14^th World Congress on Drug Design Techniques and Pharmacology September 22-22, 2020 Paris, France

Pharmaceutical Delivery Technologies are mainly focused on enhancing the drug absorption, patient experience and efficacy of Drug. Bioavailability of medications within the system can be achieved by increasing the dissolution rate with specialized drug delivery enhancement products. By increasing the latest Technologies for Drug-delivery it is possible to increase its commercial success. The main routes of drug delivery are oral, injection/infusion, and transdermal. Drug-eluting stents and other implantable drug delivery devices are presented, as well as externally applied devices. When combined with appropriate targeting moieties, drug-coated nanoparticles, drug-encapsulating liposomes and nanotubes, and tree-like dendrimers enable organ and tissue targeting.

The latest drug discovery system brings many advancements and developments in the new drugs. Now a days new biological targets, methodologies and advanced computing have enhanced modern drug discovery and have given medicinal chemistry a more thoughtful skill set and toolkit to hold the nuances  of disease pathophysiology. The mixture of both medicinal chemistry and methodology in drug discovery together makes drug delivery more efficient and more lessening attrition. In drug designing, structure-based drug design, and fragment –based drug design, natural product-based drug design, diversity-based drug design, and chemo genomics are applied.

Drug Discovery is a branch in pharmacy in which invention of potent drug entities is the important role to be involved. The major part of drug design involves the identification of characteristic diagnostic biomarkers such as a protein responsible for the disease or disorder and then developing a drug molecule of therapeutic potency that targets it. The process involves various branches of pharmacology coalesce with biotechnology, bioinformatics, molecular biology, nanotechnology and biochemistry that ultimately leads to the production of molecules of therapeutic value. Despite the advancements in modern technologies and an understanding of the biological systems, the drug discovery process is still a lengthy and expensive task. There are only a few therapeutic drugs that pass the test and enter the market but today's accelerated studies using computational drug design techniques speed up the process of drug discovery.

The processes of designing a new drug by using bioinformatics implements have opened a new area of drug research and development. Computational techniques assist us in searching various drug targets and in Drug-Formulation designing drug. 

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Targeted drug delivery systems are the way to deliver the payload to the desired site of action without the interaction with normal cells. The number of targeted drug delivery systems like use of microfluidics, nanoparticle-based formulations and the use of monoclonal antibodies for anticancer drugs are in the market and many more are in research phase. Successful translations of potential cancer, gene therapies and particularly small interfering RNA delivery (siRNA) will largely depends on targeted drug delivery strategies. In future, the advancements in these approaches can reach to significant improvements in cancer therapy procedures to avoid risks associate with chemotherapy in these methodologies.

The process by which a drug is distributed can have an important effect on its efficacy Some drugs have an optimum concentration range within which extreme benefit is derived, and concentrations above or below this range can be noxious or produce no therapeutic benefit at all. On the other hand, the very slow improvement in the efficacy of the treatment of severe diseases, has optional a growing need for a multidisciplinary approach to the delivery of therapeutics to targets in tissues.  These nanoparticles which are filled with drugs and plagued to all over the body are avoided to get interact with healthy tissues. The goal of a targeted drug delivery system is to extend, localize, target and have a vulnerable drug interaction with the diseased muscle.

Proteomics, the large-scale analysis of proteins, contributes expressively to our understanding of gene function in the post-genomic era. Protein micro characterization for large scale certification and post translational changes, differential display proteomics for comparison of protein levels with potential application in a extensive range of diseases;  with potential application in a extensive range of diseases; and (3) studies of protein–protein interactions using methods such as mass spectrometry or the yeast two-hybrid system are the three main areas to be covered in proteomics. As the new technologies are developed day by day the continuous growth and new skills are seen in proteomics technologies. And as an added value we can obtain the high-quality acquisition of proteome data easily

Nanotechnology has now introduced to develop medicine. Nanotechnology contains the use of materials with essential length scales in the nanometer measurement which demonstrate significantly changed properties associated to micron structured materials. Such materials can include particles, fibers, grain sizes, etc. This session highlighted the progressions nanotechnology is making in medicine in such fields as disease prevention, diagnosis, and treatment including (but not limited to) drug delivery, tissue engineering, implants, sensors, cancer treatment, an but not limited to) drug delivery, tissue engineering, transplants, sensors, cancer treatment, and toxic

It is seen that there in 2010 there is global market for business development of drug delivery technology having $131.6 billion and is expected to rise at 5% in its compound annual growth rate (CAGR) and reach nearly $175.6 billion by 2016. Total of 59% of the total drug delivery market in the year 2010 was constituted by US that means $78 billion.It is forecast to reach nearly $103 billion in 2016 at a CAGR of 4.7%. As Europe is contributed by 27% of the total drug delivery market in 2010 as it was $36 billion and is expected to increase by $49 billion by the year 2016 at CAGR of 5.6% for 2013 and Drug Delivery Global market was seen to be increased by $150.3 billion, according to BCC research. This was an increase from $142 billion the previous year. Thus, if the predicted annual growth is given, the market represents the considerable business opportunity, that    which can be seen in the increasing number of drug delivery specialists. Consistent quality and competitive costs of product improves Production performance and continuity of supply and Product and technology auditing and due diligence with minimizing Regulatory Issues, quality control, and business development Business opportunities in drug delivery.