Call for Abstract

International Summit on Nanotechnology and Medical Robots, will be organized around the theme “Advancements of Super Artificials in Medicine”

medicalrobots-2017 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in medicalrobots-2017

Submit your abstract to any of the mentioned tracks.

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

Nanotechnology is the engineering of efficient structures at the molecular scale. This protections both existing work and concepts that are more innovative in its original sense. Nanotechnology as demarcated by size is unsurprisingly very broad, containing fields of science as diverse as surface science, organic chemistry, molecular biology, semiconductor physics, micro fabrication, molecular engineering. The related research and applications are similarly diverse, fluctuating from extensions of conventional device physics to totally new methods based upon molecular self-assembly, from emerging new materials with measurements on the Nano scale to straight regulator of matter on the atomic scale.

  • Track 1-1Carbon nanotechnology
  • Track 1-2Exposure Scenarios
  • Track 1-3Nanomagnetics
  • Track 1-4Nanospinitronics
  • Track 1-5Nanostructured Metals;Manufacturing and Modeling
  • Track 1-6Biogenic Nanoparticles
  • Track 1-7Non Linear Optical Microscopy
  • Track 1-8Quantam field Model for Graphene Magnetism
  • Track 1-9Nano Bio Technology

Nanorobotics is an developing technology field manufacture machines or robots which mechanisms are at or near the scale of a nanometre. More precisely, nanorobotics refers to the nanotechnology engineering discipline of deceitful and erection nanorobots, with devices vacillating in size from micrometres and constructed of nanoscale or molecular modules. The terms nanobot, nanoid, nanite, nanomachine, or nanomite have also been used to describe such devices at present beneath research and improvement and even a large machine such as an atomic force microscope can be deliberated a nanorobotic instrument when configured to perform nanomanipulation.

  • Track 2-1Swarm Robotics
  • Track 2-2Industrial Robot
  • Track 2-3Nano Robotics Design and Control
  • Track 2-4 Biochips
  • Track 2-5Rehabilitation Robotics
  • Track 2-6Biorobotics
  • Track 2-7Telerobotics
  • Track 2-8Pharmacy Automation

Nanomedicine is the medical application of nanotechnology. Nanomedicine varieties from the medical solicitations of nano materials and  biological devices, to nanoelectronic biosensors, and even potential future applications of molecular nanotechnology such as biological machineries. Current snags for nanomedicine implicate appreciative the issues related to toxicity and environmental impression of nanoscale materials. Nanomedicine seeks to deliver a cherished set of research tools and clinically worthwhile devices in the near future.The National Nanotechnology Initiative expects new viable applications in the pharmaceutical industry that may contain innovative drug delivery systems, new therapies, and in vivo imaging.

  • Track 3-1Nanotechnology for Drug Delivery and Gene Delivery
  • Track 3-2Blood purification
  • Track 3-3Regenerative Nanomedicine
  • Track 3-4Chemotherapy via Nano particles
  • Track 3-5Drug Delivery in Cancer Treatment
  • Track 3-6Nanomedicine for Cardiovascular Diseases
  • Track 3-7Nanomedicine for CNS
  • Track 3-8Nanomedicine for Lung Diseases
  • Track 3-9Nanomedicine for Gastrointestinal Tract (GI) Diseases
  • Track 3-10Future aspects of Nanomedicine

Robotic surgery, or robot-assisted surgery, allows doctors to perform many types of complex procedures with more precision, flexibility and control than is possible with conventional techniques. Robotic surgery is usually associated with minimally invasive surgery procedures performed through tiny incisions. It is also sometimes used in certain traditional open surgical procedures

Robots are currently used not just for prostate surgery, but for hysterectomies, the removal of fibroids, joint replacements, open-heart surgery and kidney surgeries. They can be used along with MRIs to provide organ biopsies. Since the physician can see images of the patient and control the robot through a computer, he/she does not need to be in the room, or even at the same location as the patient.

This means that hospitals must evaluate the cost of the machine vs. the cost of traditional care. If robotic surgery cuts down on the trauma and healing time, there is money saved in terms of the number of days the patient stays in the hospital.

There is also a reduction in the amount of personnel needed in the operating room during surgery.

  • Track 4-1Coronary artery Bypass
  • Track 4-2Neurosurgery
  • Track 4-3Gynecology
  • Track 4-4Gastrointestinal Surgery
  • Track 4-5Colon and Rectal Surgery
  • Track 4-6Cardiology and Electrophysiology
  • Track 4-7Cardiothoracic Surgery
  • Track 4-8Tubal ligation
  • Track 4-9Radical Cystectomy
  • Track 4-10Radical Prostatectomy
  • Track 4-11Pyeloplasty
  • Track 4-12Hysterectomy
  • Track 4-13Gallbladder Removal
  • Track 4-14Kidney Transplant
  • Track 4-15Hip Replacement
  • Track 4-16Nerves or Important Body Organs
  • Track 4-17Ophthalmology

Molecular nanotechnology is a technology based on the knack to build structures to multifaceted, atomic conditions by means of mechanosynthesis. This is individual from nanoscale materials. Molecular  Nanotechnology  a technological insurrection which seeks nothing less than perfectibility. Molecular industrialized technology can be clean and self-contained. Molecular Nano manufacturing will slowly renovate our association towards matter and molecules as clear as the computer changed our correlation to information and bits. It will help accurate, economical control of the structure of matter. Molecular nanotechnology would involve relating physical principles revealed by biophysics, chemistry, other nanotechnologies, and the molecular machinery of life with the systems engineering standards found in modern macroscale plants.

  • Track 5-1Positional Assembly
  • Track 5-2 Atom Manipulation
  • Track 5-3Nano Tweezers
  • Track 5-4Nano Manipulator
  • Track 5-5Scanning Tunneling Microscope
  • Track 5-6Scanning Probe Microscopy Atomic Force Microscope
  • Track 5-7Modern Transmission of Electron Microscope
  • Track 5-8Scanning Electron Microscope
  • Track 5-9Electron Microscope
  • Track 5-10Atoms by Inference
  • Track 5-11Molecular Manufacturing
  • Track 5-12Molecular electronics
  • Track 5-13Microelectromechanical devices
  • Track 5-14Massive Parallelism
  • Track 5-15Nanodots

DNA nanotechnology is a division of nanotechnology apprehensive with the design, study and solicitation of synthetic structures based on DNA. DNA nanotechnology takes improvement of the physical and chemical assets of DNA rather than the genetic information it brings DNA nanotechnology is the design and creation of artificial nucleic acid edifices for technological uses. In this field, nucleic acids are secondhand as non-biological engineering materials for nanotechnology rather than as the carriers of genetic evidence in living cells. Investigators in the field have created static structures such as two- and three-dimensional crystal lattices, nanotubes, polyhedra, and arbitrary shapes, and serviceable devices such as molecular machineries and DNA computers. The field is beginning to be used as a gismo to elucidate basic science problems in structural biology and biophysics, including applications in X-ray crystallography and nuclear magnetic reverberation spectroscopy of proteins to determine structures. Potential solicitations in molecular scale electronics and nanomedicine are also being scrutinized.

  • Track 6-1Structural DNA Nanotechnology
  • Track 6-2Dynamic DNA Nanotechnology
  • Track 6-3Structural and Sequence Designing
  • Track 6-4 DNA Origami
  • Track 6-5DNA Polyhedral

A standout amongst the most encouraging nanotechnology fields is Nanopharmaceuticals. Since nanomaterials might enter the body through dermal presentation, inward breath, ingestion, or visual contact, they loan themselves to inventive medication conveyance frameworks. Pharmaceutical examination, toxicology thinks about, definition, and assembling of pharmaceutical items require material portrayal to guarantee reliable medication security and viability Nanoscale pharmaceutical procedures in medication revelation and advancement outline and improvement of Nano formulations and nanoscale drug conveyance frameworks, administrative viewpoints and approaches identified with nanopharmaceuticals

  • Track 7-1Nano Pharmaceuticals as New Drug Delivery Systems
  • Track 7-2Recombinant Nano Particles
  • Track 7-3Drug Delivery Systems
  • Track 7-4Pharmaceuticals at Nano scale
  • Track 7-5 Nanobiology

In the nourishment business, nanotechnology is being utilized to make better bundling and more beneficial sustenance. For instance, analysts are taking a shot at making sustenance bundles implanted with modest materials particularly intended to ready buyers that an item is no more drawn out safe to eat.

  • Track 8-1Nanotechnology In Food Microbiology
  • Track 8-2Nanotechnology and Risk Assessment
  • Track 8-3Nanotechnology in Agriculture Industry
  • Track 8-4 Nanotechnology in Food Industry
  • Track 8-5Nanotechnology for Controlled Release
  • Track 8-6Nanotechnology Research Agriculture and Food Industry
  • Track 8-7Potential for Regulatory Control
  • Track 8-8Regulatory Approaches to Nanotechnology In The Food Industry

The use of nanotechnology and nanomaterial’s is found in numerous corrective items which incorporates lotions, hair mind items, make up and sunscreen. The first of these is the utilization of nanoparticles as UV filters. zinc oxide and Titanium dioxide are the principle mixes utilized as a part of these applications. Natural contrasting options to these have additionally been created.

  • Track 9-1Cosmetic Formulation
  • Track 9-2Nanocosmetics Company Survey
  • Track 9-3Nanotechnology Cosmeceuticals: Benefits vs Risks
  • Track 9-4Safety of Nanomaterials in Cosmetic Products
  • Track 9-5Cosmetic Regulation Safety Assessment
  • Track 9-6 Present Position of Nanotechnology and Cosmetic Products

Nanomedicine is the nursing, repair, manufacture, and control of human biological organisms at the molecular level using engineered nanodevices and nanostructures Yeast cells were developed under various disorders; the amount of red or yellow light represents the level of RNA produced from the DNA in that gene, under those conditions. The ageing inhabitants, the high expectations for better quality of life and the changing lifestyle of European society call for improved, more efficient and affordable health care. Nanotechnology can offer notable firmness, when applied to medical experiments like cancer, diabetes, Parkinson's or Alzheimer's disease, cardiovascular problems, inflammatory or infectious diseases

  • Track 10-1Cell repair Machines
  • Track 10-2Drug Delivery
  • Track 10-3Correcting Genetic Disorders
  • Track 10-4Anesthesia plus
  • Track 10-5Immune Machines

Nanotoxicology is the study of the toxicity of nanomaterials. Because of quantum size effects and large surface area to volume ratio, nano materials have unique properties compared with their larger counterparts. Nanotoxicology is a branch of bionanoscience which deals with the study and application of toxicity of nanomaterials. Nanomaterials, even when made of inert elements like gold, become highly active at nanometer dimensions. Nanotoxicological studies are intended to determine whether and to what extent these properties may pose a threat to the environment and to human beings. For instance, Diesel nanoparticles have been found to damage the cardiovascular system in a mouse model.

  • Track 11-1Toxicity of Nanomaterials
  • Track 11-2Complications with Nanotoxicity Studies
  • Track 11-3Tolerogenic Nanoparticles
  • Track 11-4Medical Toxicology
  • Track 11-5Computational Toxicology
  • Track 11-6Occupational Toxicology
  • Track 11-7 Immunotoxicity
  • Track 11-8Cytotoxicity
  • Track 11-9Ecotoxicology
  • Track 11-10Genotoxicity
  • Track 11-11Regulation and risk Management

Nanotechnology is impacting the arena of consumer goods, several products that integrate nanomaterials are already in a variety of items; many of which people do not even realize contain nanoparticles, products with fresh functions ranging from easy-to-clean to scratch-resistant. Samples of that car bumpers are made lighter, clothing is more stain repellant, sun cream is more energy resistant, synthetic bones are stronger, cell phone screens are lighter weight. Nanotechnology applications are currently being researched, tested and in some cases already applied across the entire spectrum of food technology, from agriculture to food processing, packaging and food supplements. In our special Food Nanotechnology section we have prepared an overview of this area.

  • Track 12-1Aerospace and Vehicle Manufacturers
  • Track 12-2Surfaces and Coatings
  • Track 12-3 Nanofoods
  • Track 12-4Nanotechnology in the Oil & Gas Industry
  • Track 12-5Nanotechnology in Chemical Industry
  • Track 12-6Nanotechnology in Construction Industry

Nano electronics are based on the application of nanotechnology in the field of electronics and electronic components. Nano electronics and nanotechnology are widely used in all application of modern life. Life Safety, Healthcare, Transportation, Energy and Telecommunications and computing are the major fields benefiting from the growth of Nano electronic applications. Latest specialist ventures around 18 in gadgets ventures and 22 in material are in procedure, a yearly spending plan of $20,000 million is been supported to Nanotechnology organizations. The applications include in Nano gadgets, Reasonable and renewable vitality, common and mechanical designing, marine and resistance.

  • Track 13-1Advanced MOS devices
  • Track 13-2Metals, Semiconductors and Junction Devices
  • Track 13-3Nano Silicon and Silicon Microelectronics
  • Track 13-4Molecular Electronics and Nano Devices
  • Track 13-5Nanostructured Photoelectric Materials, Devices and Systems
  • Track 13-6Quantum Dot, Quantum Wire, Quantum Well
  • Track 13-7NEMS, MEMS and Nano Fluidics Devices
  • Track 13-8Vacuum Nanoelectronics
  • Track 13-9Organic and Molecular Electronics
  • Track 13-10Nanometer Optoelectronic Devices

There are a few advantages of utilizing miniaturized scale and nanofabrication methods for tissue building . Nanotechnology can be utilized to make Nanofibers, Nanopatterns and controlled-discharge nanoparticles with applications in tissue designing, for emulating local tissues since biomaterials to be built is of nanometre size like extracellular liquids, bone marrow, heart tissues and so on.

  • Track 14-1 Tissue Engineering
  • Track 14-2Nanotechnology and Tissue Engineering
  • Track 14-3 Applications of Nanotechnology In Stem Cell Research
  • Track 14-4Nano biotechnology: From Stem Cell, Tissue Engineering to Cancer Research
  • Track 14-5 Regulation on Advanced Therapy Medicinal Products/ Tissue Engineering

Nanotechnology is also being applied to or developed for application to a variety of industrial and purification processes. Purification and environmental cleanup applications include the desalination of water, water filtration, wastewater treatment, groundwater treatment, and other Nano remediation. In industry, applications may include construction materials, military goods, and nano-machining of nano-wires, nano-rods, few layers of graphene, etc. Also, recently a new field arisen from the root of Nanotechnology is called Nanobiotechnology. Nanobiotechnology is the biology-based, application-oriented frontier area of research in the hybrid discipline of Nanoscience and biotechnology with an equivalent contribution. Nanotechnology is applicable in medicine, electronic, fuel cell, solar cell and food technology.

  • Track 15-1Nanomaterials in Food and Agriculture Industry
  • Track 15-2Nanomaterials in Textile and Fiber
  • Track 15-3Nanomaterials in Nano Coating, Nano Adhesives
  • Track 15-4Nano printing and Nano packaging
  • Track 15-5Nanotechnology in Information Technology
  • Track 15-6Nanotechnology in Bioinformatics