Pravin Raj Solomon scite author profile

Catalysts play a significant role in transesterification of vegetable oils. Currently, chemical and biological catalysts are being investigated, and both have their inherent merits and demerits. In large-scale applications, these catalysts are expected to be cost effective and environmentally friendly. If the catalyst is homogeneous in its physical form it is more effective than is the heterogeneous catalyst, but its separation from the mixture is a major issue. Some of the heterogeneous catalysts suffer leaching in harsh reaction conditions. Of late, nanocatalysts that demonstrate high efficiency are being studed. Nanoparticles are used in biological catalysts as solid carriers for lipase immobilization. Lipase immobilized on magnetic nanoparticles has proved to be a versatile biocatalyst for biodiesel production. This article reviews the role of various catalytic systems commonly used in the transesterification reaction of oils in biodiesel generation.

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Immobilization of Lipases – A Review. Part I: Enzyme Immobilization

Thangaraj

Solomon

2019

ChemBioEng Reviews

141

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Free enzymes employed as biological catalysts have many advantages such as low reaction time, involving low energy and less waste output when compared to conventional chemical catalysts. However, commercial utilization of free enzymes is often hampered by the lack of operational stability, high cost, and non‐reusability. Immobilization of enzyme is an option to overcome these obstacles. Immobilized enzyme expresses stable performance in organic solvents even in adverse pH, which makes the biomolecules reusable and prosperous as a biological catalyst. Biological catalysis with immobilized enzymes is found to be an alternative method instead of chemical catalysis for chemical reactions in the foreseeable future. Sources of lipase, techniques in immobilization and cross‐linkers are dealt with in this paper.

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Immobilization of Lipases – A Review. Part II: Carrier Materials

Thangaraj

Solomon

2019

ChemBioEng Reviews

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Carriers used in the immobilization process play a major role in enhancing the properties of the biocatalyst. Polymers are used as organic carriers for enzyme immobilization to improve the thermal, chemical, and operational stability of the enzyme. A variety of carriers are used in the immobilization of enzymes, e.g., mica, silica, zeolites, hydrotalcites, activated carbon, gold and magnetic nanoparticles. Silica‐based carriers offer suitable matrices for enzyme immobilization to manufacture industrial products. Immobilization on nanoparticles has become attractive in biocatalytic applications due to the combination of physical, chemical, catalytic, electronic, and optical properties. Gold nanoparticles also have received attention in the preparation of biocatalysts due to the above‐mentioned reasons. Magnetic nanoparticles are used as a carrier since they can be isolated by an external magnetic field, which is of special interest in the synthesis of organic products such as biodiesel. Different carrier materials involved in the immobilization of enzymes are discussed in this paper.

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Synthesis of Carbon Quantum Dots with Special Reference to Biomass as a Source - A Review

Thangaraj

Solomon

Ranganathan³

2019

CPD

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Quantum dots (QDs) have received much attention due to their extraordinary optical application in medical diagnostics, optoelectronics and in energy storage devices. The most conventional QDs are based on semiconductors that comprise heavy metals whose applications are limited due to toxicity and potential environmental hazard. Of late, researchers are focusing on carbon-based quantum dots, which have recently emerged as a new family of zero-dimensional nanostructured materials. They are spherical in shape with a size below 10 nm and exhibit excitation-wavelength-dependent photoluminescence (PL). Carbon quantum dots (CQDs) have unique optical, photoluminescence and electrochemical properties. They are environment-friendly with low toxicity as compared to toxic heavy metal quantum dots. Generally, CQDs are derived from chemical precursor materials, but recently researchers have focused their attention on the production of CQDs from waste biomass materials due to the economic and environmental exigency. In this review, recent advances in the synthesis of CQDs from waste biomass materials, functionalization and modulation of CQDs and their potential application of biosensing are focused. This review also brings out some challenges and future perspectives for developing smart biosensing gadgets based on CQDs.

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Association of IL17 and IL23R gene polymorphisms with rheumatic heart disease in South Indian population

Poomarimuthu

Elango

Solomon

et al. 2018

Immunological Investigations

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