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Category Archives: Nano medicine
Functional Polymer Market Insights, Trends, Analysis, Types, Applications, key players, Market shares and Forecast 2019 to 2027 – The Market Plan
Posted: September 22, 2019 at 5:44 pm
Global Functional Polymer Market: An Overview
The global functional polymers market is expected to expand at a healthy growth rate during 2018-2026. The market is witnessing a rising demand for functional polymers, due to their diverse application as catalysts, reagents, protecting groups, and many others. Their additional mechanical stability and functioning reactions are key to end-user industries. Additionally, these polymers can also be molded in physical shapes and for enhancing chemical reactions, thanks to their flexible industrial nature.
Their wide ranging applications include washing agents in agriculture and medicine. Growing demand for dyes is also driving growth for the functional polymer market. Functional polymers offer a wide variety of benefits for coloring hair through properties such as thermal stability, biocompatibility, chemical stability, solvent resistance, and great color fastness. The functional polymer market is also witnessing growth due to functional and surface coatings. Polymer coating provide an added advantage of superior protection and adherence from corrosion. Furthermore, polymers use as a catalyst for a wide variety of chemical reactions in industries are likely to generate considerable growth for the functional polymer market in the near future.
Global Functional Polymer Market: Notable Developments According to a new study, polymer-based Nano medicine can revolutionize the treatment of cancer in the near future. As per the study published in the Journal of American Chemical Society (JACS), polymer and Nano medicine combination results in negligible immunotoxicity and high level of therapeutic performance for cancers. Researchers in the study developed a theranostic supramolecular polymer using -cyclodextrin as the host. This advanced potion delivered superior ant metastasis capability, and antitumor performance. This development can propel the functional polymer market significantly, thanks to a growing number of cancers worldwide. Polymer based techniques are widely being experimented in the medical sector. A recent study has paved way for artificial limbs, guided by light. A new polymer based material mechanism enables shrinking of materials and changes in shape as needed. The study presented at American Chemical Societys national meeting, the researcher said, they can apply the new polymer in any 3D network and turn it into a stimuli-responsive material. Growing research and development activities such as these driven by growing interest in polymers are expected to create significant opportunities for many players in the functional polymer market.
Global Functional Polymer Market: Key Trends
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The global functional polymer market is expected to expand significantly in the near future, thanks to a rising demand for lightweight material. The materials are rising in demand due in automotive and aerospace industries as well. Additionally, increased in medical applications and depleting petrochemical resources are also expected to drive growth for the functional polymer market.
Growth of bio-based functional polymers is also a positive sign for the functional polymer market. These polymers, derived from agricultural feedstock such as potatoes and corn is lowering dependency on petrochemicals through products such as polybutylene succinate (PBS), polyethylene terephthalate (PET), polyethylene (PE), and polypropylene (PP).
Global Functional Polymer Market: Regional Outlook
The global functional polymer market report will be divided into several main regions including North America, Europe, Asia Pacific, Latin America, and Middle East and Africa. The functional polymer market is expected to grow significantly in North America due to growing investment in medical breakthroughs, and growing demand in 3D applications. Additionally, rising automotive and defense related applications are also expected to drive growth in Asia Pacific region in the functional polymer market.
Global Functional Polymer Market: Competitive Dynamics
The global functional polymer market is a competitive and fragmented landscape. Increased innovation and low cost initial investments are driving growth for the functional polymer market in many regions. Some key players in the functional polymer market are Schneider Electric, Honeywell, Federal Signal Corporation, WERMA Signaltechnik, Larson Electronics, and Eaton.
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The report offers a comprehensive evaluation of the market. It does so via in-depth qualitative insights, historical data, and verifiable projections about market size. The projections featured in the report have been derived using proven research methodologies and assumptions. By doing so, the research report serves as a repository of analysis and information for every facet of the market, including but not limited to: Regional markets, technology, types, and applications.
The study is a source of reliable data on: Market segments and sub-segments Market trends and dynamics Supply and demand Market size Current trends/opportunities/challenges Competitive landscape Technological breakthroughs Value chain and stakeholder analysis
The regional analysis covers: North America (U.S. and Canada) Latin America (Mexico, Brazil, Peru, Chile, and others) Western Europe (Germany, U.K., France, Spain, Italy, Nordic countries, Belgium, Netherlands, and Luxembourg) Eastern Europe (Poland and Russia) Asia Pacific (China, India, Japan, ASEAN, Australia, and New Zealand) Middle East and Africa (GCC, Southern Africa, and North Africa)
The report has been compiled through extensive primary research (through interviews, surveys, and observations of seasoned analysts) and secondary research (which entails reputable paid sources, trade journals, and industry body databases). The report also features a complete qualitative and quantitative assessment by analyzing data gathered from industry analysts and market participants across key points in the industrys value chain.
A separate analysis of prevailing trends in the parent market, macro- and micro-economic indicators, and regulations and mandates is included under the purview of the study. By doing so, the report projects the attractiveness of each major segment over the forecast period.
Highlights of the report: A complete backdrop analysis, which includes an assessment of the parent market Important changes in market dynamics Market segmentation up to the second or third level Historical, current, and projected size of the market from the standpoint of both value and volume Reporting and evaluation of recent industry developments Market shares and strategies of key players Emerging niche segments and regional markets An objective assessment of the trajectory of the market Recommendations to companies for strengthening their foothold in the market
Note:Although care has been taken to maintain the highest levels of accuracy in TMRs reports, recent market/vendor-specific changes may take time to reflect in the analysis.
Request for TOC of This Report visit at https://www.transparencymarketresearch.com/sample/sample.php?flag=T&rep_id=66401&source=atm
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Functional Polymer Market Insights, Trends, Analysis, Types, Applications, key players, Market shares and Forecast 2019 to 2027 - The Market Plan
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Nanotechnology in Medical Applications Market: Strategic Analysis to Understand the Competitive Outlook of the Industry, 2025 – Market Forecast
Posted: September 22, 2019 at 5:44 pm
Global Nanotechnology in Medical Applications Market: Overview
In the 20th century, developments in the field of nanotechnology and the applications of the technology in pharmaceuticals and medicines have increased significantly. Nanotechnology uses individual molecules, compounds, or atoms in various structures to produce devices and materials with unique characteristics. It works on matter with dimensions that could range from 1 nanometer to 100 nanometer. Nanotechnology has applications in the formation of various types of nano devices and nano materials. Nanomedicine is a signficant application of nanotechnology. Nanotechnology drugs are used in the field of medicine and health. Nanomedicine makes use of nano electronic biosensors and nano materials. It enables improved diagnosis, early detection and prevention, and proper treatment and examination of diseases. Nanomedicine involves interactions between nano devices and bio molecules in extracellular medium as well as inside human cells. Performance and functioning of drugs at a nano scale is varied from the one seen in a micro scale. The use of nanotechnology can improve the detection of the root cause of diseases and treat the damage that has occurred in the human body. The effect of nanomedicine drugs is faster than that of traditional drugs. Nanomedicine drugs can be used to target specific diseases.
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The invention of nanotechnology has benefitted human health to a large extent. Advancements in nanotechnology can help repair and reproduce damaged tissue of the body. Nanotechnology enables the production of artificially stimulated cells that are used in tissue engineering. This helps in the development of artificial implants or transplantation of organs. Nanorobots can be modified to repair particular diseased cells. They function in the same way as antibodies that aid in the natural healing processes within the body. Nanotechnology has signficant contributions in the field ofstem cell research. Gold nanoparticles are used in the detection of targeted nucleic acids, with their sequence to recognize the treatment. Gold nanoparticles are being tested for use in the treatment of cancer and other serious harmful diseases. Nanotechnology is being used for developing instruments that purity the human blood. Magnetic microparticles aid in the separation of proteins and cells from complex media, thus helps in the examination of infections in diseases such as sepsis.
Global Nanotechnology in Medical Applications Market: Key Trends
The global nanotechnology in medical applications market is expected to expand at a rapid pace in the coming years. Research and development in nanomedicine is expected to drive the market. Moreover, government funding programs specifically for nanotechnology in key regions are expected to augment the market. However, long drawn out product approval processes and high costs of nanotechnology-based medical devices and products are expected to inhibit the growth of the nanotechnology in medical application market from 2018 to 2026.
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Global Nanotechnology in Medical Applications Market: Segmentation
The global nanotechnology in medical applications market can be segmented based on product, application, and region. Based on product, the global nanotechnology in medical applications market can be classified into nanoparticles, biochips, medical textiles, implantable materials, active implantable devices, wound dressings, and others. The implantable materials segment can be further divided into dental filling materials and bone restorative materials. The active implantable devices segment can be further divided into cardiac rhythm management devices, hearing aid devices, and retinal implants. The active implantable devices segment is expected to constitute a prominent share of the global nanotechnology in medicine application market. In terms of application, the market can be categorized into drug delivery & therapeutics, diagnostics techniques, and others.
Global Nanotechnology in Medical Applications Market: Regional Analysis
Based on region, the global nanotechnology in medical applications market can be divided into North America, Europe, Asia Pacific, Latin America, and Middle East & Africa. The market in Asia Pacific is expected to expand at a robust pace, due to an increase in research efforts, rise in geriatric population, and increase in R&D expenditure on nanotechnology in the region.
Global Nanotechnology in Medical Applications Market: Competitive Landscape
Prominent players operating in the global nanotechnology in medical applications market are AstraZeneca, Ablynx, Abraxis BioScience Inc (Celgene Corporation), BioForce Nanosciences, Calando Pharmaceuticals, Inc., Elan (Alkermes), Kereos, Inc, Kleindiek Nanotechnik GmbH, MagForce AG, BlueWillow Biologics, Nanobiotix, Nanocopoeia, LLC., and Transgenex Nanobiotech, Inc.. among others. The report offers a comprehensive evaluation of the market. It does so via in-depth qualitative insights, historical data, and verifiable projections about market size. The projections featured in the report have been derived using proven research methodologies and assumptions. By doing so, the research report serves as a repository of analysis and information for every facet of the market, including but not limited to: Regional markets, technology, types, and applications. The study is a source of reliable data on: Market segments and sub-segments Market trends and dynamics Supply and demand Market size Current trends/opportunities/challenges Competitive landscape Technological breakthroughs Value chain and stakeholder analysis The regional analysis covers: North America (U.S. and Canada) Latin America (Mexico, Brazil, Peru, Chile, and others) Western Europe (Germany, U.K., France, Spain, Italy, Nordic countries, Belgium, Netherlands, and Luxembourg) Eastern Europe (Poland and Russia) Asia Pacific (China, India, Japan, ASEAN, Australia, and New Zealand) Middle East and Africa (GCC, Southern Africa, and North Africa) The report has been compiled through extensive primary research (through interviews, surveys, and observations of seasoned analysts) and secondary research (which entails reputable paid sources, trade journals, and industry body databases). The report also features a complete qualitative and quantitative assessment by analyzing data gathered from industry analysts and market participants across key points in the industrys value chain. A separate analysis of prevailing trends in the parent market, macro- and micro-economic indicators, and regulations and mandates is included under the purview of the study. By doing so, the report projects the attractiveness of each major segment over the forecast period. Highlights of the report: A complete backdrop analysis, which includes an assessment of the parent market Important changes in market dynamics Market segmentation up to the second or third level Historical, current, and projected size of the market from the standpoint of both value and volume Reporting and evaluation of recent industry developments Market shares and strategies of key players Emerging niche segments and regional markets An objective assessment of the trajectory of the market Recommendations to companies for strengthening their foothold in the market Note:Although care has been taken to maintain the highest levels of accuracy in TMRs reports, recent market/vendor-specific changes may take time to reflect in the analysis.
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Nanotechnology in Medical Applications Market: Strategic Analysis to Understand the Competitive Outlook of the Industry, 2025 - Market Forecast
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Global Nanorobots Market Prospective Growth, Opportunities, Top Key Players and Forecast to 2024 – Pioneer Reporter
Posted: September 22, 2019 at 5:44 pm
WiseGuyRerports.com Presents Global Nanorobots Market 2019 by Company, Regions, Type and Application, Forecast to 2024 New Document to its Studies Database
According to the latest report added to the online inventory of Wise Guys Report (WGR) the global Nanorobots market has witnessed an unprecedented rise and the extrapolated growth indicates further growth to $85 billion by 2024 registering a record CAGR of 21.5% during the forecast timeline.Nanorobots are the FDA approved new generation nanomachines that come with a wide spectrum of new therapies. Basically it is a tiny machine that is programmed to achieve certain tasks once or repeatedly in particular parts with high precision. Nanorobots are mainly used to treat cancer bytransforming them into drug carrying vendors. These drugs which are usually toxic medications are administered directly to the effected region with high precision without compromising the healthy tissues in the surrounding regions. It is the medical characteristics of nanorobots that has propelled the expansion in research and development of nanorobots in the healthcare vertical for the creation of nanomedicines. Currently nanomedicine accounts for the maximum share of the global nanorobotics market.More inclination for safe and reliable healthcare technologies have driven the use of Nanobots in healthcare. Nanobots possess the ability to scan the body for cancer cells. If it locates disputable cells it does further careful analysis post which it destroys the cell using more vigorous mechanisms than what the immune system is designed for. Widespread adoption of nanotechnology among surgeons, specialists and other medical caretakers will only propel and encourage the Nanobots market. The biggest impediment in the global nanorobot market is the cost of any new product that hits the market. This is mainly attributed to the temporary monopoly gained by the manufacturer backed by the patents they have acquired.
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Global Nanorobots Market: Segmental Analysis
According to the segmental analysis of global nanorobot market the landscape can be bifurcated as per type, application and marketing channel adopted.Based on type the variants of nanorobots available in the market are Microbivore Nanobots, RespirOcyte NamObots, Clottocyte Nanobots and Cellular Repair Nanobots.
Categorized by application nanorobots can be used in Nano Medicine, Biomedical, Mechanical and others. The nanomedicine has more prevalent market presence contributing almost 35% of the Overall share as of 2016. This has been triggered by technological advancements in the field of healthcare giving birth to nano-swimmers, bacteria powered robots and magnetically controlled nanobots that are specifically designed to target cancerous regions in nano-dimensions.
Labelled by marketing channel, the marketing models used in global nanorobot scope are direct marketing, indirect marketing and nanorobots customers.
Global Nanorobots Market: Regional Analysis
Market segmentation by companies engaged in production of nanorobots include enterprises such as Bruker, Lhemo Fisher, Ginkgo BioworkS Oxford Instruments. Ex Group, Imina Technologies, Toronto Nano Instrumentation, Klocke Nanotechnik. Kleindiek Nanotechnik, Xidex, Synthace, Park Systems, Smaract Nanonics Imaging, Novascan technologies and Angstrom Advanced.
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Global Nanorobots Market Prospective Growth, Opportunities, Top Key Players and Forecast to 2024 - Pioneer Reporter
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Growing hair on bald heads with electric tech may soon be easy – Livemint
Posted: September 22, 2019 at 5:44 pm
BENGALURU
Reversing baldness could someday be as easy as wearing a hat, thanks to a noninvasive, low-cost hair-growth-stimulating technology, according to engineers at the University of Wisconsin-Madison. Before you jump with excitement, though, do keep in mind that the researchers have only patented the concept with the Wisconsin Alumni Research Foundation, and are yet to test this on humans.
Based on devices that gather energy from a body's daily motion, the hair-growth technology stimulates the skin with gentle, low-frequency electric pulses, which coax dormant follicles to reactivate hair production. The devices don't cause hair follicles to sprout anew in smooth skin. Instead, they reactivate hair-producing structures that have gone dormant.
That means they could be used as an intervention for people in the early stages of pattern baldness, but they wouldn't bestow cascading tresses to someone who has been as bald as a billiard ball for several years. Further, because the devices are powered by the movement of the wearer, they don't require a bulky battery pack or complicated electronics. In fact, they're so low-profile that they could be discreetly worn underneath the crown of an everyday baseball cap.
Xudong Wang, a professor of materials science and engineering at UW-Madison, and his colleagues have published a description of the technology in the journal ACS Nano, the researchers said in 20 September statement.
Wang is a world expert in the design and creation of energy-harvesting devices. He has pioneered electric bandages that stimulate wound-healing and a weight-loss implant that uses gentle electricity to trick the stomach into feeling full.
The hair-growth technology is based on a similar premise: Small devices called nanogenerators passively gather energy from day-to-day movements and then transmit low-frequency pulses of electricity to the skin. That gentle electric stimulation causes dormant follicles to "wake up." "Electric stimulations can help many different body functions," says Wang. "But before our work there was no really good solution for low-profile devices that provide gentle but effective stimulations."
Because the electric pulses are incredibly gentle and don't penetrate any deeper than the very outermost layers of the scalp, the devices don't seem to cause any unpleasant side effects. That's a marked advantage over other baldness treatments, like the medicine Propecia, which carries risks of sexual dysfunction, depression and anxiety.
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Growing hair on bald heads with electric tech may soon be easy - Livemint
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Nano-biotechnology Market by Manufacturer Analysis 2016-2024 – BitGmx
Posted: September 22, 2019 at 5:44 pm
Global Nano-biotechnology Market: Overview
Nanotechnology is referred as the manipulation of matter on the super-molecular, molecular, and atomic scale. The earliest description of nanotechnology is the goal of technologically manipulating the molecules and atoms for the fabrication of macro-scale components, commonly known as molecular nanotechnology. Moving to nano-biotechnology, it refers to the miniaturization of biotechnology and the ways in which nanotechnology can be used for the development of devices employed for studying biological systems, thus aiding in advancing the goals of biology. It is also the branch of nanotechnology that is known for dealing with biochemical and biological uses or applications. Nano-biotechnology also studies the nature of fabricating new nano-devices and elements existing in living organisms. The applications of nano-biotechnology in terms of commercial use in the biomedical field are basically directed towards development new techniques in biosciences and drugs delivery systems.
Although nano-biotechnology is in an infant stage, researchers and scientists are developing several methods that immense scope of development in future, thus increasing the hope of participants that it will yield beneficial results in future. Nano-biotechnology also finds applications in drug delivery systems in target specific therapies, biomarkers, biosensors, molecular imaging, disease diagnosis, and gene therapy. When collaborated with biological research, nano-biotechnology results in the development of high-end innovations in the healthcare industry. Nano-biotechnology has capacities for progressing medical science thus refining health care practices across the globe. Numerous novel nano-particles and nano-devices are anticipated to be employed, with a colossal positive effect on human health. While true clinical applications of nano-technology are still basically inexistent, a noteworthy amount of favorable medical projects are in an advanced experimental stage. Implementation of nanotechnology in physiology and medical means that devices are so precisely designed that they can interrelate with sub-cellular levels of the body with an extraordinary degree of specificity. Thus, therapeutic worth can be attained to extreme with trifling side effects with regards to tissue-specific or targeted cell clinical intervention.
The market research publication is a comprehensive analysis of the growth trajectory in terms of the past, present, and future progress and prospects of the global nano-biotechnology market. It further presents an assessment of the aspects that are expected to influence the growth of the market and the chief trends. The report also offers a diverse understanding of the competitive scenario of the market by utilizing the value chain and Porters five forces analysis. The report highlights the research and development projects, mergers and acquisitions, details on collaborations and licensing. The study also offers information on the marketing strategies, products, and shares of the key players operating in the market.
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Global Nano-biotechnology Market: Trends and Opportunities
The global nano-biotechnology is likely to witness promising growth owing to the rise in the number of new, promising, and innovative products that are currently undertaking clinical trials. Scientists are confident that these trials will give positive results and nano-biotechnology will help in transforming the prevention process, diagnosis, and treatment of various diseases in the near future. Other than medicine, nano-biotechnology also has potential use in areas such as energy production, electronics, and biomaterials. The increasing applications of nano-biotechnology along with the investments being made public and private companies and organizations is an indication of a bright future for nano-biotechnology. It has been predicted that the products that presently under the pipeline review are likely to find commercial platforms soon.
Like any new introduction in the market, nano-biotechnology is also likely to face several challenges. The primary issues that are expected to have an adverse impact on the market growth are environmental problems and effect of the toxicity of nano-materials on the environment and the global economy. Other threats include uncertainty of product effectiveness, scarce resources, funding, scalability, and the development of proper devices.
Global Nano-biotechnology Market: Regional Outlook
The global nano-biotechnology market has been segmented into Asia Pacific, North America, Europe, and the Rest of the World. The manufacturers of nano-biotechnology devices can gen potential opportunities in the emerging markets in North America and Europe. The United States is investing heavily in the research and development projects of nano-biotechnology and is also implementing flexible policies.
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Companies Mentioned in the Report
The companies operating in the market are Ablynx, AC Serendip, dermaCM, Dabur Pharma, Xantec Bioanalytics, Cellix, WaveSense, Marina Biotech, BioNano Genomics, and INanoBio among others.
This research report analyzes this market depending on its market segments, major geographies, and current market trends. Geographies analyzed under this research report include North America Asia Pacific Europe Rest of the World
This report gives you access to decisive data such as: Market growth drivers Factors limiting market growth Current market trends Market structure Market projections for the coming years
Key highlights of this report Overview of key market forces propelling and restraining market growth Up-to-date analyses of market trends and technological improvements Pin-point analyses of market competition dynamics to offer you a competitive edge An analysis of strategies of major competitors An array of graphics and SWOT analysis of major industry segments Detailed analyses of industry trends A well-defined technological growth map with an impact-analysis Offers a clear understanding of the competitive landscape and key product segments
The report offers a comprehensive evaluation of the market. It does so via in-depth qualitative insights, historical data, and verifiable projections about market size. The projections featured in the report have been derived using proven research methodologies and assumptions. By doing so, the research report serves as a repository of analysis and information for every facet of the market, including but not limited to: Regional markets, technology, types, and applications. The study is a source of reliable data on: Market segments and sub-segments Market trends and dynamics Supply and demand Market size Current trends/opportunities/challenges Competitive landscape Technological breakthroughs Value chain and stakeholder analysis The regional analysis covers: North America (U.S. and Canada) Latin America (Mexico, Brazil, Peru, Chile, and others) Western Europe (Germany, U.K., France, Spain, Italy, Nordic countries, Belgium, Netherlands, and Luxembourg) Eastern Europe (Poland and Russia) Asia Pacific (China, India, Japan, ASEAN, Australia, and New Zealand) Middle East and Africa (GCC, Southern Africa, and North Africa) The report has been compiled through extensive primary research (through interviews, surveys, and observations of seasoned analysts) and secondary research (which entails reputable paid sources, trade journals, and industry body databases). The report also features a complete qualitative and quantitative assessment by analyzing data gathered from industry analysts and market participants across key points in the industrys value chain. A separate analysis of prevailing trends in the parent market, macro- and micro-economic indicators, and regulations and mandates is included under the purview of the study. By doing so, the report projects the attractiveness of each major segment over the forecast period. Highlights of the report: A complete backdrop analysis, which includes an assessment of the parent market Important changes in market dynamics Market segmentation up to the second or third level Historical, current, and projected size of the market from the standpoint of both value and volume Reporting and evaluation of recent industry developments Market shares and strategies of key players Emerging niche segments and regional markets An objective assessment of the trajectory of the market Recommendations to companies for strengthening their foothold in the market Note:Although care has been taken to maintain the highest levels of accuracy in TMRs reports, recent market/vendor-specific changes may take time to reflect in the analysis.
Request for TOC of This Report visit at https://www.transparencymarketresearch.com/sample/sample.php?flag=T&rep_id=788&source=atm
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Nano-biotechnology Market by Manufacturer Analysis 2016-2024 - BitGmx
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Journal of Nanomedicine and Biotherapeutic Discovery- Open …
Posted: May 1, 2019 at 11:51 pm
Nanomedicine is an application of nanotechnology which made its debut with greatly increased possibilities in the field of medicine. Nanomedicine desires to deliver research tools and clinically reformative devices in the near future.
Journal of Nanomedicine & Biotherapeutic Discovery is a scholarly open access journal publishing articles amalgamating broad range of fields of novel nano-medicine field with life sciences. Nanomedicine & Biotherapeutic Discovery is an international, peer-reviewed journal providing an opportunity to researchers and scientist to explore the advanced and latest research developments in the field of nanoscience & nanotechnology.
This is the best academic journal which focuses on the use nanotechnology in diagnostics and therapeutics; pharmacodynamics and pharmacokinetics of nanomedicine, drug delivery systems throughout the biomedical field, biotherapies used in diseases treatment including immune system-targeted therapies, hormonal therapies to the most advanced gene therapy and DNA repair enzyme inhibitor therapy. The journal also includes the nanoparticles, bioavailability, biodistribution of nanomedicines; delivery; imaging; diagnostics; improved therapeutics; innovative biomaterials; regenerative medicine; public health; toxicology; point of care monitoring; nutrition; nanomedical devices; prosthetics; biomimetics and bioinformatics.
The journal includes a wide range of fields in its discipline to create a platform for the authors to make their contribution towards the journal and the editorial office promises a peer review process for the submitted manuscripts for the quality of publishing. Biotherapeutics journals impact factors is mainly calculated based on the number of articles that undergo single blind peer review process by competent Editorial Board so as to ensure excellence, essence of the work and number of citations received for the same published articles.
The journal is using Editorial Manager System for quality peer review process. Editorial Manager is an online manuscript submission, review and tracking systems. Review processing is performed by the editorial board members of Journal of Nanomedicine & Biotherapeutic Discovery or outside experts; at least two independent reviewers approval followed by editor approval is required for acceptance of any citable manuscript. Authors may submit manuscripts and track their progress through the system, hopefully to publication. Reviewers can download manuscripts and submit their opinions to the editor. Editors can manage the whole submission/review/revise/publish process.
Submit manuscript at http://editorialmanager.com/chemistryjournals/ or send as an e-mail attachment to the Editorial Office at[emailprotected]
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Journal of Nanomedicine and Biotherapeutic Discovery- Open ...
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IEEE-NANOMED 2016 The 10th IEEE International Conference …
Posted: October 13, 2018 at 8:45 am
Holiday Inn Macao Cotai Central Sands Cotai Central, Cotai Strip, Taipa, Macau SAR, China
Program Timetable (PDF version) is available. (FINAL, updated on Oct 26)
Registration Time:
IEEE-NANOMED is one of the premier annual events organized by the IEEE Nanotechnology Council to bring together physicians, scientists and engineers alike from all over the world and every sector of academy and industry, working at advancement of basic and clinical research in medical and biological sciences using nano/molecular and engineering methods. IEEE-NANOMED is the conference where practitioners will see nano/molecular medicine and engineering at work in both their own and related fields, from essential and advanced scientific and engineering research and theory to translational and clinical research.
Conference Theme:
Authors are also invited to submit results to a special issue of the journal Micromachines (impact factor 1.295), on the topic of Microdevices and Microsystems for Cell Manipulation. More information on the special issue and paper submission can be found here:http://www.mdpi.com/journal/micromachines/special_issues/cell_manipulation
Authors are also invited to submit results to a special issue of the journal Micromachines (impact factor 1.295), on the topic of MEMS/NEMS for Biomedical Imaging and Sensing. More information on the special issue and paper submission can be found here:http://www.mdpi.com/journal/micromachines/special_issues/MEMS_biomedical_imaging_sensing
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IEEE-NANOMED 2016 The 10th IEEE International Conference ...
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Nanomedicine – Overview
Posted: October 8, 2018 at 2:45 pm
The program began in 2005 with a national network ofeight Nanomedicine Development Centers. Now, in the second half of this 10-year program, the four centers best positioned to effectively apply their findings to translational studies were selected to continue receiving support.
Nanomedicine, an offshoot of nanotechnology, refers to highly specific medical intervention at the molecular scale for curing disease or repairing damaged tissues, such as bone, muscle, or nerve. A nanometer is one-billionth of a meter, too small to be seen with a conventional lab microscope. It is at this size scale about 100 nanometers or less that biological molecules and structures operate in living cells.
The NIH vision for Nanomedicine is built upon the strengths of NIH funded researchers in probing and understanding the biological, biochemical and biophysical mechanisms of living tissues. Since the cellular machinery operates at the nanoscale, the primary goal of the program - characterizing the molecular components inside cells at a level of precision that leads to re-engineering intracellular complexes - is a monumental challenge.
The teams selected to carry out this initiative consist of researchers with deep knowledge of biology and physiology, physics, chemistry, math and computation, engineering, and clinical medicine. The choice and design of experimental approaches are directed by the need to solve clinical problems (e.g., treatment of sickle cell disease, blindness, cancer, and Huntingtons disease). These are very challenging problems, and great breakthroughs are needed to achieve the goals within the projected 10 year timeframe. The initiative was selected for the NIH Roadmap (now Common Fund) precisely because of the challenging, high risk goals, and the NIH team is working closely with the funded investigators to use the funds and the intellectual resources of the network of investigators to meet those challenges.
10 Year Program Design High Risk, High Reward
The Centers were funded with the expectation that the first half of the initiative would be more heavily focused on basic science with increased emphasis on application of this knowledge in the second five years. This was a novel, experimental approach to translational medicine that began by funding basic scientists interested in gaining a deep understanding of an intracellular nanoscale system and necessitated collaboration with clinicians from the outset in order to properly position work at the centers so that during the second half of the initiative, studies would be applied directly to medical applications. The program began witheight Nanomedicine Development Centers(NDCs), and four centers remain in the second half of the program.
Clinical Consulting Boards (CCBs)
The program has establishedClinical Consulting Boards (CCBs)for each of the continuing centers. These boards consist of at least three disease-specific clinician-scientists who are experts in the target disease(s). The intent is for CCBs to provide advice and insight into the needs and barriers regarding resource and personnel allocations as well as scientific advice as needed to help the centers reach their translational goals. Each CCB reports directly to the NIH project team.
Translational Path
In 2011, the PIs of the NDCs worked with their CCBs to precisely define their translational goals and the translational research path needed to reach those goals by the end of the initiative in 2015. To facilitate this, the NIH project team asked them to developcritical decision pointsalong their path. These critical decision points differ from distinct milestones because they may be adjusted based on successes, challenges, barriers, and progress. Similarly, the timing of these decision points may be revised as the centers progress. Research progress and critical decision points are revisited several times a year by the CCB and the NIH team, and when a decision point is reached, next steps are re-examined for relevance, feasibility and timing.
Transition plan
Throughout the program, various projects have been spun off of work at all the centers and most have received funding from other sources. This was by design as work at each center has been shifting from basic science to translational studies. Centers will not be supported by the common fund after 10 years. It is expected that work at the centers will be more appropriately funded by other sources. Pre-clinical targets will likely be developed, and the work at each center will be focused on a specific disease so the work will need to transition out of the experimental space of the common fund.
Support for the NIH Nanomedicine Initiative is provided by the NIH Common Fund, and a team of staff members from across the NIH oversees the program. You may direct questions or comments on the NIH Nanomedicine Initiative to Dr. Richard S. Fisher, Nanomedicine Project Team Leader (nano@nih.gov).
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Nanomedicine - Overview
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Nanomedicine Conferences | Nanotechnology Events …
Posted: October 8, 2018 at 2:45 pm
About Conference
ME Conferences invites all the participants from all over the world to attendNanomedicine and Nanotechnology in Health CareDuring 17-19 September, 2018 at Abu Dhabi, UAE. This includes prompt keynote presentations, Oral talks, Poster presentations and Exhibitions. And it provides an opportunity to learn about the complexity of the Diseases, discuss interventional procedures, look at new and advances in Nanotechnology and their efficiency and efficacy in diagnosing and treating various diseases and also in Healthcare treatments.
ME Conferences organizes 1000+ Global Events Every Year across USA, Europe & Asia with support from 1000 more scientific societies and Publishes 700+ Open access journals which contains over 1,00,000 eminent personalities, reputed scientists as editorial board and organizing committee members. ME Conferences journals have over 5 million readers and the fame and success of the same can be attributed to the strong editorial board which contains over 30000 eminent personalities and the rapid, quality and quick review processing.ME Conferences make the perfect platform for global networking as it brings together renowned speakers and scientists across the globe to a most exciting and memorable scientific event filled with much enlightening interactive sessions, international workshops, world class international exhibitions and poster presentations.
Why to attend?
This Conference Nanomedicinemeet 2018 will focus on Healthcare and Medicine. World-renowned speakers, the most recent techniques, tactics, and the newest updates in fields Nanotechnology and Engineering, Medical Nanotechnology, Tissue Engineering are hallmarks of this conference. Nanomedicinemeet-2018 is an exciting opportunity to showcase the modern technology, the new products of your company, and/or the service your industry may offer to a broad international audience. It covers a lot of topics and it will be a nice platform to showcase their recent researches on Nanotechnology, MaterialScienceand other interesting topics.
Target Audience:
The termNano medicineencompasses a broad range of technologies and materials. Types of nanomaterials that have been investigated for use as drugs,, drug carriersor other Nonmedical agents. There has been steep growth in development of devices that integrate nanomaterials or other nanotechnology. Thenanotechnology-based medical devices market is categorized into three major segments, namely, therapeutic applications, diagnostics applications, and research applications. Rising incidence of lifestyle and age-related disorders (such as cardiovascular and hearing disorders) has contributed significantly to the growth of the nanotechnology-based active implantable devices market. Nanotechnology, or systems/device manufacture at the molecular level, is a multidisciplinary scientific field undergoing explosive development. The genesis of nanotechnology can be traced to the promise of revolutionary advances across medicine, communications and genomics. On the surface, miniaturization provides cost effective and more rapidlyfunctioningbiological components. Less obvious though is the fact that Nanometer sized objects also possess remarkableself-ordering and assemblybehaviors under the control of forces quite different from macro objects.
Advances in technology have increased our ability to manipulate the world around us . Nanotechnology is rapidly emerging within the realm of medicine. Nanomedicine is the process of diagnosing, treating, and preventing disease andtraumatic injury, of relieving pain, and of preserving and improving human health, using molecular tools and molecular knowledge of the human body. An exciting and promising area of Nano technological development is the building of Nanorobots. Highly precise positioning techniques are required in Miniaturing in chip technology, optics , micro mechanic, medicine , gene and biotechnology. The new manipulation technology is the desire to enter the micro and Nano world not only by viewing but also acting, alteringmicro andNanosized objects. Nanorobots plays a critical roles for many applications in the human body, such astargetingtumoral lesionsfor therapeutic purposes, miniaturization of the power source with an effective onboard controllable propulsion and steering system have prevented the implementation of such mobile robots.
The therapeutic properties of light have been known for thousands of years, but it was only in the last century that photodynamic therapy (PDT) was developed. It is an emerging modality for the treatment of a variety of diseases that require the killing of pathological cells (e.g. cancer cells or infectious micro-organisms) or the removal of unwanted tissue (e.g. neovascularization in the choroid or atherosclerotic plaques in the arteries). It is based on the excitation of nontoxic photosensitizers.Photodynamic therapy(PDT) uses the combination of dyes with visible light to produce reactive oxygen species and kill bacteria and destroy unwanted tissue. Nanotechnology plays a great role insolubilizing thephotosensitizers, metal nanoparticles can carry out Plasmon resonance enhancement, andfullerenescan act as photosensitizers, themselves.
Nanotechnology is becoming increasingly important for the several sectors. Promising results and applications are already being developed in the areas of nutrient delivery systems through bioactive Nano encapsulation,biosensorsto detect and quantifypathogens organic compounds. The sensitivity and performance of biosensors is being improved by using nanomaterials for their construction. The use of these nanomaterials has allowed the introduction of many new signal transduction technologies in biosensors. Many scientists have involved themselves to know the application and the benefits of nanotechnology in different areas of food industry that include bioactive Nano encapsulation, edible thin film, packages andNano sensors.
Green chemistry and Nano science are both emerging fields that take advantage of molecular-level designing and have enormous potential for advancing our science. Nano science is the study of materials that are on the length-scale of 100 nanometers or smaller and have properties that are dependent on their physical size. The principles of green chemistry can guide responsible development of Nano science, while the new strategies of Nano science can fuel the development ofgreener productsand processes.Phytochemicalsoccluded in tea have been extensively used as dietary supplements and as naturalpharmaceuticalsin the treatment The parallel development of green chemistry and Nano science and the potential synergy of the two fields can lead to more successful and profitable technologies with reduced environmental impacts and improved conservation of resources. In recent years, green synthesis ofmetal nanoparticlesis an interesting issue of the nanoscience.
Nanotechnologyis enabling technology that deals with Nano-meter sized objects. It is expected that nanotechnology will be developed at several levels: materials, devices and systems. The combination of biology and nanotechnology has led to a new generation ofNano devicesthat opens the possibility to characterize the chemical, physical, mechanical, and other molecular properties. And it can be even used to characterize the single molecules or cells at extraordinarily high throughput.Nanoparticleswith distinctive chemical compositions, sizes, shapes, and surface chemistries can be engineered easily and this technique has wide range of applications in biological systems.Utility of nanotechnology to biomedical sciences imply creation of materials and devices designed tointeraction in sub-cellular scaleswith a high degree of specificity.
Biopolymer nanoparticles are offering numerous advantages which embrace the simplicity of their preparation from well-understood biodegradable, biocompatible polymers and their high stability inbiological fluidsduring storage. Since the emergence of Nanotechnology in the past decades, the development and design of organic andbioorganic nanomaterialshas become an important field of research. And several types of polymers have been tested and are used in drug delivery systems; including nanoparticles, dendrimers, capsosomes and micelles. Researchers have found, the synthesized polymers even serves as a good carrier and plays a vital role in carrying a drug. And in other hand they are used in food industries too for food package purposes. There are thousands of organic chemicals are in present in various pharmaceutical to consumer product and are being used in dyes, flavoring agents. It can be explained in organic compounds ranging in diameter from 10 to 1m.Ultrafine particlesare the same asnanoparticlesand between 1 and 100 nanometers in size, fine particles are sized between 100 and 2,500 nanometers, and coarse particles cover a range between 2,500 and 10,000nanometers.
The biological synthesis ofnanoparticlesis synthesis method through which we can control, size and shape of nanoparticles and it increasingly regarded as a rapid, ecofriendly, and easily scaled-up technology. Over the past few years researches have shown their interest inmetallic nanoparticlesand their synthesis has greatly increased. However, drawbacks such as the involvement oftoxic chemicalsand the high-energy requirements of production. Synthesizing living organisms such as bacteria, fungi and plants is an alternative way to overcome the drawbacks. Plant mediated synthesis of nanoparticles is the green chemistry that connects. Generally, metal nanoparticles are synthesized and stabilized by using physical and chemical: the chemical approach, such as chemical reduction,electrochemical techniques,photochemical reactionsin reverse micelles. There is a growing attention to biosynthesis the metal nanoparticles using organisms. Among these organisms, plants seem to be the best candidate and they are suitable for large scale biosynthesis of nanoparticles.
Nanoparticles used asdrug deliveryvehicles are generally below 100 nm , and are coated with different biodegradable materials such as natural or synthetic polymers (PEG,PVA,PLGA,etc.), lipids, or metals , it plays significant role on cancer treatment as well as it holds tremendous potential as an effective drug delivery system. A targeted drug delivery system (TDDS) is a system, which releases the drug in a controlled manner. Nanosystems with different compositions and biological properties have been extensively investigated for drug and gene delivery applications. To achieve efficient drug delivery it is important to understand the interactions ofNanomaterialswith the biological environment, targetingcell-surface receptors, drug release, multiple drug administration, stability of therapeutic agents. Nanotechnology refers to structures roughly in the 1100 nm size regime in at least one dimension. Despite this size restriction, nanotechnology commonly refers to structures that are up to several hundred nanometers in size and that are developed bytop-down or bottom-up engineering of individual components.
Nanosuspention formulation can be used to improve the solubility of the poorly soluble drugs. One of the major problems associated with poorly soluble drugs is very low bioavailability. The Preparation ofNanosuspentionis simple and applicable to all drugs which are water insoluble. It consists of the pure poorly water-soluble drug without any matrix material suspended in dispersion . Various techniques are used for the enhancement of the solubility of poorly soluble drugs which include physical and chemical modifications of drug and other methods like particle size reduction,crystal engineering, salt formation, solid dispersion, use ofsurfactant, complexation A range of parameters like solubility, stability at room temperature, compatibility with solvent, excipient, andphotostabilityplay a critical role in the successful formulation of drugs. Use of some drug which is potentially restricted because of its toxic side-effects and its poor solubility, making it unsuitable for intravenous use in patients withdrug malabsorption.
Nano medicine drives the convergence of nanotechnology and medicine it is delineated as the application of nanotechnology in healthcare. The field of tissue engineering has developed in phases: initially researchers searched for inert biomaterialsto act solely as replacement structures in the body. Tissue engineering is classified as an associate field of biomaterialsand engineering. It focuses on the use of cellular and material-based therapies aimed attargeted tissue regenerationcaused by traumatic, degenerative, and genetic disorders.It covers a broad range of applications, in practice the term has come to represent applications that repair or replace structural tissues (i.e., bone, cartilage, blood vessels, bladder, etc.). Today, these Nano scale technologies are coming to the forefront in medicine because of their biocompatibility, tissue-specificity, and integration and ability to act as therapeutic carriers.
Polymeric nanoparticles (NPs) are one of the most studied organic strategies for Nano medicine. Intense interest lies in the potential ofpolymeric NPsto revolutionize modern medicine. Polymeric NPs include drug delivery techniques such as conjugation and entrapment of drugs,prodrugs, stimuli-responsive systems,imaging modalities, and theranostics.The use of biodegradable polymeric nanoparticles (NPs) for controlled drug delivery has shown significanttherapeutic potential. Concurrently, targeted delivery technologies are becoming increasingly important as a scientific area of investigation. Polymericnanoparticles-based therapeutics show great promise in the treatment of a wide range of diseases, due to the flexibility in which their structures can be modified, with intricate definition over their compositions, structures and properties. Advances in polymerizationchemistries and the application of reactive, efficient andorthogonal chemicalmodification reactionshave enabled the engineering of multifunctional polymericnanoparticles.
In recent years,microbubbleand Nano bubble technologies have drawn great attention due to their wide applications in many fields of science and technology, such as water treatment,biomedical engineering, and nanomaterials.Nano bubblesexhibit unique characteristics; due to their minute size and high internal pressure, they can remain stable in water for prolonged periods of time. Nanobubbles can be created whengold nanoparticlesare struck by short laser pulses. The short-lived bubbles are very bright and can be made smaller or larger by varying the power of the laser. Because they are visible under a microscope, nanobubbles can be used to either diagnose sick cells or to track the explosions that are destroying them.
Natural productshave been used in medicine for many years. Many top-sellingpharmaceuticalsare natural compounds or their derivatives.. And plant- or microorganism-derived compounds have shown potential as therapeutic agents against cancer, microbial infection, inflammation, and other disease conditions. Natural products had huge success in the post-World War II era as antibiotics, and the two terms have become synonymous.While large pharmaceutical companies have favored screening synthetic compound libraries for drug discovery, small companies have started to explore natural products uses against cancer, microbial infection, inflammation, and other diseases.The incorporation of nanoparticles into a delivery system for natural products would be a major advance in the efforts to increase their therapeutic effects. Recently, advances have been made showing that nanoparticles can significantly increase the bioavailability of natural products bothin vitro and in vivo.
Nanoscience and nanotechnology are new frontiers of this century and food nanotechnology is an emerging technology. Food technology is regarded as one of the industry sectors where nanotechnology will play an important role in the future. The development of new products and applications involving nanotechnologies holds great promise in different industrial sectors, Nanotechnology may revolutionize the food industry by providing stronger, high-barrier packaging materials, more potentantimicrobial agents. Several possibilities exist to exploit the benefits of nanotechnologies during different phases of the food chain with the aim to enhance animal nutrition and health. Several complex set of engineering and scientific challenges in the food and bioprocessing industries for manufacturing high quality and safe food through efficient and sustainable means can be solved through nanotechnology. Bacteria identification and food quality monitoring using biosensors; intelligent, active, and smart food packaging systems; and Nanoencapsulationofbioactive food compoundsare few examples of emerging applications of nanotechnology for the food industry.
The main current applications of Nanotechnology for surgeons are in the areas of development of surgical implants using Nanomaterials, Imaging, Drug Delivery and development of Tissue Engineering products, such as scaffolds with enhanced materialcell interaction. An example of this is the development of a scaffold for delivery of stem cells to replace defective retinal pigmented epithelial cells in age-related Macular Degeneration. In Dentistry research has been done, liposomal Nanoparticles that contained collagenase and performed tests with them in rats, and found compared to conventional surgery, collagenase weakened the collagen fibers, making it easier to shift the teeth afterward with braces.
Nanoparticles with their unique size-dependent properties are at the forefront of advanced material engineering applications in several fields. Metals, non-metals, bio-ceramics, and manypolymeric materialsare used to produce nanoparticles of the respective materials. These are functional in producing liposomes, PEG and many more. Due to their small size nanoparticles has found to be interacting with human bodies same like of gases. Nanoparticles of the same composition can display behavioral differences when interacting with different environments. Nanoparticles can enter the human body via inhalation, ingestion, or skin contact. The range of pathologiesrelated to exposure tonanoparticles encompasses respiratoryand even several organs and leads to diseases. Accurate in vitro assessment ofnanoparticle cytotoxicityrequires a careful selection of the test systems. Due to high adsorption capacity and optical activity, engineered nanoparticles are highly potential in influencing classical cytotoxicity assays.
One of the exciting features of nanotechnology is its utility in the field of Nano medicine, therapeutics, and medical devices . When these small size materials are introduced into biological systems, their extremely small size and their unique Nano scale properties make it possible to use them as delivery vectors and probes for biological diagnostics,bioimagingand therapeutics. In fact, when size decreases, thesurface area to volume ratioof materials becomes very large, so that a vast suitable surface is available forchemical interactions withbiomolecules. This critically implied that nanotechnology is facing a transition into the tangible advancement ofhuman therapeutics. Recently, There are multiple clinical trials of nanomaterials have done; both for therapeutics and for medical devices.
Related conferences: Nanomedicine Conferences | Nanotechnology Events | Nano Healthcare Congress | Nanomedicine Meet | Nanoscience Event | Nanoengineering Conference | Tissue Engineering Meeting
Related Societies:
USA:International Organization of Materials, International Association of Nanotechnology, Graphene Stakeholders Association, Nano Science and Technology Institute (NSTI),NanoBusiness Commercialization Association, Alliance for Nanotechnology in Cancer,International association of nanotechnology,National Institute for Nanotechnology, Waterloo Institute for Nanotechnology, The Institute for Molecular Manufacturing (IMM),NanoBusiness Alliance, Nanotechnology and Nanoscience Student Association (NANSA),Nano Science and Technology Institute (NSTI),National Cancer Institute, National Nanotechnology Initiative,American Nano society, Metals and Minerals Societies, Society for Advancement of Material and process Engineering,American Composites Manufacturers Association, Brazilian Composites Materials Association,Canadian Biomaterials Society, American Institute of Aeronautics and Astronautics (AIAA).
Europe:International Union of Crystallography, European Nanoscience and Nanotechnology Association (ENNA),German Association of Nanotechnology, Nanotechnology Industries Association, The Institute of Nanotechnology (IoN), Nanotechnology Industries Association (NIA),Russian Society of Scanning Probe Microscopy and Nanotechnology, Society of Nanoscience and Nanotechnology, Federation of Materials Societies, Society for Biomaterials, Federation of European Materials Societies
Asia-Pacific & Middle East:Nano Technology Research Association (NTRA), Asian Nanoscience and Nanotechnology Association (ANNA), Nanoscience & Nanotechnology, ASPEN-Asian society of precision engineering and nanotechology, The International Association of Nanotechnology (IANT), Iran Nanotechnology Initiative Council (INIC), National Institutes of Health, Society of Materials Science, Japan Society for Composite Materials, Australasian Society for Biomaterials and Tissue Engineering, Australasian Ceramic Society, Materials Research Society, National Centre for Nanoscience and Technology.
Theme: Role of Nanotechnology in Humans life
Summary:
The field of Nanotechnology has recently emerged as the most commercially viable technology of this century because of its wide-ranging applications in our daily lives. Man-made Nanostructured materials such as fullerenes, nanoparticles, Nano powders, Nanotubes, Nanowires, Nanorods, Nano-fibers, Quantum dots, Dendrimers, Nano clusters, Nanocrystals, and Nanocomposites are globally produced in large quantities due to their wide potential applications, e.g., in skincare and consumer products, healthcare, electronics, photonics, biotechnology, engineering products, Pharmaceuticals, drug delivery, and agriculture. Many emerging economies such as Brazil, China, India, Iran, UAE, Malaysia, Mexico, Singapore and South Africa have ambitious research and development (R&D) plans for Nanotechnology.A group of scientists who have mapped out the uses of Nanotechnology and the needs of global health argue that Nano medicine is relevant for the developing world. They surveyed researchers worldwide and concluded that Nanotechnology could greatly contribute to meeting the Millennium Development Goals for health.
Importance and scope:
Nanotechnologyis becoming a crucial driving force behind innovation in medicine and healthcare, with a range of advances including Nano scale therapeutics, biosensors, implantable devices, drug delivery systems, and imaging technologies. Universities also have begun to offer dedicated Nano medicine degree programs (example:MSc program in Nanotechnology for Medicine and Health Care). Nanotechnology will be getting to be progressively prevalent these times Around learners. Actually, if you follow again of the Inception about nanotechnology, you will discover that Ayurveda need long been utilizing gold Also silver nanoparticles, known as bhasmas, to treat Different therapeutic ailments. Presently, nanotechnology may be generally utilized within huge numbers industries, going from cosmetics, agriculture, and materials should pharmaceutical Also human services. Nanomedicine may be the provision for nanotechnology for those diagnoses, detection, and medicine Also aversion of illnesses. Presently there need aid various items on the business that would the outcome from claiming nanotechnology. Talking for scratching the surface, we likewise have Nano auto wax that fills done the individuals minor cracks more successfully Furthermore provides for you a shinier vehicle. There need aid likewise Nano items accessible with stay with your eyewear What's more different optical units cleaner, dryer, What's more that's only the tip of the iceberg tough.
Conference highlights:
Why in Abu Dhabi?
Abu Dhabi is the federal capital and centre of government in the United Arab Emirates sits off the mainland on an island in the Persian (Arabian) Gulf. It is the largest city of the Emirate of Abu Dhabi and one of the most modern cities in the world. It is a well-ordered, industrious city with a pretty waterside location. Innovative Nano Technology LLC was founded in the beginning of 2016 in Al Ain City, Abu Dhabi, United Arab Emirates. It was established with the goal of taking a leading role in the field of Nano Technology Based Coatings, and is considered as one of the first Companies who offer the new Nano technology based Coatings in the region.
Why to attend?
United Arab Emirates has a number of universities that offer research and educational opportunities in nanotechnology. United Arab Emirates University, The first and foremost comprehensive National University in the United Arab Emirates. eFORS office is the University consultancy office within the college of engineering that deals with several science and technology issues including Biochemical and Biopharmaceutical Processes and Bioengineering and Nanotechnology. Reports released during October 2012 revealed that the worlds second largest foundry, Globalfoundries has agreed to partner with Masdar Institute to develop Abu Dhabi as a centre for semiconductor R&D and manufacturing excellence. In September, the company allowed students and professors to use its technology facilities at its Abu Dhabi branch. The facilities have a laboratory-like environment with powerful production servers, engineering work stations and a high-speed data network that can be used for enabling remote access to very advanced nanotechnology engineering systems
Technology domains of patent applications in UAE
This graph shows the global Nanomedicine market size, measured in terms of revenues, such as sales revenues, grants revenues, and milestones. From2006to date, a steady growth has occurred, which is expected to continue through2014, at aCAGRof13.5% [BCCResearch, Nanotechnology in Medical Applications. The drug delivery market is the largest contributing application segment, whereas biomaterials are the fastest growing application area in this market. Nanomedicine accounts for77Marketed Products Worldwide, representing an Industry with an estimated market $249.9Billion by2016[ETPNdata,BCC].
Globally, the industry players would centering essentially once R&D to get Regard for Different clinical trials for future Nanodrugs with a chance to be economically accessible in the business sector. If a chance to be generally arranged for exactly of the most punctual What's more The greater part essential requisitions of Nano medicine for regions for example, gene treatment and tissue building. The a greater amount propelled requisitions for Nano medicine will pose interesting tests As far as order Furthermore support about exploratory dexterity.
Nano medicine market :
Nano-enabled medical products beganappearing on the market over a decade ago and some have become best-sellers in theirtherapeutic categories. The main areas in which Nanomedical products have made animpact are cancer, CNS diseases, cardiovascular disease, and infection control. At present, cancer is one of the largesttherapeutic areas in which Nano-enabled products have made major contributions; theseinclude Abraxane, Depocyt, Oncospar, Doxil,and Neulasta. Cancer is a prime focus forNano pharmaceutical R&D, and companieswith clinical-stage developments in this fieldinclude Celgene, Access, Camurus, andCytimmune. Treatments for CNS disorders includingAlzheimers disease and stroke also feature prominently in Nano therapeutic research,seeking to build on achievements already posted by products such as Tysabri, Copazone,and Diprivan. According to BCC Research,this is a field hungry for successfultherapeutic advances and annual growth fromexisting and advanced pipeline products isexpected to reach 16% over the next 5 years.
Nanotechnology Companies in Asia and Middle East:
Nano Congress 2017
We gratefully thank all our wonderful Speakers, Conference Attendees, Students, Media Partners, Associations and Sponsors for making Nano Congress 2017 Conference the best ever!
The19thNano Congress for Next Generation, hosted by the ME Conferences was held duringAugust 31- September 01, 2017atBrussels, Belgiumbased on the themeNext Generation Nanotechnology Concepts Methodologies Tools and Applications". Benevolent response and active participation was received from the Organizing Committee Members along with Scientists, Researchers, Students and leaders from various fields of Nanotechnology who made this event a grand success.
ME Conferences expresses its gratitude to the conference Moderator,namelyDr.Dominique Ausserrefor taking up the responsibility to coordinate during the sessions. We are indebted to your support.
Similarly we also extend our appreciation towards our Poster judge namely,Dr. Arturs Medvids.
The conference was initiated with theHonorable presenceof theKeynote forum. The list includes:
The meeting reflected various sessions, in which discussions were held on the following major scientific tracks:
Nano Materials Synthesis and Characterisation
Nano Photonics
Molecular Nanotechnology
Nanotechnology and Cosmetics
Nanotechnology in Agriculture and Food Industry
Carbon Based Nano materials and Devices
Nanotechnology Safety
Nano Medicine and Nano Biotechnology
Nano Science and Technology
Nano Applications
Nano-electronics
Nano Biomaterials
Nano Biometric
Advanced Nanomaterials
Nano Technology in Tissue Engineering
Nanotech for Energy and Environment
Nano Computational Modelling
ME Conferences offers its heartfelt appreciation to organizations such asAllied Academies,Andrew John Publishing Inc.,New York private Equity Forum,Crowd Reviewsand other eminent personalities who supported the conference by promoting in various modes online and offline which helped the conference reach every nook and corner of the globe. ME Conferences also took privilege to felicitate the Keynote Speakers, Organizing Committee Members, Chairs and sponsors who supported this event
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Nanomedicine Conferences | Nanotechnology Events ...
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The Promise of Nanomedicine – Laboratory Equipment
Posted: July 23, 2018 at 9:42 am
More than a decade ago, nanotechnology became an integral part of the overall scientific research world. Governments started funding programs specifically aimed at nanotechnology, research universities opened their facilities and coursework to the new discipline, and journals focusing on nano research became commonplace.And now, many researchers believe, its nanomedicines turn to do the same. Nanomedicinewhich has emerged as nanotechnologys most important sub-disciplineis the application of nanotechnology to the prevention and treatment of disease in the human body. It is already having an impact clinically among some of the deadliest diseases in the world.
Nanomedicine is far from the stuff of science fiction. The possibilities for nanomedicine to help us diagnose, treat and image diseases are endless. Imagine a smart nanomedicine that is able to bind to tumor cells and enhance imaging and diagnosis, at the same time as being able to deliver a gene therapy or chemotherapy agent. With the technologies available to us and our multidisciplinary teams, this will be possible in my lifetime, said Phoebe Phillips, head of the pancreatic cancer translational research group at the University of New South Wales in Sydney.
Phillips and her team have created a nanoparticle that dramatically increases its effectiveness as an anti-cancer drug for patients with pancreatic cancers, which is one of the fastest killing cancers from time of initial detection, often leaving patients with no suitable treatment options and only weeks to live.
While nanomedicine canand likely willplay a role in diagnostics, regenerative medicine, prosthetics and more, the effect the sub-discipline is currently having on the treatment of autoimmune diseases and cancers is significant.
Nanomedicine for HIVThirty years ago, a diagnosis of HIV/AIDS was essentially a guarantee of a painful, protracted death. It wasnt until 1996 that researchers discovered antiretroviral drugs, and the potent combination therapy that leads to successful management of HIV/AIDS in most cases. However, not much has changed since that discovery. Those suffering from the autoimmune disease still require daily oral dosing of three to four pills, and chronic oral dosing has significant complications that can arise from the high pill burden experienced by patients, leading to non-adherence to therapies for a variety of reasons.
Ive been working in HIV for over 20 years, Andrew Owen, professor of molecular and clinical pharmacology at the University of Liverpool (UK) told Laboratory Equipment. I was trying to understand the variability in drug exposure that occurs between different individuals and the genetic basis for that. We were finding a lot of interesting things, but they werent clinically implementable. They gave us a good understanding of why drug exposure was variable, but it didnt actually help the patients in any way.
In an attempt to solve the problem rather than just characterize it, Owen turned to nanomedicine in 2009, eventually becoming part of the first team to conduct human trials of orally dosed nanomedicines for HIV. Since then, Owen and his interdisciplinary team at the Liverpool Nanomedicine Partnership have secured more than 20 million of research funding for a multitude of nanomedicine-based approaches to HIV, such low-dose oral delivery, long-acting injectable medications and targeted delivery of antiretrovirals.
Some of Owens most important research to date tackles two of the pharmaceutical industrys biggest challenges: oral delivery of potent drugs and supply and demand.
One of the major problems that has plagued drug discovery and drug development over the last 30 years has been compatibility with oral drug delivery, Owen explained. The pharmaceutical industry has wrestled with that because they can develop very potent molecules across diseases, but actually delivering those molecules orally is very challenging. As you try to design into the molecule oral bioavailabilty, you usually get further away from the potency you want.
The Liverpool team solved this problem with the creation of Solid Drug Nanoparticles. The technology consists of combining a normal drug, in its solid form, with particles on that drug that are measurable within the nanometer scale. There are other things packed into the formulation as well, such as FDA-approved stabilizers that are proven to help disperse the drug. Owen says it is all about increasing the surface area covered by the drug.
If you imagine you take a granulated form of the drug, youre going to get big chunks of drugs in the intestinal tract when dissolution happens. But if you have nanometer-sized particles within the GI tract, then you are going to get a complete coating of the inside of the intestine after you take the drug, Owen explained. What that does is it massively increases the surface area covered by the drug, which saturates all sorts of drug influx processes within the GI tract.
Since 80 percent of a humans immune system is concentrated in the gut, the Solid Drug Nanoparticles are the perfect mechanism. The immune cells in the gut instinctually move toward the particles, creating a pathway for the drugs to cross the intestines, move through the lymphatic system, and finally into the systematic circulation.
In February, Owen presented the results of two trials at the Conference on Retroviruses and Opportunistic Infections (CROI) that confirmed his Solid Drug Nanoparticles can be effective at a 50 percent dose reduction. Specifically, Owen and his team applied the nanomedicine-based approach to the formulation of two drugs: efvirenz (EFV) and lopinavir (LPV). EFV is the current WHO-recommended regimen, with 70 percent of adult HIV patients in low- and middle-income countries taking the medication. At 50 percent of the dose, the patients in the trial were able to maintain plasma concentrations of the conventional dose.
Globally, the supply of drugs needed to treat every patient with HIV is outstripping manufacturing capabilitymeaning we, as a human species, cannot physically make enough HIV medication to treat everyone with the disease. A 50 percent reduction in dose means twice as many patients served with the existing drug supply.Owen and his team are working with multiple global partners to move the technology forward. For the drugs already formulated, the Medicines Patent Pool and Clinical Health Access are helping to scale up and take them to market. Meanwhile, USAIDs Project OPTIMIZE is applying the nanoparticle technology to the newest HIV drugs for use in low- and middle-income countries.
For their latest collaboration with Johns Hopkins University, the Liverpool team was just awarded $3 million to examine the use of implantable technologies that can deliver drugs for weeks, or even months.
The current oral drug regimens for HIV comprises three drugs in combinationone is the major driver for efficacy, and the other two are nucleoside reverse transcriptase inhibitors that prevent resistance to the main drug. However, current injectable formulations are only available with the main drugnone include the nucleoside reverse transcriptase inhibitors.
So, our project aims to develop the first long-acting injectable nucleoside reverse transcriptase inhibitors so that we can use them to have a fully long-acting regimen that matches the current clinical paradigm for therapy, Owen said.
The Liverpool/Hopkins team has also thought about applying their long-acting injectable technology to other chronic diseases, such as malaria and tuberculosis, as well as some cardiovascular applications.
Nanomedicine for diabetesWhen the nanoparticles he was working with as an imaging tool didnt produce the desired results, Pere Santamaria grew frustratedbut he didnt give up. Instead, the doctor and professor at the University of Calgary (Canada) changed his assumptions and pursued his experimentuntil the data came pouring in that confirmed it wasnt a failed experiment at all. Rather, it was a discovery.
The discovery of Navacims was a bit serendipitous, Santamaria told Laboratory Equipment. Thankfully I am a little OCD and I didnt let the failed experiment go.Navacims are an entirely new class of nanomedicine drugs that harness the ability to stop disease without impairing normal immunity. Santamaria has been studying Navacims for the past 17 years, ever since unintentionally developing them. He even started a spin-off company, Parvus Therapeutics, Inc., to help bring the drugs to market.
In autoimmune diseases, white blood cells, which are normally responsible for warding off foreign invaders and disease, turn on the body, attacking the good cells and causing their destruction. Each specific autoimmune disease results from an attack against thousands of individual protein fragments in the targeted organ, such as the insulin-producing pancreatic cells in the case of type 1 diabetes.
But Santamarias studies show that nanoparticles decorated with protein targets acting as bait for disease-causing white blood cells can actually be used to reprogram the cells to rightfully suppress the disease they once intended to cause.
Once the immune system recognizes the presence of a Navacim, a white blood cell is reprogrammed by epigenetic changes into a lymphocyte that no longer wants to cause tissue damage, but rather work to suppress disease. According to Santamaria, the reprogramming step is immediately followed by an expansion of that population of lymphocytesone now-good white blood cell dividing into a million.
Basically they turn the tables on the immune system, and then there is a very sophisticated series of downstream cellular events that arise from that reprogramming event that involves the recruitment of other lymphocytes and other cell types that completely suppress the inflammation in the organ that is being infected, Santamaria explained. This happens extremely efficiently and comprehensively. This is an approach that can efficiently, selectively and specifically blend a complex response without impairing basic immunity.
In addition, the design of Navacims is modular, meaning the nanomedicine can be applied to severalif not allautoimmune diseases, including multiple sclerosis and rheumatoid arthritis. Navacims can be altered to target different diseases by simply changing a small portion of the bait molecules on the nanoparticles. Santamarias studies have shown this to work in about seven autoimmune diseases thus far.
In April, Santamarias company Parvus entered into a license and collaboration agreement with Novartis for Navacims. Under the terms of the agreement, Novartis receives exclusive worldwide rights to use Parvus Navacim technology to develop and commercialize products for the treatment of type 1 diabetes, and will be responsible for clinical-stage development and commercialization. Parvus will still be responsible for conducting ongoing preclinical work in the diabetes area, with some research funding from Novartis.
Weve had such a long time to prove ourselves, that this is not a flash in the pan, that this is something serious and robust, Santamaria said. We know so much about the mechanisms of our actions, and so much granularity. I think there are no other drugs that have reached the clinic with this level of understanding. That was painful in the beginning for us, but in the end its going to be good.
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The Promise of Nanomedicine - Laboratory Equipment
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