In this project, I am investigating the impact of varying concentrations of gallic acid on the growth parameters of mung bean (Vigna radiata). By treating the plants with different gallic acid levels, I aim to assess its influence on growth metrics such as shoot and root lengths, biomass (fresh and dry weights), chlorophyll content, and biochemical parameters. This research seeks to evaluate the potential of gallic acid as a plant growth regulator, exploring its ability to enhance stress tolerance and promote overall plant health. The findings may provide valuable insights into the application of natural phenolic compounds in sustainable agriculture.

I conducted a comparative analysis to explore the effects of biologically and chemically synthesized iron nanoparticles on wheat growth under wastewater stress. I germinated wheat seeds in four distinct conditions: water, untreated wastewater, biologically nanoparticle-treated wastewater, and chemically nanoparticle-treated wastewater. Over 18 days, I carefully monitored and analyzed growth parameters, including shoot and root lengths, fresh and dry weights, chlorophyll content, and biochemical responses such as antioxidant enzyme activities and ROS levels. This research aimed to evaluate the potential of biologically synthesized nanoparticles in mitigating the harmful effects of wastewater stress, hypothesizing that they wo

I successfully initiated callus induction from maize immature embryos in a tissue culture setting, demonstrating proficiency in plant tissue culture techniques and biotechnological applications. This project involved meticulous preparation of growth media, precise handling of sterile conditions, and strategic manipulation of plant growth regulators to stimulate callus formation. By optimizing hormone concentrations and culture conditions, I achieved robust callus proliferation, highlighting my skills in experimental design and execution within biotechnology. This achievement showcases my ability to conduct detailed scientific research.

I conducted a significant research project on the sterile germination and maturation of maize immature embryos using tissue culture techniques, aimed at optimizing conditions for controlled propagation. This involved protocol development for aseptic culture, isolation of embryos, and optimization of growth media and environmental factors. Through rigorous monitoring and evaluation, I successfully achieved healthy germination and growth, contributing valuable insights into maize embryo development. This project showcases my commitment to advancing agricultural biotechnology.