Bioprinting & Tissue Engineering An Introduction Bioprinting and tissue engineering blend 3D printing, biomaterials, and cellular biology to recreate living tissues and organs. Researchers layer bio-inks—containing cells, hydrogels and growth factors—to design functional constructs. Applications range from skin grafts and cartilage support to vascularized organs. This interdisciplinary domain draws on regenerative medicine, additive manufacturing and scaffold design. Key semantic entities include extracellular matrix, stem cells and bio fabrication platforms. LSI keywords: organ printing, regenerative scaffolds, biopolymer hydrogels. NLP‑related terms: cell viability prediction, tissue morphology classification, annotation pipeline. Historical Development & Key Milestones The evolution of bioprinting began with inkjet printing of living cells in the early 2000s. Subsequent breakthroughs involved micro extrusion and laser-assisted systems. In 2013 researchers printed a mi...
Synthetic Biology Introduction and Overview Synthetic biology , an emerging frontier in science, merges molecular biology, genetic engineering, and systems biology to design novel biological systems. By constructing new DNA sequences or reprogramming living organisms, researchers aim to address global challenges—from sustainable manufacturing to precision medicine. This interdisciplinary field draws on bioengineering, metabolic engineering, and genome editing methods. CRISPR‑Cas9 , plasmid assembly and gene circuits all feature prominently. As ethical debates and regulatory frameworks evolve, synthetic biology promises transformative applications in agriculture, energy and diagnostics. LSI keywords: synthetic genomics, biological systems, DNA synthesis. Historical Roots: From Recombinant DNA to Synthetic Genomes Synthetic biology’s roots trace back to recombinant DNA techniques developed in the 1970s, enabling scientists to splice and clone genes. Subsequent advances in mol...