Recent Trends in Pharmaceutical Sciences and Research

Green chemistry (GC) is the rapid emerging branch of chemistry. The beginning of GC is considered as a response to the need to reduce the damage of the environment by man-made materials and the processes used to produce them. The GC could include anything from reducing waste to even disposing of waste in the correct manner. All chemical waste should be set out in the best feasibleway without causing any harm to the surroundings and livelihoods.GC is the synthesis of substance in such a way that is proper, non-polluting and protected and which requires lowest amounts of resources and energy but generating slight or no waste material. The GC is required to minimize the harm of the nature by anthropogenic materials and the processes applied to generate them. The GC indicates research emerges from scientific discoveries about effluence responsiveness. The GC involves twelve set of values which minimize or eliminates the use or production of unsafe substances. Scientists and Chemists can significantly minimize the risk to environment and health of human by the help of all the valuable ideology of GC. The principles of GC can be achieved by the use environmental friendly, harmless, reproducible and solvents and catalysts during production of medicine, and in researches. The use of UV-energy Microwave irradiation in is also significant way to achieve the goal of GC.This article explains ideology and presents selected examples of implementation of green chemistry principles in everyday life in industry, the laboratory and in education.

Sheldon R.A. Catalysis: The Key to Waste Minimization. J Chem Tech Biotechnol. 1997; 68(4): pp. 267.381–388.

Noyori R. Pursuing practical elegance in chemical synthesis. Chemistry for the Environment. Interuniversity Consortium. http://www.incaweb.org/.

Green & Sustainable Chemistry Network, Japan. Green & Sustainable Chemistry Network.

Anastas P.T. & Hovarsth I.T. Innovations and Green Chemistry, Chem.Rev. 2007; 107: pp. 2169.

Anastas P.T. & Warner J.C. Green Chem Theory and Practice. Oxford Univ. Press, New York. 1998.

Ravichandran S. Int. J. ChemTech Res. 2010; 2(4): pp. 2191.

Trost B.M. Atom economy-A challenge for organic synthesis: Homogeneous catalysis leads the way. Angew Chem Int., Ed. 1995; 34: pp. 259.

Bharati VB. Resonance. 2008; 1041.

Ahluwalia V.K. & Kidwai M. New Trends in Green Chemistry. Anamaya Publisher, New Delhi. 2004.

Ravichandran S. Int. J. ChemTech Res. 2010; 2(4): pp. 2191.

Trost B.M. Atom economy-A challenge for organic synthesis: Homogeneous catalysis leads theway. Angew Chem Int. 1995; 34: pp. 259.

Sheldon R.A. Green solvents for sustainable organic synthesis: State of the art. Green Chem. 2005; 7: pp. 267.

Bharati V.B. Resonance. 2008; pp. 1041.

Ahluwalia V.K. & Kidwai M. New Trends in Green Chemistry. Anamaya Publisher, New Delhi. 2004.

Anastas P.T & Warner J.C. Green Chemistry: Theory and Practice. Oxford University Press: New York. 1998: pp. 30.

Micell Technology, Website: www.micell.com, accessed Dec. 1999.

Dhage S.D. Applications of green chemistry principles in everyday life. Inter J Res Pharm & Chem, 2013; 3(3): pp. 518-520.

Tundo P. & Anastas PT. Green Chemistry: Challenging Perspectives. Oxford University Press, Oxford. 1998.

Micell Technology, Website: www.micell.com, accessed Dec. 1999.

Hall J.A., Vuocolo L.D., Suckling I.D., Horwitz C.P., Allison R.M., Wright L.J. & Collins T. Proceeding of 53rd APPITA Annual Conference, Rotorua, New Zealand. April 19-22, 1999.

Jaiswal S., Kapoor D., Kumar A. & Sharma K. Applications of green chemistry. Inter J Cybernetics & Informatics. 2017; 6(1/2): pp. 127-133.

Jagtap T. & Chopade J. Green chemistry: A Review. Eur J Pharm & Med Res. 2017; 4(5): pp. 566-568.

Gholam A.M. & Jolene M.S. Microwave Irradiation Reactions: Synthesis of Analgesic Drugs. JChem Educ. 2000; 77(3): pp. 356.

Istvan T.H. Solvents from nature. Green Chem. 2008; 10: pp. 1024-1028.