The significant rise in the number of diabetic patients worldwide, as well as the development of new insulin delivery techniques such as inhalation or oral administration which require higher dosages, are expected to increase the demand for recombinant insulin. Current manufacturing technologies will be unable to fulfill the rising demand for inexpensive insulin due to their production capacity limitations and high production costs. Production of therapeutic recombinant insulin requires a suitable host organism with adequate post-translational modification and refolding machinery. E. coli and S. cerevisiae have been used extensively to make recombinant human insulin for medicinal applications. However, transgenic plants are particularly appealing expression systems as they can be used to synthesize huge amounts of insulin for human medicinal purposes. Plant-based expression systems have the potential for high-capacity insulin synthesis at a minimal cost. The significant production of biologically active proinsulin in seeds or leaves with long-term stability provides a low-cost technique to develop proinsulin for both injectable and oral administration. Recently, stem cell therapy is being utilized for the treatment of diabetes, as these cells are capable of differentiating into insulin producing c ells. With the advancement of regenerative medicine research for different chronic diseases, treatment for type 1 diabetes mellitus has been reported. The current review concentrates on several biotechnological attributes applied to the rapid and mass synthesis of biologically active insulin and its analogs in microbes, various types of stem cells and transgenic crops.
Bioremediation involves the use of natural microorganisms for the purpose ofdegrading numerous types of industrial and environmental waste. Microorganismsrequire carbon, nutrients, and energy to live and multiply as all living organisms do. Inorder to obtain energy, such microorganisms break down organic pollutants into simplerorganic compounds like carbon, salts, water, and similar harmless products. Thisapproach of degrading contaminants using microorganisms has proved much beneficialand has been proven to be cost-effective and efficient. There are a lot of naturally occurringmicroorganisms that have been reported essential in the degradation of organic pollutants.Different industries use different types of bioremediation methods. Specificenvironmental conditions may be required for optimal functioning of microbes e.g., pH,temperature, humidity, etc. Bioremediation has been proven as an environment-friendlyand cost-effective approach to deal with industrial contaminants. Descriptive informationof microbes involved in bioremediation has been explained in this review.
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