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10th International Conference & Exhibition on Biosensors & Bioelectronics, will be organized around the theme “Research, Design, Development, and Application of Biosensors and Bioelectronics”

Biosensors & Bioelectronics 2018 is comprised of 14 tracks and 92 sessions designed to offer comprehensive sessions that address current issues in Biosensors & Bioelectronics 2018.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

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A biosensor is an analytical device, used for the detection of an analyte,that combines a biological component with a physicochemical detector. Electrochemical biosensors are normally based on enzymatic catalysis of a reaction that produces or consumes electrons (such enzymes are rightly called redox enzymes). The sensor substrate usually contains three electrodes; a reference electrode, a working electrode and a counter electrode. Amperometric biosensors function by the production of a current when a potential is applied between two electrodes. They generally have response times, dynamic ranges and sensitivities similar to the potentiometric biosensors. The potentiometric biosensor, (potential produced at zero current) gives a logarithmic response with a high dynamic range. Such biosensors are often made by screen printing the electrode patterns on a plastic substrate, coated with a conducting polymer and then some protein (enzyme or antibody) is attached. They have only two electrodes and are extremely sensitive and robust. A microbial biosensor is an analytical device which integrates microorganism(s) with a physical transducer to generate a measurable signal proportional to the concentration of analytes.

  • Track 1-1Electrochemical Biosensors
  • Track 1-2Amperometric Biosensors
  • Track 1-3Potentiometric Biosensors
  • Track 1-4 Biosensors Market Analysis
  • Track 1-5 Microbial Biosensors
  • Track 1-6 Enzymatic Biosensors
  • Track 1-7Optical Biosensor

Biosensors Graphene based enzymatic and non-enzymatic electrodes can efficiently detect glucose, cytochrome-c, NADH, hemoglobin, HRP, and cholesterol, hydrogen peroxide, AA, UA, DA, respectively. Nanocapsules are nanoscale shells made out of a nontoxic polymer. They are vesicular systems that are made up of a polymeric membrane which encapsulates an inner liquid core at the nanoscale level. Nanocapsules have a myriad of uses, which include promising medical applications for drug delivery, food enhancement, nutraceuticals, and for the self-healing of materials

  • Track 2-1Non-invasive biosensors in clinical analysis
  • Track 2-2Biosensors and bioelectronics for clinical diagnostics
  • Track 2-3Nanocapsule based drug delivery: Challenges and opportunities
  • Track 2-4Recent advances in graphene-based biosensors & bioelectronics

A biotransducer is the recognition-transduction component of a biosensor system. It consists of two intimately coupled parts; a bio-recognition layer and a physicochemical transducer, which acting together converts a biochemical signal to an electronic or optical signal. Electronic biosensing offers significant advantages over optical, biochemical and biophysical methods, in terms of high sensitivity and new sensing mechanisms, high spatial resolution for localized detection, facile integration with standard wafer-scale semiconductor processing and label-free, real-time detection in a nondestructive manner. Gravimetric biosensors use the basic principle of a response to a change in mass. Most gravimetric biosensors use thin piezoelectric quartz crystals, either as resonating crystals (QCM), or as bulk/surface acoustic wave (SAW) devices. Pyroelectric biosensors generate an electric current as a result of a temperature change. This differential induces a polarization in the substance, producing a dipole moment in the direction of the temperature gradient. The result is a net voltage across the material.

  • Track 3-1Biotransducers
  • Track 3-2Bioreceptors
  • Track 3-3FET-based electronic biotransducers
  • Track 3-4Gravimetric/Piezoelectric biotransducers
  • Track 3-5Pyroelectric biotransducers
  • Track 3-6Airborne Transducers
  • Track 3-7Ultrasound Transducers
  • Track 3-8Pressure Transducers
  • Track 3-9Aimer Transducers

Aptamers are oligonucleotide or peptide molecules that bind to a specific target molecule. Aptamers are usually created by selecting them from a large random sequence pool, but natural aptamers also exist inriboswitches. Immunosensors are built by means of the appropriate combination of the biomolecules with the transducer used together, they can be applied  in specific analytical situations. Immunosensors commonly rely on the reuse of the same receptor surface for many measurements. A Biochip is a combination of minute DNA spots hooked up to a hard surface. Scientists use DNA Biochips to check the expression levels of huge number of genes at the same time. Each DNA spot contains picomoles of a precised DNA sequence known as a probe. These can be tiny section of a gene or a DNA particle that are used to cross breed a cDNA or cRNA. Probe-target cross breeding is usually quantified and detected by detection of fluorophore. Silver or chemiluminescence-labeled targets to identify corresponding abundance of nucleic acid sequences in the target. Sensors are devices that respond to physical or chemical stimuli and produce detectable signals. They are a critical extension of human perception of the world in many aspects of the modern society. This is largely because we are much less sensitive to the chemical or biological environment than to the physical environment (e.g., light, pressure, temperature, or humidity). However, appropriate chemical or biological compositions are tightly linked to the quality of life.

  • Track 4-1Aptamers and their biological applications
  • Track 4-2Proteomics, single cell analysis, and electronic noses
  • Track 4-3 Immunosensors
  • Track 4-4Natural & synthetic receptors (including Molecularly imprinted polymers)
  • Track 4-5Organism and whole cell-based biosensors

Biological properties can be measured and altered using electronics, magnetics, photonics, sensors, circuits, and algorithms. Applications range from basic biological science through clinical medicine, and enable new discoveries, diagnoses, and treatments by creating novel devices, systems, and analyses. Biomolecular Electronics is a branch of nano-science and technology dealing with the investigation and the technological exploitation of electron transport properties in special classes of biomolecules. Albeit it deals with molecules that can donate to or receive electrons, biomolecular electronics has nothing to do with the molecular bases ruling the generation and propagation of electrical signals in neural cells, i.e. the action potential. Bioanalysis is one of the sub categories of Chemistry that helps in measuring Xenobiotics (unnatural concentration or location of drugs, Metabolites and biological molecules)   in biological system. Biomedicine is a branch of medical sciences that deals with applying biological and natural science principles to clinical practices. It studies our ability to cope with the environmental changes.

  • Track 5-1Circuits for biomedical applications/devices
  • Track 5-2 Automation science and engineering
  • Track 5-3Biomolecular electronics and bioanalysis
  • Track 5-4Implantable electronics

Photonic Sensing focuses on experimental contributions related to novel principles, and structures or materials for photonic sensors. Optical fibers can be used as sensors to measure strain, temperature, pressure and other quantities by modifying a fiber so that the quantity to be measured modulates the intensity, phase, polarization and wavelength or transit time of light in the fiber. Sensors that vary the intensity of light are the simplest, since only a simple source and detector are required. A particularly useful feature of intrinsic optical fiber sensors is that they can, if required, provide distributed sensing over very large distances. Photonic integrated circuits (PICs) are optically active integrated semiconductor photonic devices which consist of at least two different functional blocks, (gain region and a grating based mirror in a laser...). These devices are responsible for commercial successes of optical communications and the ability to increase the available bandwidth without significant cost increases to the end user, through improved performance and cost reduction that they provide. The most widely deployed PICs are based on Indium phosphide material system. Silicon photonics is an active area of research

  • Track 6-1 Bio and environmental analytics
  • Track 6-2 Quantum and high powered lasers
  • Track 6-3 Photonic diagnostics & biosensors
  • Track 6-4Security and process technology

Bio-sensing technologies are of increasing importance in healthcare, agri-food, environmental and security sectors, and this is reflected in the continued growth of global markets for such technologies. Biomechanics is closely related to engineering, because it often uses traditional engineering sciences to analyze biological systems. Some simple applications of Newtonian mechanics and/or materials sciences can supply correct approximations to the mechanics of many biological systems. Reliable methodologies are needed for point and stand-off detection of chemical, biological, radiological, special nuclear and explosive (CBRNE) materials. These technological needs are not universally military in nature. For example, there is pervasive interest among diverse disciplines such as medicine, law enforcement, explosive ordinance disposal, Natural environmental protection, industrial manufacturing and food processing in being able to develop capabilities for the rapid detection and identification capabilities for various biochemical markers

  • Track 7-1 Sensing technologies for health and medicine
  • Track 7-2Biomechanics and human rehabilitation
  • Track 7-3CBRNE sensing (chemical, biological, radiological, nuclear, ecological)
  • Track 7-4Ubiquitous devices for bio detection
  • Track 7-5Sensing for agriculture, food quality, and safety
  • Track 7-6Optical Sensing Technologies
  • Track 7-7Security and Sensing

The field of optical sensors has been a growing research area over the last three decades. A wide range of books and review articles has been published by experts in the field who have highlighted the advantages of optical sensing over other transduction methods. Fluorescence is by far the method most often applied and comes in a variety of schemes. Nowadays, one of the most common approaches in the field of optical biosensors is to combine the high sensitivity of fluorescence detection in combination with the high selectivity provided by ligand-binding proteins. In this chapter we deal with reviewing our recent results on the implementation of fluorescence-based sensors for monitoring environmentally hazardous gas molecules. Medical Image Analysis provides a forum for the dissemination of new research results in the field of medical and biological image analysis, with special emphasis on efforts related to the applications of computer vision, virtual reality and robotics to biomedical imaging problems.

  • Track 8-1 Live cell fluorescent biosensors
  • Track 8-2 Theranostics & implantable sensors
  • Track 8-3 3D imaging interaction
  • Track 8-4Novel biosensors for live cell imaging
  • Track 8-5 Biomedical image analysis

The majority of reported biosensor research has been directed toward development of devices for clinical markets; however, driven by a need for better methods for environmental surveillance, research into this technology is also expanding to encompass environmental applications. Biosensors are biophysical devices which can detect the presence of specific substances e.g. sugars, proteins, hormones, pollutants and a variety of toxins in the environment. They are also capable of measuring the quantities of these specific substances in the environment.

  • Track 9-1 Biosensors for Environmental Monitoring
  • Track 9-2 Plants as Environmental Biosensors
  • Track 9-3Biodetection for heavy metal ions in water
  • Track 9-4 Biosensors for marine monitoring

Biomedical engineering (BME) is the application of engineering principles and design concepts to medicine and biology for healthcare purposes (e.g. diagnostic or therapeutic). This field seeks to close the gap between engineering and medicine: It combines the design and problem solving skills of engineering with medical and biological sciences to advance health care treatment, including diagnosis, monitoring, and therapy. To ensure that good quality assurance practices are used for the design of medical devices and that they are consistent with quality system requirements worldwide, the Food and Drug Administration revised the Current Good Manufacturing Practice (CGMP) requirements by incorporating them into the Quality System Regulation, 21 CFR Part 820. An important component of the revision is the addition of design controls

  • Track 10-1 Commercial biosensors, manufacturing and markets
  • Track 10-2Medical device design and testing
  • Track 10-3Surface characterization in biomaterials
  • Track 10-4Biomedical engineering

Nanolithography is the art and science of etching, writing, or printing at the microscopic level, where the dimensions of characters are on the order of nanometers (units of 10 -9meter, or millionths of a millimeter). This includes various methods of modifying semiconductor chips at the atom ic level for the purpose of fabricating integrated circuits. Nanophotonics is the new emerging paradigm where light interacts with nano-scaled structures and brings forth the mysterious world to research.The combination of Photonics and Nanotechnology giving birth to “Nanophotonics” compliments and benefits each other in terms of new functions, materials, fabrication processes and applications.

  • Track 11-1 Nanolithography
  • Track 11-2 Nano-bio-computing
  • Track 11-3Nanophotonics/THz sensing
  • Track 11-4 Novel approaches of nanoparticles
  • Track 11-5 Nanomaterials and nanoanalytical systems
  • Track 11-6Nanosensors

Micro-/nanoelectromechanical systems (MEMS/NEMS) micro-/nanoelectromechanical system (MEMS/NEMS) need to be designed to perform expected functions in short durations, typically in the millisecond to picosecond range. Most mechanical properties are known to be scale dependent, therefore the properties of nanoscale structures need to be measured. For bioMEMS/bioNEMS, bioMEMS/bioNEMS adhesion between biological molecular layer molecular layers and the substrate, and friction and wear of biological layers, can be important. Bionics is the application of biological methods and systems found in nature to the study and design of engineering systems and modern technology Bionics means the replacement or enhancement of organs or other body parts by mechanical versions. Bionic implants differ from mere prostheses by mimicking the original function very closely, or even surpassing it. Bio robotics is the use of biological characteristics in living organisms as the knowledge base for developing new robot designs. The term can also refer to the use of biological specimens as functional robot components. Bio robotics intersects the fields of cybernetics, bionics, biology, physiology, and genetic engineering

  • Track 12-1Biorobotics
  • Track 12-2Bionics
  • Track 12-3Photothermal blade and nano delivery system
  • Track 12-4Biosensor controlled gene therapy

A gas Sensor is a device that detects the presence of gases in an area, often as part of a safety system. This type of equipment is used to detect a gas leak and interface with a control system so a process can be automatically shut down. A gas detector can sound an alarm to operators in the area where the leak is occurring, giving them the opportunity to leave. This type of device is important because there are many gases that can be harmful to organic life, such as humans or animals. Metal oxide-based resistive-type gas sensors are solid-state devices which are widely used in a number of applications from health and safety to energy efficiency and emission control. Nanomaterials such as nanowires, nanorods, and nanoparticles have dominated the research focus in this field due to their large number of surface sites facilitating surface reactions. Previous studies have shown that incorporating two or more metal oxides to form a heterojunction interface can have drastic effects on gas sensor performance, especially the selectivity. Interdigitated capacitive transducers have been inkjet printed onto flexible substrates and optimized for gas sensing applications. Their characteristics have been improved by tuning the annealing/sintering conditions and making use of additional passivation procedures, such as Ag electroplating with Ni or Parylene-C coating of the whole device surface. Surface acoustic wave sensors are a class of microelectromechanical systems (MEMS) which rely on the modulation of surface acoustic waves to sense a physical phenomenon. The sensor transducers an input electrical signal into a mechanical wave which, unlike an electrical signal, can be easily influenced by physical phenomena. The device then transduces this wave back into an electrical signal. Changes in amplitude, phase, frequency, or time-delay between the input and output electrical signals can be used to measure the presence of the desired phenomenon. The calorimetric gas sensor is a device which uses calorimetry as the transduction principle and operates by measuring the heat of a reaction on the sensor surface. It is known that the exothermic nature of the combustion (the oxidation reaction) causes a rise in temperature.

  • Track 13-1Metal Oxide Based Gas Sensors
  • Track 13-2Capacitance Based Gas Sensors
  • Track 13-3Acoustic Wave Based Gas Sensors
  • Track 13-4Calorimetric Gas Sensors
  • Track 13-5Optical gas sensors
  • Track 13-6Electrochemical gas sensors

Bioengineering is the interface between medicine and engineering. Working with scientists, practices and researchers, bioengineers use traditional engineering principles and techniques and improving them to real-world biological and medical issues.

Bioengineering is to collaboration between engineering and the life sciences that enhance the scientific research, mythology and the invention of new cutting-edge technologies which impacts on future research and education process.

  • Track 14-1Biomechanics & Biomarkers
  • Track 14-2Sports and physiological monitoring
  • Track 14-3Rehabilitation
  • Track 14-4Neurotechnology
  • Track 14-5Telemanipulators
  • Track 14-6Wearable technology
  • Track 14-7Biomedical engineering
  • Track 14-8Biochemical engineering
  • Track 14-9Bioprocess engineering
  • Track 14-10Biorobotics
  • Track 14-11Bioinformatics
  • Track 14-12Artificial implants and Biomechanics
  • Track 14-13Nanobiotechnology & Biomaterials
  • Track 14-14Sports technology