Welcome to BIO 2025

7th International Conference on Bioscience & Engineering (BIO 2025)

March 28 ~ 29, 2025, Virtual Conference



Accepted Papers
Biomass Energy: Harnessing Nature’s Power for Sustainable Development & Climate Change Mitigation

Sachdeep Kour, Dr. Arashdeep Singh & Puneet Kour, American College of Education, USA

ABSTRACT

Biomass energy, derived from organic materials such as plant matter and animal waste, presents a significant opportunity for sustainable development and climate change mitigation. As a renewable energy source, biomass can reduce dependence on fossil fuels, lower greenhouse gas emissions, and promote energy security. This paper explores the potential of biomass as a tool for achieving Sustainable Development Goals (SDGs) while addressing climate change challenges. It examines various biomass conversion technologies, their environmental impacts, and socio-economic benefits. Furthermore, the integration of biomass into national energy policies is discussed to highlight its role in fostering a circular economy and enhancing rural livelihoods. The findings underscore the importance of strategic investments in biomass technologies and infrastructure to maximize their contributions to sustainable development.

Keywords

Biomass, Bioenergy, Sustainable Development Goals (SDGs), Green House Gases (GHGs), Fossil Fuels, Climate Change Mitigation, Decarbonization, Renewable Energy (RE), Paris Agreement, Renewable Energy, Feed-in Tariffs (FITs), Biomass Residues, Fatty Acid Methyl Esters (FAME), Pyrolysis, Hydrotreating, Gasification, Transesterification, Biomethane, International Renewable Energy Agency (IRENA), Indirect Land Use Change (iLUC), Circular Economy (CE), Biorefineries, Biofuels, Carbon Capture and Storage (CCS), Net Zero Emissions (NZE), Renewable Energy Directive (RED), Fossil Fuels, Pollutants, Sustainable Practices, Scrubbers, Fabric Filters, Electrostatic Precipitators, Renewable Portfolio Standards (RPS), Bioenergy with Carbon Capture and Storage (BECCS).


Wave Optics of Chromosomes for the Remote Transfer of the Bioholographic Analogue of Aspirin

Irene Caesar, President, Wave Genome LLC, 30 Barstow Road, Unit SUPT, Great Neck, New York 11021

ABSTRACT

Current medical treatment, including chemical pharmaceuticals, EMP treatments, mRNA therapies, and genetic engineering via cutting and pasting DNA snippets do not take into consideration the Structural Damage in Chromosomes they cause by excessive chemicals, electromagnetic fields and homologous nucleotides, all of which break the precisely calibrated geometry of a chromosome. And the Structural Damage of Chromosomes is the major cause of all diseases. The extreme cases of the Structural Damage in Chromosomes are turbo cancer, AIDS, sterilization and prion disease as the ultimate case of encephalopathy. Thus, the urgent task of biological science and technology is to address the issue of the Structural Damage in Chromosomes. This task includes the necessity of creating the fundamental theory of how the structure of a chromosome operates, and the biotechnology that corrects and enhances the structure of chromosomes. In this paper, I introduce my fundamental theory of Wave Optics in Chromosomes, and the biotechnology of Bioholography for the correction of the structural damage in chromosomes. Specifically, I introduce the theoretical and technological paradigm of the Remote Transfer of the Bioholographic Analogue of Aspirin (aka Haspirin), including the results of the clinical trials conducted by my company Wave Genome LLC at the Moscow State Bauman Technical University in 2017. Haspirin clinical trials had verified and confirmed my fundamental theory of Wave Optics in Chromosomes.

Keywords

wireless optogenetics, computational biophysics, structural genomics, scalar waves, bioholography.