Abdul Bakrudeen Ali Ahmed

Pharmaceutical, cosmeceutical, and traditional applications of marine carbohydrates.

Marine carbohydrates are most important organic molecules made by photosynthetic organisms. It is very essential for humankind: the role in being an energy source for the organism and they are considered as an important dissolve organic compound (DOC) in marine environments sediments. Carbohydrates found in different marine environments in different concentrations. Polysaccharides of carbohydrates play an important role in various fields such as pharmaceutical, food production, cosmeceutical, and so on. Marine organisms are good resources of nutrients, and they are rich carbohydrate in sulfated polysaccharide. Seaweeds (marine microalgae) are used in different pharmaceutical industries, especially in pharmaceutical compound production. Seaweeds have a significant amount of sulfated polysaccharides, which are used in cosmeceutical industry, besides based on the biological applications. Since then, traditional people, cosmetics products, and pharmaceutical applications consider many types of seaweed as an important organism used in food process. Sulfated polysaccharides containing seaweed have potential uses in the blood coagulation system, antiviral activity, antioxidant activity, anticancer activity, immunomodulating activity, antilipidepic activity, etc. Some species of marine organisms are rich in polysaccharides such as sulfated galactans. Various polysaccharides such as agar and alginates, which are extracted from marine organisms, have several applications in food production and cosmeceutical industries. Due to their high health benefits, compound-derived extracts of marine polysaccharides have various applications and traditional people were using them since long time ago. In the future, much attention is supposed to be paid to unraveling the structural, compositional, and sequential properties of marine carbohydrate as well.

In Vitro Production of Gymnemic Acid from Gymnema sylvestre (Retz) R. Br. Ex Roemer and Schultes Through Callus Culture Under Abiotic Stress Conditions

Plant secondary metabolites have enormous potential for research and new drug development. Many secondary metabolites have a complex and unique structure and their production is often enhanced by biotic and abiotic stress conditions. Gymnemic acid (C(43)H(68)O(14)), a pentacyclic triterpenoid isolated from the leaves of Gymnema sylvestre, exhibits potent inhibitory effect on diabetes. The gymnemic acid content is determined by chromatographic methods: Camag HPTLC system equipped with a sample applicator Linomat IV and TLC scanner and integration software CAT 4.0. In HPLC C(18) (ODS) reverse phase column; water 486 UV detector; mobile phase, water/methanol (35:65, HPLC grade) + 0.1% acetic acid are used. Sample (20 microL) is applied with a flow rate of 1 mL/min and read at 230 nm with UV detector. The production of gymnemic acid is significantly higher in callus treated with 2,4-dichloro phenoxy acetic acid (2,4-D) and kinetin (KN). The blue light increases gymnemic acid accumulation upto 4.4-fold as compared with fluorescent light treatment and out of which 2.8 is found in leaves. Gymnemic acid is isolated from callus, grown under stress conditions followed by preparative TLC, simple and reproducible character based on HPTLC and high performance liquid chromatography.

Effect of Picloram, Additives and Plant Growth Regulators on Somatic Embryogenesis of Phyla nodiflora (L.) Greene

The present study describes the plant regeneration via somatic embryogenesis in suspension culture der ived from the leaf and stem explants of Phyla nodiflora . The medium type, plant growth regulators, complex extract (coconut milk and malt extract) and anti-oxidant (activated charcoal, ascorbic acid, Polyvinylpyrrolidone and cacid) markedly influenced the embryo regeneration of P. nodiflora . MS with 2,4-D and activated charcoal (10 mg/L) ga ve the highest stimulation of embryogenic callus growt h. Optimized callus was transfered into suspension culture, which showed the globular, heart shaped embryos in MS with 2,4-D + BA + picloram (0.1 mg/L), coconut m ilk (10 ml/L), citric acid (100 mg/L) on 6 th subcultures. Further development stages such as to rpedo and cotyledonary stage embryos and fostered maturation of embryos we re observed at 8 th and 10 th subculture. However, the high frequency embryo germination and plantlet (45 plant s/20 mg cotyledonary stages embryos) formation was obtained in half-strength MS medium without growth regulator s from cotyledonary embryos. All the plantlets esta blished in the field exhibited morphological characters simila r to those of the mother plant.

Preparation, properties and biological applications of water soluble chitin oligosaccharides from marine organisms

Chitin oligosaccharides (COSs) can be isolated from various natural resources, which have widely been used in biological active supplements (BAS) for the benefit of humankind. Several technological approaches for the preparation of COSs such as enzymatic, chemical, acid-catalysts hydrolysis, microwave radiation, membrane bioreactor methods have been developed and among them, membrane bioreactor, bioconversion and continuous mass production technologies are reported to be excellent. Compounds isolated from natural products have made a drastic impact on the pharmaceutical industry and especially, water-soluble chitin oligosaccharides have shown greater clinical activity, which have been demonstrated in various cell lines of disease significance. The activities of these COSs were being investigated in different patients, animals and even plants as a broad phase clinical trial program. In the present article, we have discussed the COSs preparation by different methods through comprehensive diffraction procedures along with the merits and demerits given in detail. In addition, a summary of recent work describing the synthesis and biological activities of water-soluble COSs has been presented here.

The Perspectives of the application of biofilm in the prevention of chronic infections

Biofilms are a natural part of the ecology of the earth. Many biofilms are quite harmful and must be treated or controlled. Other biofilms are beneficial and can be used to help fix serious problems. Biofilms can grow on many different surfaces, including rocks in water, foods, teeth, and various biomedical implants. This bacterial colonization may present the need for additional operations, amputation, or it may even lead to death. The fundamental principles of bacterial cell attachment and biofilm formation are discussed. Biofilms represents a new, wide-open field practice and research that is only going to get hotter with time. Functional organic plasma polymerized coatings are also discussed for their potential as bio-sensitive interfaces, connecting metallic electronic devices with their physiological environments.