Prof. Mamta Baunthiyal, from the Department of Bioscience and Biotechnology at Bansthali University, Rajasthan, India, is focused on the screening of local flora for bioremediation of fluoride-contaminated soil and water. Under the guidance of Prof. Vinay Sharma, her research aims to identify plant species with the potential to mitigate the harmful effects of fluoride pollution, which is a significant environmental concern. This bioremediation approach could provide sustainable solutions to detoxify contaminated ecosystems, promoting environmental health and community well-being. π±π§πΏππ¬
Research Impact
Prof. Mamta Baunthiyal is renowned for her pioneering work in fluoride phytoremediation, focusing on utilizing plants to remove harmful fluoride from contaminated environments. Her research not only advances scientific understanding but also highlights the importance of environmental health. Prof. Baunthiyal is dedicated to educating local communities about the risks of fluoride contamination and promoting sustainable solutions. Through her academic and outreach efforts, she exemplifies a strong commitment to both academic excellence and social responsibility. π±π§πππΏ
Leadership and Mentorship
Prof. Baunthiyal has made remarkable contributions to the advancement of biotechnology research, particularly in developing state-of-the-art laboratories at her institute. Her leadership and vision played a key role in introducing innovative biotechnology programs, shaping the future of the field. As a mentor, she has supervised numerous research projects, guiding students and researchers to explore new frontiers in biotechnology. Her dedication to fostering a dynamic research environment has had a lasting impact on both her institute and the broader scientific community. Prof. Baunthiyal’s work continues to inspire the next generation of biotechnologists. π§¬π¬π±π©βπ¬
Global Recognition
Prof. Baunthiyal is an esteemed member of several prominent scientific organizations, reflecting her influence in the global research community. Her active participation in key scientific networks enables her to contribute significantly to the advancement of her field. Furthermore, she has collaborated with renowned international institutes on various projects, fostering knowledge exchange and driving innovative research. These partnerships not only enhance her academic profile but also expand her global reach, ensuring her work has a lasting impact on both local and international scientific advancements. ππ¬π€ππ
Research Focus
Prof. Mamta Baunthiyal’s research primarily focuses on plant physiology, environmental stress, and phytoremediation. She investigates the impact of various pollutants, including fluoride and metal toxicity, on plants, examining physiological and biochemical responses. Her work includes studying the accumulation of fluoride by plants and exploring their potential for environmental cleanup. Additionally, Prof. Baunthiyal’s research extends to the synthesis of silver nanoparticles using plant extracts like Urtica dioica and their synergistic effects with antibiotics. She also works on computational biology, identifying drug-like compounds for treating diseases like hyperuricemia. π±π¬ππΏπ§¬
Publication Top Notes
Characterization of silver nanoparticles synthesized using Urtica dioica Linn. leaves and their synergistic effects with antibiotics
Metal toxicity and photosynthesis
Physiological and biochemical responses of plants under fluoride stress: an overview
Accumulation of fluoride by plants: potential for phytoremediation
Organ-wise accumulation of fluoride in Prosopis juliflora and its potential for phytoremediation of fluoride contaminated soil
Identification of new drug-like compounds from millets as Xanthine oxidoreductase inhibitors for treatment of Hyperuricemia: A molecular docking and simulation study
In silico identification of mimicking molecules as defense inducers triggering jasmonic acid mediated immunity against alternaria blight disease in brassica species
Computer aided screening of natural compounds targeting the E6 protein of HPV using molecular docking