BANGKOK 8th International Conference on Bioscience, Biotechnology & Environmental Engineering: B3E2-27

Call for papers/Topics

All Abstracts, Reviews, short articles, Full articles, Posters are welcomed related with any of the following research fields:

1. Independent Core Disciplines

These represent the foundational pillars of each distinct field before they intersect with one another.

Bioscience (The Study of Living Systems)

  • Molecular Biology: DNA replication, transcription, translation, and genetic regulation.

  • Cell Biology: Organelle function, cellular signaling, metabolic pathways, and cell division.

  • Microbiology: Virology, bacteriology, mycology, and microbial physiology.

  • Ecology and Evolution: Population dynamics, ecosystem structure, natural selection, and biodiversity.

Biotechnology (The Technological Application of Biology)

  • Genetic Engineering: Recombinant DNA technology, CRISPR-Cas9 gene editing, and cloning.

  • Bioprocess Engineering: Fermentation technology, bioreactor design, and downstream processing (separation and purification).

  • Industrial Biotechnology: Production of bio-based chemicals, industrial enzymes, and synthetic biology applications.

  • Bioinformatics: Computational genomics, structural biology modeling, and biological data mining.

Environmental Engineering (The Protection of Ecosystems and Public Health)

  • Water and Wastewater Treatment: Municipal water purification, industrial effluent treatment, and desalination.

  • Air Quality Engineering: Particulate matter control, greenhouse gas mitigation, and industrial emission monitoring.

  • Solid and Hazardous Waste Management: Landfill engineering, toxic waste neutralization, and recycling infrastructures.

  • Hydrology and Water Resources: Groundwater modeling, stormwater management, and watershed protection.

2. Interrelated Cross-Disciplinary Fields

These subtopics exist at the intersections where two or more of these primary fields overlap and rely on one another.

Bioscience + Biotechnology (The Innovation Nexus)

  • Medical Biotechnology (Red Biotech): Monoclonal antibodies, vaccine development, gene therapy, and stem cell research.

  • Agricultural Biotechnology (Green Biotech): Genetically modified organisms (GMOs), pest-resistant crops, and molecular breeding.

  • Marine Biotechnology (Blue Biotech): Harvesting extremophiles for novel pharmaceuticals and bioactive compounds.

Bioscience + Environmental Engineering (The Nature-Engineered Nexus)

  • Environmental Microbiology: Studying microbial communities that naturally degrade pollutants or cycle nutrients in ecosystems.

  • Ecotoxicology: Assessing the biological impact of chemical pollutants on living organisms and food webs.

  • Ecological Engineering: Designing human habitats and infrastructure that integrate smoothly with natural ecosystems.

Biotechnology + Environmental Engineering (The Remediation & Sustainability Nexus)

  • Bioremediation: Utilizing engineered or native microorganisms to clean up contaminated soil, groundwater, and oil spills.

  • Phytoremediation: Using genetically optimized or specialized plants to extract and neutralize heavy metals from polluted sites.

  • Biofiltration: Employing biological systems (like compost beds or biofilms) to capture and treat air pollutants and industrial odors.

3. Advanced Multi-Disciplinary Subtopics

These complex fields merge all three disciplines to address modern global sustainability and climate challenges.

  • The Bioeconomy & Biorefineries: Replacing fossil-fuel-based economies by converting organic waste (environmental engineering) via microbial fermentation (biotechnology) into biofuels and bioplastics based on organic chemistry principles (bioscience).

  • Waste-to-Energy Systems: Using anaerobic digestion and microbial fuel cells to process sewage sludge and municipal solid waste while simultaneously generating electricity or methane gas.

  • Carbon Capture and Biological Sequestration: Engineering microalgae photobioreactors to capture industrial carbon dioxide emissions and convert them into valuable biomass, protein sources, or biofuels.

  • Synthetic Biology for Environmental Sustainability: Designing entirely synthetic metabolic pathways in microorganisms to degrade highly persistent modern pollutants, such as microplastics, PFAS ("forever chemicals"), and pharmaceutical residues