shown to have immunomodulatory properties.

For example, RNA nanoparticles have been found to increase inflammation by inducing pro-inflammatory cytokine release. The raw materials used to make nanoplatforms can have a variety of immunological impacts, either as a result of contamination or because of the chemical features of the material.

Certain nanomaterials, including lipid-based nanocarriers and carbon nanotubes, are immunostimulatory, causing cytokine production and inflammation.

The rabbit pyrogen test (RPT) became the bioassay used to identify microbial contamination. It detects pyrogens, as well as any contaminants that causea histamine reaction, chills, fever, and other inflammation side effects.

As the rabbit pyrogen test identifies all pyrogens, it has a high level of unpredictability, is costly, and requiressignificant animal usage for tests.

As issues with beta-glucan and endotoxin identification in nanoformulations arise from excipient-, carrier-, or drug-mediated external interference, sources of interferences and techniques to overcome them have been discovered. Here, direct detection methods are often utilized.

For an efficient test, a suitable biomarkercan be any chemical with a beneficial attribute, such as a mechanical by-product, that can be measured or assessed, either direct or indirect, and utilized as an indication of anormal biological, pathological, or pharmacological condition.

Recent experimentshave placed focus on thein vitro and in vivo effects of IIMIsbecause as the long-term objective of these investigations is to prevent human immunotoxicity and probable immunogenicity.

These biological tests detect immune cell growth and proliferation or measure quantities of released innate immunity biomarkers,which may help to prime immune cells and contribute to immunogenicity.

The FDA's mandated panel of IIMIs for measurement should be broadened to include a far larger range of impurities, such as microbial antigens that may trigger additional innate immune pathways, popular manufacturing leachates and solvents, and hazardous chemicals needed to keep host cells alive.

The utilization of a single high-throughput platform designed to detect a large panel of indicators from the same class (proteins, small molecules, or nucleic acids) simultaneously, such as multiplex MS, ELISAs, or genomic arrays, should be used to standardize data across trials and laboratories. Broader nanoassortment of cytokines can be applied to make the data more complete.

Continue reading: Why Nanotoxicology Should be the First Step Towards a Nanotechnology Future.

Holley, C., and Dobrovolskaia, M. (2021). Innate Immunity Modulating Impurities and the Immunotoxicity of Nanobiotechnology-Based Drug Products. Molecules 26(23). Available at:https://www.mdpi.com/1420-3049/26/23/7308

Disclaimer: The views expressed here are those of the author expressed in their private capacity and do not necessarily represent the views of AZoM.com Limited T/A AZoNetwork the owner and operator of this website. This disclaimer forms part of the Terms and conditions of use of this website.

Read more here:
Understanding the Immune Response to Nanomedicine Pharmaceuticals - AZoNano

NOIDA, India, March 8, 2021 /PRNewswire/ -- A comprehensive overview of the Nanotechnology in Drug Delivery market is recently added by UnivDatos Market Insights to its humongous database. The Nanotechnology in Drug Delivery market report has been aggregated by collecting informative data of various dynamics such as market drivers, restraints, and opportunities. This innovative report makes use of several analyses to get a closer outlook on the Nanotechnology in Drug Delivery market. The Nanotechnology in Drug Delivery market report offers a detailed analysis of the latest industry developments and trending factors in the market that are influencing the market growth. Furthermore, this statistical market research repository examines and estimates the Nanotechnology in Drug Delivery market at the global and regional level. The Global Nanotechnology in Drug Delivery Market is expected to grow at a CAGR of 19.9% from 2021-2027 to reach USD 182.3 billion by 2027.

Market Overview

The Global Nanotechnology in Drug Delivery Market is experiencing significant growth on account of surging prevalence of cancer and other diseases. More people die from CVDs worldwide than from any other source, according to the World Health Organization with over 17.9 million per year. In 2020, American Heart Association has set a goal of reducing cardiovascular disease and stroke deaths by 20% and thus focused on enhancing factors such as physical activity, diet, obesity/overweight, smoking, blood pressure, cholesterol, and blood sugar. The rising number of deaths cause increased burden among the people, which can surge the demand for novel nanotechnology drug delivery techniques that are efficient than traditional medicine and therefore is expected to drive the general market to grow.

There has been major expansion in the transformation of nano-based cancer therapies and diagnostics and different new technologies are in the pipeline. Nanomedicine and nano delivery systems are being utilized as diagnostic tools or in delivering therapeutic agents to specific targeted sites in a controlled manner wherein materials are used in the nanoscale range. Since 1995, nearly 50 nano pharmaceuticals have received FDA approval and are currently available for clinical use. In oncology, over 20% of the therapeutic nanoparticles already in clinics or under clinical evaluation have been created. Most FDA-approved therapeutic nanoparticles are currently being designed for the re-formulation of combinations of chemotherapeutic drugs with polymeric nanoparticles.

Request Sample Copy of this Report @ https://univdatos.com/report/global-nanotechnology-in-drug-delivery-market-current-analysis-and-forecast-2020-2027

COVID-19 Impact

The current impact of COVID-19 on global health is enormous, but in addition, the worldwide impact on the economy, employees, and companies is going to be considerable. This global emergency calls for a science and technology response to the COVID-19 pandemic, where advanced solutions during the epidemic are anticipated to be explored by nanotechnology. A study performed by Leuschner et al. brings a direction in the use of nanotechnology to control the cytokine storm which is amongst few clinical complications of COVID-19. Nanoparticles perform an essential role at different stages of disease pathogenesis, contemplating their inhibition potential in the initial attachment and membrane fusion during viral entry and infected cell protein fusion.

Ask for Price & Discounts @ https://univdatos.com/report/global-nanotechnology-in-drug-delivery-market-current-analysis-and-forecast-2020-2027

Global Nanotechnology in Drug Delivery Market report is studied thoroughly with several aspects that would help stakeholders in making their decisions more curated.

By Technology, the market is primarily bifurcated into

Nanoparticles segment dominated the by type of the global nanotechnology in drug delivery market and will row at 19.4% CAGR to reach US$ 48.1 billion by the year 2027.

By Application, the market is primarily segmented into

Amongst application type, oncology accounted for the largest share and is expected to grow at 20% CAGR during the forecast period 2021-2027. In 2019, the oncology segment accounted for a revenue share of almost 36%.

Nanotechnology in Drug Delivery Market Geographical Segmentation Includes:

Based on the estimation, the North America region dominated the Nanotechnology in Drug Delivery market with almost US$ 18.9 billion revenue in 2019. At the same time, the Asia-Pacific region is expected to grow remarkably with a CAGR of 22.5% over the forecast period on account of the increasing population and modernization of healthcare infrastructure.

Ask for Report Customization @https://univdatos.com/report/global-nanotechnology-in-drug-delivery-market-current-analysis-and-forecast-2020-2027

The major players targeting the market includes

Competitive Landscape

The degree of competition among prominent global companies has been elaborated by analyzing several leading key players operating worldwide. The specialist team of research analysts sheds light on various traits such as global market competition, market share, most recent industry advancements, innovative product launches, partnerships, mergers, or acquisitions by leading companies in the nanotechnology in drug delivery market. The leading players have been analyzed by using research methodologies for getting insight views on global competition.

Key questions resolved through this analytical market research report include:

We understand the requirement of different businesses, regions, and countries, we offer customized reports as per your requirements of business nature and geography. Please let us know If you have any custom needs.

For more informative information, please visit us @ https://univdatos.com/report/global-nanotechnology-in-drug-delivery-market-current-analysis-and-forecast-2020-2027

About UnivDatos Market Insights

UnivDatos Market Insights (UMI) is a passionate market research firm and a subsidiary of Universal Data Solutions. We believe in delivering insights through Market Intelligence Reports, Customized Business Research, and Primary Research. Our research studies are spread across topics across the world, we cover markets in over 100 countries using smart research techniques and agile methodologies. We offer in-depth studies, detailed analysis, and customized reports that help shape winning business strategies for our clients.

Contact

UnivDatos Market InsightsPawnendra PawanClient Development LeadPh: +91-7838604911Email: pawnendra@univdatos.com Website: https://univdatos.com/

Logo: https://mma.prnewswire.com/media/1225049/UnivDatos_Logo.jpg

SOURCE UnivDatos Market Insights

Visit link:
Nanotechnology in Drug Delivery Market to Reach US$ 182.3 Billion by 2027, Globally | CAGR: 19.9% | UnivDatos Market Insights - PR Newswire UK

The rapid pace of technology disruption will transform workers' lives and create new professions as the global economy enters an era of robo-sapiens, according to Bank of America Securities.

This will force about 100 million workers to switch occupations by 2030.

A $14 trillion opportunity exists for the future of work, where humans and robots will collaborate, the bank said in a report.

The future of work is not zero-sum between humanity and technology. We believe humans can collaborate with and work alongside robots, rather than be displaced by them, and that technology can create more jobs than it destroys, said BofA Securities.

These new-collar jobs could emerge in sectors ranging from health care to renewables, with humans expected to have more leisure time as machines relieve people of mundane, repetitive daily tasks.

The future of work is not zero-sum between humanity and technology

Bank of America Securities

Technology, industrials, medical technology and education are among the key sectors that stand to benefit as companies upskill and retrain workers.

However, the commercial property and the legacy transport sectors face headwinds.

By 2025 alone, automation will result in a net addition of 12 million jobs as robots eliminate 85 million jobs but create 97 million new ones, according to the World Economic Forum.

The next decade will be marked by unprecedented change in the world of work, the BofA Securities report said.

Humans and machines could spend an equal amount of time completing work tasks by 2025, with the global robot installed base doubling to 5 million units compared with 2019 levels.

The field of cobots the collaboration between humans and industrial robots is a fast-growing area with a projected compound annual growth rate of 50 per cent through to 2023.

Apart from white and blue-collar work, the Covid-19 pandemic is expected to spur a boom in pink, green and new-collar jobs, BofA Securities said.

Pink-collar jobs are professions in the care economy such as doctors, nurses, psychologists, teachers and childcare providers.

Green-collar jobs involve work in the clean energy sector performed by solar engineers, wind technicians and battery experts while new-collar jobs are focused on technology, cyber security and coding.

A transforming world could lead to some truly futuristic jobs that have yet to be invented. Some of these new roles could be data privacy managers, nanomedicine surgeons, lab meat scientists, space tourist guides, freelance biohackers, AI avatar designers, 3D food printer chefs, leisure time planners, ethical algorithm programmers and brain simulation specialists, according to the report.

We are at the early stages of Eureka! Future tech, where we think the exponential growth of moonshot technology will create a new wave of professions that we have not even thought of yet, the report's authors said.

Many jobs of the future have yet to be created, they said, with 65 per cent of children starting school today expected to work in jobs that do not exist at this time.

Covid may spark rapid growth in new types of occupation, the report's authors said.

For example, companies may hire a work-from-home integration manager to ensure that new technology and equipment are in place to make remote work a success.

Organisations with a renewed focus on health and hygiene may hire office disinfectors or chief medical officers.

New occupations such as smart home designers and algorithm bias checkers who ensure algorithms do not lead to discriminatory decisions are emerging.

Around the globe, growing demand for automation, AI and digitisation will spur the need for a wide range of workers such as robot repair technicians and 3D printing engineers, said BofA Securities.

A new report by McKinsey Global Institute said the need for workers to switch occupations would lead to the reskilling of workers a post-Covid future that chief executives must prepare for.

Ageing populations, higher consumer incomes and the pandemic will drive growth in healthcare jobs while transport jobs will grow due to high demand for delivery and e-commerce, according to the McKinsey Global Institute report.

The customer service, sales, warehousing and computer-based work segments will be hit the hardest in terms of jobs lost.

People in these declining job categories will need to be retrained to take up new occupations.

The challenge is not only the large numbers but the jumps they will need to make are much higher than in the past, said Susan Lund, McKinsey Global Institute leader and a labour market expert.

We will need to figure out how to help them to transition to different career pathways. This will disproportionately affect women four times as many as men and people without college degrees, as well as young people and ethnic minorities.

While there are areas where humans can beat machines, including jobs that require creativity or social intelligence, the BofA Securities report said the risks posed by robots should not be disregarded.

Adopting technology could displace about 2 billion jobs by 2030. Up to 47 per cent of US jobs could be at risk from computerisation over the next 20 years. This figure could reach 85 per cent in emerging markets, BofA Securities said.

Emerging markets such as India and China are at the greatest risk of facing skills disruption due to the trend, according to the report.

Ethiopia, Cambodia and Bangladesh are the three countries that face the greatest risk from automation as the majority of work performed in these countries can be done by robots.

The most worrying trend is that emerging market jobs are most at risk of automation because of the low or mid-skilled nature of sectors such as manufacturing, highlighting the risk of premature deindustrialisation.

Premature deindustrialisation refers to a situation where countries hit peak manufacturing before they traverse the economic development curve sufficiently.

Economic history tells us the traditional route to prosperity has been for countries to move from an agrarian economy towards manufacturing via industrialisation, for example, the UK in the early 19th century, the US in the late 19th century and, more recently, China at the turn of the 20th century, the report said.

Bypassing industrialisation could lead to the displacement of manual labour as automation becomes more sophisticated.

View original post here:
'Robo-sapiens' era will force 100 million workers to switch jobs by 2030, BofA says - The National