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5th International Conference on Pharmaceutical and Biomedical Engineering, will be organized around the theme “Future Engineering Approaches to Pharmaceutical and Biomedical Sciences”

Pharma Engineering 2018 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Pharma Engineering 2018

Submit your abstract to any of the mentioned tracks.

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Branch of pharmaceutical science and technology that entail development and manufacturing of products, processes, and components in the pharmaceuticals industry. It covers thesis important to the global pharmaceutical industry across all divisions, including biotechnology, traditional pharmaceuticals, and generics. Pharmaceutical Engineering nouns useful information on the technical developments and latest scientific issues, regulatory initiatives and innovatory solutions to real-life problems and challenges through possible application articles and case studies.

  • Track 1-1Rational drug design
  • Track 1-2Novel drug delivery
  • Track 1-3Targeted drug delivery
  • Track 1-4Processing of liquid and dispersed phase systems
  • Track 1-5Pharmaceutical packaging technology

Drug discovery and development includes the manufacture of pharmaceutical drug extracted from, or semi synthesized from biological sources. Different from chemically symphonized pharmaceuticals, they include vaccines, blood, or blood components, allergenics, somatic cells, tissues, gene therapies, recombinant therapeutic protein, and living cells used in cell therapy. Biologics can be staid of sugars, proteins, or nucleic acids or complex combinations of these substances, or may be living cells or tissues.

  • Track 2-1Drug Engineering
  • Track 2-2Biologic drugs
  • Track 2-3Drug manufacture
  • Track 2-4Chemical synthesis

Biopharmaceutics is the study of drug absorption rate that is affected by various factors like physical and chemical properties of the drug, the dosage form of the drug and the route of adminstration. Pharmaceutical technology is the appliance of scientific knowledge or technology to pharmacy, pharmacology, and the pharmaceutical industry. It includes design, techniques, and instrumentation in the manufacture, preparation, compounding, dispensing, packaging, and accumulating of narcotic and other preparations used in diagnostic and determinative procedures and in the treatment of patients.

  • Track 3-1Biopharmaceutical Manufacturing
  • Track 3-2Pharmacokinetics and Pharmacodynamics
  • Track 3-3Bioprocessing
  • Track 3-4Supply chain safety
  • Track 3-5Molecular isotopic engineering
  • Track 3-6Medication management

Pharmaceutical analysis is a subsection of chemistry, which concerns the series of process for the identification, purification, determination, and quantitation. This is mainly used for the separation of the components from the mixture and for the determination of the structure of the compounds. It mostly concerns about complex manufacturing, drug safety, costly development programs, market demands for evidence-based data and increased regulatory requirements are all issues that can be consigned through a better understanding of your drug product , drug substance or manufacturing process which in turn, can only be carry through experienced robust analytical data and analytical studies. Bio analytics is the field of research in which biotechnology concerned with various analytical techniques.

  • Track 4-1Chemical analysis
  • Track 4-2Traditional medicine
  • Track 4-3Medicinal materials
  • Track 4-4Clinical laboratory and Bio analysis
  • Track 4-5Analysis of crude drugs
  • Track 4-6Clinical Trails Management

Pharmaceutical Formulation is the process in which different chemical substances i.e., active chemical substances will combined together to produce a medical compound i.e., medical drug. This process involves production of drug which characterized by two things: Stability of the product, second Acceptability to the patient. Process engineering target on the design, operation, control, and cumulation of chemical, physical, and biological processes. Process engineering contain a vast range of industries, such as chemical, petrochemical, food, agriculture, pharmaceutical, mineral processing,  software development, and biotechnological industries.

  • Track 5-1Novel Drug Delivery Formulations
  • Track 5-2Quality assurance
  • Track 5-3Quality control
  • Track 5-4Good Manufacturing Practices
  • Track 5-5Process control and Process design

Medical devices are the Instruments, apparatus, tools, software, material or other article, whether used alone or in combination used specifically for diagnostic or for therapeutic purposes and necessary for its proper application, intended for the purpose of diagnosis, prevention, monitoring, and treatment of various diseases.

Medical imaging envelop different imaging modalities and processes to image the human body for diagnostic and treatment, therefore plays an important role in  to improve public health for all population groups. Furthermore, medical imaging is frequently justified in the foul up of a disease already diagnosed or treated.

  • Track 6-1Radiography and echocardiography
  • Track 6-2Magnetic resonance imaging (MRI)
  • Track 6-3Elastography and Ultrasonography
  • Track 6-4Thermography and Tomography
  • Track 6-5Biomedical Instrumentation measurements
  • Track 6-6Instrumentation for psychophysiological measurements
  • Track 6-7Pacemakers and Defibrillators
  • Track 6-8Ophthalmic and ENT instruments
  • Track 6-9CT and PET scanners

Molecular pharmacology deals with the biochemical and biophysical characteristics of interactions between drug molecules and those of the cell. It is molecular biology applied to pharmacological and toxicological questions. The methods of molecular pharmacology include precise mathematical, physical, chemical, and molecular biological techniques to understand how cells respond to hormones or pharmacologic agents, and how chemical structure correlates with biological activity.

Experimental therapeutics is the development of various treatment strategies specifically to treat human diseases more effectively and with less toxicity.

  • Track 7-1Pharmacogenomics
  • Track 7-2Systems pharmacology
  • Track 7-3Pharmacoeconomics
  • Track 7-4Molecular Genetics
  • Track 7-5Molecular pathology and models
  • Track 7-6Toxicology

Biomedical Engineering is the science of application of engineering principles to the fields of biology and health care. Bioengineers work with doctors, therapists and researchers to implement systems, equipment and devices in order to solve clinical problems which focus on the advances that improve human health and health care at all levels.

Clinical engineering is a special field within Biomedical engineering responsible primarily for applying and implementing medical technology to optimise healthcare delivery.

  • Track 8-1Cardiovascular Engineering
  • Track 8-2Sequence and image analysis
  • Track 8-3Proteomics and Transcriptomics
  • Track 8-4Biomedical Modelling and Simulation
  • Track 8-5Biomedical optics
  • Track 8-6Biomedical computing and analysis
  • Track 8-7Therapeutic Engineering
  • Track 8-8Interactive 3D modelling
  • Track 8-9Telemedicine

Biomechanics is the study of systems and structures of biological organisms from the smallest plants to the largest animals react with external stimuli. In animals, biomechanics often refers to the study of how the skeletal and musculature systems work under different cases. In biomechanics more generally, scientists often try to apply physics and other mathematical based forms of analysis to discover the limits and capabilities of biological systems.

Biomaterials are substances that are used in medical devices or in contact with biological systems. Biomaterials use impression from medicine, biology, chemistry, materials science and engineering.

  • Track 9-1Implants and Vascular grafts
  • Track 9-2Comparative biomechanics
  • Track 9-3Cellular and Plant biomechanics
  • Track 9-4Injury Biomechanics
  • Track 9-5Musculoskeletal and Orthopaedic Biomechanics
  • Track 9-6Ergonomy and Allometry
  • Track 9-7Continuum biomechanics
  • Track 9-8Sustainable materials
  • Track 9-9Bionics and Biopolymers
  • Track 9-10Bio tribology and Bio fluid mechanics

Medical and Nano biotechnology are the applications of medical and nanotechnology in the biological fields. Nanobiotechnology is the fusion of nanotechnology and biotechnology in which nanosized machines can be synthesized by incorporating biological systems to study and manipulate different biological processes at molecular level.

  • Track 10-1Nanomedicine
  • Track 10-2Tissue Growing Nanostructures
  • Track 10-3Nano-Bio-Computing
  • Track 10-4Biomedical Application of Nanoparticles

Cell engineering exploits the principles and methods of engineering to the complication of cell and molecular biology of both a basic and applied nature.

Tissue engineering is a technique which generates living tissue ex vivo for replacement or therapeutic applications through materials development, biochemical controls, cell culture, and genetic engineering. Tissue engineering uses biomaterials and cells to produce new tissues. Stem cells have infused great excitement in the field as a potentially powerful cell source to rebuild tissues.

  • Track 11-1Bone bioengineering
  • Track 11-2Organ preservation
  • Track 11-3Cartilage biology
  • Track 11-4Nerve regeneration
  • Track 11-5Microscale biocomplexity
  • Track 11-6Stem cells and Functional tissue
  • Track 11-7Cellular and Tissue Engineering
  • Track 11-8Cell fate mechanisms

Bioinstrumentation is the use of bioelectronics instruments for the recording or transmission of physiological information. Biomedical devices are combination of biology, sensors, interface electronics, microcontrollers, and computer programming, including biology, optics, mechanics, and electronics, chemistry, and computer science. Bioinstrumentation engineers design, frame, test, and manufacture advanced medical instruments and implantable devices into a single, more productive unit.

  • Track 12-1Recent advances in patient treatment and care
  • Track 12-2Recent Advances in spectroscopy
  • Track 12-3Green techniques for medicinal chemistry
  • Track 12-4High-throughput screening and Laboratory automation
  • Track 12-5Computational molecular systems

Bio imaging covers the complex chain of acquiring, processing and visualizing structural or functional images of living objects or systems, including extirpation and processing of image-related information. Image processing methods, such as denoising, segmentation, deconvolution and registration methods, feature detection and classification represent an indispensable part of bio imaging, as well as related data analysis and statistical tools are involved in this process.

  • Track 13-1Bio Image Informatics
  • Track 13-2Bio probes
  • Track 13-3Image data handling
  • Track 13-4Cardiac Imaging
  • Track 13-5Cancer Imaging
  • Track 13-6Bio Optics

Bioinformatics and Computational Biology are highly flexible interdisciplinary fields which involve the study of computer sciences, biological sciences, and mathematical sciences together. These include biomarker identification, drug target discovery, functional genomics and proteomics, coding sequence analysis, cross-validation analysis, forensic applications of genetics.

  • Track 14-1Genome sequencing
  • Track 14-2Dynamic Modeling Methods
  • Track 14-3Systems biology
  • Track 14-4Computational Bio medicine
  • Track 14-5Structural Bioinformatics
  • Track 14-6Biological and medical ontologies
  • Track 14-7Biomarker Identification
  • Track 14-8Big Data Analytics

Bio Robotics is a collective study of cybernetics, bionics and genetic engineering. Bio Robotics is the use of biological characteristics in living organisms as the knowledge base for developing new robot designs.

Biosensors are the devices used in order to determine the concentration of substances and other parameters of biological interest even where they do not utilise a biological system directly. Biosensors basically involve the quantitative analysis of various substances by converting their biological actions into measurable signals.

  • Track 15-1Rehabilitation Robotics
  • Track 15-2Surgical Robotics
  • Track 15-3Amphibious Robotics
  • Track 15-4Modular Robotics
  • Track 15-5Nanosensors
  • Track 15-6Types of Biosensors
  • Track 15-7Applications of Biosensors

Genetic engineering adverts to the direct manipulation of DNA to alter an organism’s characteristics in a proper way. In most cases, use of recombinant DNA adds an extra gene to an organism to alter a trait or to add a new trait. Uses of genetic engineering include imposing the nutritional quality of food, creating pest-resistant crops, and creating infection-resistant livestock.

  • Track 16-1Transformation and Genome editing
  • Track 16-2Genetically modified organisms
  • Track 16-3Gene knockout
  • Track 16-4Traditional breeding
  • Track 16-5Genetically engineered plants and Transgenic Animals
  • Track 16-6Polymerase chain reaction
  • Track 16-7Electroporation
  • Track 16-8Pharmacogenomics
  • Track 16-9Next generation sequencing

Regulatory affairs is a comparatively new profession which developed from the desire of governments to protect public health by controlling the safety and efficacy of products in areas including pharmaceuticals, veterinary medicines, medical devices, cosmetics and complementary medicines. Regulatory Affairs is involved in the development of new medicinal products from early on, by integrating regulatory principles and by preparing and submitting the relevant regulatory dossiers to health authorities. Regulatory Affairs is actively involved in every stage of development of a new medicine and in the post-marketing activities with authorised medicinal products. The Regulatory Affairs department is an important part of the organisational structure of pharmaceutical companies.

  • Track 17-1Quality by Design (QbD)
  • Track 17-2Scope and importance of regulatory affairs
  • Track 17-3Marketing Authorizations
  • Track 17-4Current status of drug safety and pharmacovigilance
  • Track 17-5Intellectual Property rights
  • Track 17-6Drug Policy and Regulation
  • Track 17-7Regulatory issues in the pharmaceutical industry

Rehabilitation engineering is the clinical and biomechanical application of engineering to provide services, research, and development to assist people with disabilities. Rehabilitation engineering includes the systematic application of technologies, engineering methodologies, or scientific principles to meet the needs of, and address the barriers confronted by, individuals with disabilities in areas that include education, rehabilitation, employment, transportation, independent living, and recreation.

Neural engineering is the application of biomedical engineering principles to the nervous system.

  • Track 18-1Virtual rehabilitation
  • Track 18-2Orthoses and Prosthesis
  • Track 18-3Scope of neural engineering
  • Track 18-4Neural Tissue engineering

The biomedical industry comprises of pharmaceutical, medical device, biotech and diagnostic fields. Biomedical industry covers the companies which produce the drugs, therapies and equipment for the health care system in the global economy. A large number of research technologies were developed in the field of pharmaceutical and biomedical industries.

  • Track 19-1Drug-pricing concerns
  • Track 19-2Drug Access and Regulation
  • Track 19-3Current and Future Biomedical Business Models
  • Track 19-4Industry Dynamics
  • Track 19-5Biomedicine in industry