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24th Annual Meeting on Nanomaterials Science, will be organized around the theme “An insight for the future of nanotechnology”

Nanomaterials-2019 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Nanomaterials-2019

Submit your abstract to any of the mentioned tracks.

Register now for the conference by choosing an appropriate package suitable to you.


<p style="\&quot;text-align:" justify;\"="">\r\n Nanoscale materials are a progressively significant product of nanotechnologies. Nanomaterials are forthcoming into use in healthcare, electronics, cosmetics and other areas. Their physical and chemical properties often varies from those of bulk materials, so they sound as specialized risk assessment. This needs a protection to workers and consumers, and environment from potential health risk. This is currently done on a case by case basis, but risk assessment methods need to be kept up to date as the use of nanomaterials expands, especially as they find their way into consumer products.


  • Track 1-1 Nanometric
  • Track 1-2 Nanopolymers
  • Track 1-3Nanoglasses
  • Track 1-4Nano ceramics
  • Track 1-5Biological nanomaterials
  • Track 1-6Quantum dots
  • Track 1-7Nanomaterials for data storage
  • Track 1-8Physico-chemical methods of nanostructured materials


<p style="\&quot;text-align:" justify;\"="">\r\n Nanostructures provide an interesting tool for studying the electrical, magnetic, optical, thermal, and mechanical properties of matter at the nanometer scale. On the practical side, nanostructures can provide significant improvements in the performance of electronic/optical devices and sensors. In addition, optical sources and detectors having nm-size dimensions exhibit improved characteristics not achievable in larger devices. These improvements create novel possibilities for next-generation computation and communication devices. In the sensors area, shrinking dimensions beyond conventional optical lithography can provide major improvements in sensitivity and selectivity.


  • Track 2-1The science of miniaturization
  • Track 2-2e-beam nanofabrication
  • Track 2-3Epitaxy and strain engineering
  • Track 2-4Scanning-probe techniques
  • Track 2-5Nanomanipulation and processing
  • Track 2-6Self-assembly and template manufacturing


<p style="\&quot;text-align:" justify;\"="">\r\n Bionanotechnology is an inter-disciplinary area of research that placed at the interface of chemistry, biology, materials science, engineering and medicine. The exploitation of the inherent properties of nucleic acid like DNA to create useful materials is a promising area of modern research. Proteins that self-assemble to produce functional materials could be used as an innovative method for the significant production of programmable nanomaterials. Also, virus like nanoparticle plays a very important role in bionanotechnology due to their monodisperse nature and biocompatibility. The major area of research in bionanotechnology are DNA bionanotechnology and Lipid bionanotechnology.  


  • Track 3-1Diagnosis
  • Track 3-2Drug delivery
  • Track 3-3Tissue engineering
  • Track 3-4Catalysis
  • Track 3-5Agriculture
  • Track 3-6Textiles
  • Track 3-7Cosmetics
  • Track 3-8Energy production


<p style="\&quot;text-align:" justify;\"="">\r\n A nanorobot is a tiny machine designed to accomplish a definite mission repetitively and with precision at nanoscale dimensions. Nanorobots have potential applications in the assembly and maintenance of classy systems. Nanorobots are of special interest to researchers in the medical industry.   Nanoscale systems can also function much faster than their larger counterparts because displacements are smaller; this allows mechanical and electrical events to occur in less time at a given speed.


  • Track 4-1Carbon nanohorns
  • Track 4-2Smart delivery agents
  • Track 4-3Robotic functionalities
  • Track 4-4Nonsystemic therapeutic delivery
  • Track 4-5Magnetic targeting
  • Track 4-6Magnetic resonance navigation (MRN)
  • Track 4-7Magnetic resonance navigation (MRN)
  • Track 4-8Magnetic carrier detection
  • Track 4-9Magnetic nanoparticles
  • Track 4-10Liposomes
  • Track 4-11Drug delivery systems
  • Track 4-12Molecular machines


<p style="\&quot;text-align:" justify;\"="">\r\n Nanotoxicology is defined as the study of the nature and mechanism of toxic effects of nanoparticles on living organisms and other biological systems. It also deals with the quantitative assessment of the severity and occurrence of nanotoxic effects relative to the exposure of the organisms. Human exposure routes for nanoparticles are mainly mediated through inhalation, dermal, oral intake or by injection. The small particle size and the shape of nanomaterial enables uptake into blood and lymph circulation and circulation to tissues in the body that normally are protected by barriers, such as the brain by penetration of the blood-brain-barrier (BBB).


  • Track 5-1Growth factor signaling
  • Track 5-2Inflammation
  • Track 5-3Necrosis
  • Track 5-4Nephrotoxicity
  • Track 5-5Freshwater toxicology
  • Track 5-6Nano-enabled agrochemicals
  • Track 5-7Engineered nanomaterials
  • Track 5-8Cytotoxicity and genotoxicity


<p style="\&quot;text-align:" justify;\"="">\r\n Nanotechnology is rapidly entering the world of smart materials and taking them to the next level. Smart materials are defined as materials with properties engineered to change in a controlled manner under the influence of external stimuli. Some of the external stimuli are temperature, force, moisture, electric charge, magnetic fields and pH. The self-assembly of peptides has enormous applications in the fields of medicine and electronics. Bio-inspired engineered systems have been designed based on the mechanistic perceptions obtained from natural systems for novel self-assembled structures.  In the biological system, each cell type is programmed to display different levels of smartness.


  • Track 6-1Biogenic nanoparticle
  • Track 6-2Stealth nanoparticle
  • Track 6-3Virosomes and virus like nanoparticle for gene delivery
  • Track 6-4Stimuli responsive smart nanosystems
  • Track 6-5Targeted nanodelivery systems
  • Track 6-6Neutron capture therapy for cancer
  • Track 6-7Photodynamic therapy
  • Track 6-8Nanoparticles for live cell dynamics
  • Track 6-9Capture based, cell based and tissue based sensors

Targeted drug delivery system is a special form of drug delivery system where the medicament is selectively targeted or delivered only to its site of action or absorption and not to the non-target organs or tissues or cells. It is a method of delivering medication to a patient in a manner that increases the concentration of the medication in some parts of the body relative to others. Targeted drug delivery seeks to concentrate the medication in the tissue of interest while reducing the relative concentration of the medication in the remaining tissues. This improves efficacy and reduce side effects.


  • Track 7-1Strategies of drug targeting
  • Track 7-2Nanotubes
  • Track 7-3Nanoshells
  • Track 7-4Nanowires
  • Track 7-5Quantum dots
  • Track 7-6Nanopores
  • Track 7-7Gold nanoparticle
  • Track 7-8Liposomes


<p style="\&quot;text-align:" justify;\"="">\r\n Nanotheranostics is a burgeoning field in recent years, which makes use of “nanotechnology” for diagnostics and therapy of different diseases. The advent of nanotheranostics is expected to benefit the pharmaceutical and healthcare industries in the next 5-10 years. Nanotechnology holds an immense potential to be explored as a multifunctional platform for a wide range of biological and engineering applications such as molecular sensors for disease diagnosis, therapeutic agents for the treatment of diseases, and a vehicle for delivering therapeutics and imaging agents for theranostic applications in cells and living animals.\r\n

  • Track 8-1Nanoparticle Platforms for Theranostics
  • Track 8-2Cancer Nanomedicine
  • Track 8-3Nanoprobes and Contrast Agents
  • Track 8-4Theranostics-Based Personalized Medicine
  • Track 8-5Nanosensors for Biomarker Detection
  • Track 8-6Molecular imaging
  • Track 8-7Fluorescence real-time imaging
  • Track 8-8Image-guided surgery
  • Track 8-9Magnetodynamic therapy


<p style="\&quot;text-align:" justify;\"="">\r\n Many whitening and antiaging cosmetic products apply various vitamin complexes and their derivatives, but not all products offer sufficient tangible results, as the corneum layer of the skin acts as a barrier that considerably reduces the absorption rate of the vitamins and other active ingredients. Apart from this, the vitamins are decomposed easily under ordinary conditions. The nanocosmetic technology can help these skin whitening and antiwrinkle/sagging applications, to nanosize the vitamin derivatives, amino acids, and other active ingredients, so that they can reach the target areas in a stable form, and sustain the pharmacological effect for a long time.


  • Track 9-1 Polymeric nanocapsules
  • Track 9-2Metallic nanoparticles
  • Track 9-3Lipid nanoparticle as carrier for cosmetic ingredients
  • Track 9-4Elastic liposomes
  • Track 9-5Druggable Targets for Skin Photoaging


<p style="\&quot;text-align:" justify;\"="">\r\n A nanocomposite is a multiphase durable material where one of the stage as one, a few measurement of under 100nm, or structures having nanoscale rehash contrast between the distinctive stages that make up the material. It comprises of at least one irregular stages which appropriated in one nonstop stage where persistent stage is called "grid" while spasmodic stage is called "support" or "fortifying material". The nanocomposites is grouped into polymer based and non-polymer based nanocomposite. It has a wide application in electrocatalyst in batteries for vitality sparing, lite weight material for less fuel utilization, in counterfeit joints, marine application, scraped spot and wear application. 


  • Track 10-1Dental nanocomposites
  • Track 10-2Polymer nanocomposites
  • Track 10-3Chitosan nanocomposite
  • Track 10-4Optic adjustment
  • Track 10-5Photochromism
  • Track 10-6Nanocomposite and their applications


<p style="\&quot;text-align:" justify;\"="">\r\n Nanosensor is a very tiny device which is capable of detecting and responding to any physical stimuli with dimensions of less than 100nm. Nanosensors are any chemical, biological or surgical parts that is used to convey information about nanoparticles to the macroscopic world. The use of nanosensors mainly involves various medicinal purposes and as gateways to building other nanoproducts, such as computer chips that work at the nanoscale and nanorobots. Currently, there are many ways proposed to make nanosensors, including top-down lithography, bottom-up assembly, and molecular self-assembly.


  • Track 11-1Molecular self-assembly
  • Track 11-2Metal nanoparticle based sensor
  • Track 11-3Quantum dot sensor
  • Track 11-4Nanowire based sensor
  • Track 11-5Carbon nanotube based sensor
  • Track 11-6Sensors based on nanostructures of metal oxide
  • Track 11-7Sensors based on polymeric nanostructures
  • Track 11-8Optical Sensors

\r\n Biomedical nanotechnology is one of the fastest growing fields of research across the globe. In terms of products for use inside the human body, nanotechnology-based applications for anticancer drugs, implanted insulin pumps, and gene therapy are being developed, while other researchers are working on prostheses and implants which contain nanostructured materials. Carbon nanotubes might be useful as drug delivery vehicles inside or on the surface of the human body. Cosmetics based on quantum dots (3-5 nm) as well as nano-crystalline materials such as zinc oxide, for use in advanced sunscreens, are also available.

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  • Track 12-1Trends in biomedical nanotechnology
  • Track 12-2Diagnostics
  • Track 12-3Nanodrugs
  • Track 12-4Prostheses and implants
  • Track 12-5Potential risk


<p style="\&quot;text-align:" justify;\"="">\r\n Forensic science mainly deals with identification, evaluation, investigation of the crime, finding connections between pieces of evidence and perpetrators. Nanotechnology has been increasingly proven to be a powerful tool in a number of areas including medicine, imaging, and energy sciences. Nanotechnology may have a potential to make efficient positive involvement in forensic drug detection to solve crimes. It was theorized that the nanoparticles and chemically modified nanoparticles may alter or enhance the spectroscopic signals of forensic drugs in fingerprint samples. Nanoparticle has unique and unified nanostructures that may specifically interact with forensic drugs via their well-controlled nanostructures.


  • Track 13-1Finger print development
  • Track 13-2DNA sequencing
  • Track 13-3Forensic toxicology
  • Track 13-4 Drug identification
  • Track 13-5Trace evidence analysis
  • Track 13-6Fiber and hair analysis


<p style="\&quot;text-align:" justify;\"="">\r\n The meaning of nanofood is that nanotechnology methods or apparatuses are utilized amid development, creation, preparing, or bundling of the nourishment. It doesn't mean molecularly adjusted sustenance or nourishment created by nanomachines. Nanotechnologists are more idealistic about the possibility to change the current arrangement of sustenance handling and to guarantee the wellbeing of nourishment items, making a solid nourishment culture. They are additionally cheerful of upgrading the nutritious nature of sustenance through chose added substances and changes to the way the body processes and assimilates nourishment.  


  • Track 14-1Risk and safety assessment
  • Track 14-2Food regulatory system
  • Track 14-3Genetic modification
  • Track 14-4Nutraceuticals
  • Track 14-5Nanoencapsulation
  • Track 14-6Nanostructure lipid carrier
  • Track 14-7Food processing
  • Track 14-8Nanopackaging


<p style="\&quot;text-align:" justify;\"="">\r\n The use of nanotechnology to human social insurance, offers various potential pathways to enhancing therapeutic determination and treatment and even to recover tissues and organs. It can totally change the human services segment for the people to come. Nanotechnology will help medicinal experts in the present most intense therapeutic issues, for example, repairing of harmed organs, conclusion and treatment of disease cells, expulsion of obstacle in cerebrum and it can help in better medication conveyance framework. Nanotechnology can be utilized for both in vivo and in vitro biomedical research and applications. Nano particles can be utilized as a part of focusing on tumor cells at beginning stage. Nanotechnology can be utilized to create ''signature protein'' to treat tumor.  


  • Track 15-1Nanomedicine
  • Track 15-2Nano tweezers
  • Track 15-3Antimicrobials
  • Track 15-4Scaled down tests for perceiving ailment
  • Track 15-5Twisted care at the nano scale
  • Track 15-6Nano-specks that follow ailment
  • Track 15-7Enhanced discovery through therapeutic imaging


<p style="\&quot;text-align:" justify;\"="">\r\n Neuroengineering focuses on the development of artificial devices and novel materials to be functionally and structurally interfaced with the central nervous system (CNS). Today, there is the expectation that materials science and nanotechnology will be able to address these challenges and lead to breakthroughs at the level of the interfaces between artificial transducers/actuators and living cells. Nanoparticles are able to penetrate the BBB of in vitro and in vivo models; and therefore can be used to develop diagnostic tools as well as nano-enabled delivery systems that can bypass the BBB in order to facilitate conventional and novel neurotherapeutic interventions such as drug therapy, gene therapy, and tissue regeneration.


  • Track 16-1Up-take mechanisms of nanoparticles into brain
  • Track 16-2Advances in the treatment of Alzheimer’s disease with nanoparticle
  • Track 16-3Advances in the treatment of Parkinson’s disease with nanoparticle
  • Track 16-4Advances in the treatment of huntington disease with nanoparticle
  • Track 16-5Advances in the treatment of vascular dementia disease with nanoparticle
  • Track 16-6 Advances in the treatment of lewd body dementia disease with nanoparticle
  • Track 16-7Advances in the treatment of frontotemporal disease with nanoparticle
  • Track 16-8Current and future development


<p style="\&quot;text-align:" justify;\"="">\r\n The implementation of nanotechnology poses unknown risks which are difficult to assess with respect to their impact on the environment, human health, ethical, legal and societal issues. Nanomaterials are already released into the environment because of their small dimensions nanomaterials can be largely distributed within the environment in water streams, soil and air. The absorption of nanoparticle in human body is mediated through skin, lung, gastro-intestinal tract. They are distributed within the whole organism via blood and lymphatic systems. Also ideals like toxic particles that can go everywhere and self-replicating nanorobots can produce fear and uncertainty in the broad public and can lead to severe societal problems.


  • Track 17-1Risk assessment
  • Track 17-2Toxicology
  • Track 17-3Safety evaluation of nanomaterials
  • Track 17-4Global safety governance
  • Track 17-5 Conceptual framework


<p style="\&quot;text-align:" justify;\"="">\r\n Sustainable nanotechnology is the development of science and technology within the 1 – 100 nanometer scale, with considerations to the long-term economic viability and a sensible use of natural resources, while minimizing negative effects to human health and the environment. Potential negative effects may be caused by engineered nanomaterials or by anthropogenic changes in the prevalence of naturally occurring nanomaterials. Nanotechnology offers substantial prospects for the development of innovative products and it is expected that the number of nanotechnology-based products will increase in the future.  


  • Track 18-1Risk assessment
  • Track 18-2Decision analysis
  • Track 18-3Decision analysis
  • Track 18-4Nanomanufacturing
  • Track 18-5Preservation
  • Track 18-6Nanoengineered solutions


<p style="\&quot;text-align:" justify;\"="">\r\n Explanatory science is frequently depicted as the range of  science in charge of portraying the arrangement of issue, both subjectively and quantitatively. Generally scientific experts routinely make subjective and quantitative measurements. Analytical scientists ordinarily work at the extraordinary edges of examination, broadening and enhancing the capacity of all scientific experts to make important estimations on littler examples, on more mind boggling tests, on shorter time scales, and on species exhibit at bring down focuses. There are a wide assortment of procedures utilized for examination, from basic weighing (gravimetric investigation) to titrations (titrimetric) to extremely progressed procedures utilizing profoundly specific instrumentation. There are numerous more methods that have particular applications, and inside each major expository procedure there are numerous applications also, varieties of the general procedures.


  • Track 19-1Kinetic method of analysis
  • Track 19-2Electrophoretic methods
  • Track 19-3 Hyphenated techniques
  • Track 19-4Titrimetric techniques
  • Track 19-5Chromatographic techniques
  • Track 19-6Spectroscopic techniques


<p style="\&quot;text-align:" justify;\"="">\r\n Nanotechnology and biomedical medications utilizing undeveloped cells, (for example, remedial cloning) are among the most up to date veins of biotechnological examine. Foundational microorganisms (SCs) are undifferentiated cells in charge of the development, homeostasis and repair of many tissues. The support and survival of SCs is emphatically impacted by a few jolts from the neighborhood microenvironment. The greater part of flagging atoms associate with SCs at the nanoscale level. Hence, platforms with surface nanostructures have potential applications for SCs and in the field of regenerative solution.  


  • Track 20-1Tracking or labelling
  • Track 20-2Scaffold or platforms
  • Track 20-3Imaging and visualization
  • Track 20-4Nucleotide Delivery for Genetic Control
  • Track 20-5Nanoparticle Toxicity to Stem Cells
  • Track 20-6Regenerative medicine


<p style="\&quot;text-align:" justify;\"="">\r\n Nanophotonics is defined as the science and engineering of light matter interactions that take place on wavelength and subwavelength scales where the physical, chemical or structural nature of natural or artificial nanostructured matter controls the interactions. Nanophotonics researchers pursue a very wide variety of goals, in fields ranging from biochemistry to electrical engineering. 


  • Track 21-1Quantum confined materials
  • Track 21-2Photonic crystals
  • Track 21-3Plasmonics
  • Track 21-4Near field optics
  • Track 21-5Nanophotonic fabrication
  • Track 21-6Nanobiophotonics