RoboSynAI: The Convergence of AI, Robotics, and Synthetic Biology RoboSynAI—the deep integration of artificial intelligence (AI), robotics, and synthetic biology—is reshaping industries such as healthcare, manufacturing, energy, and environmental sustainability. This multidisciplinary fusion acceler … RoboSynAI: The Convergence of AI, Robotics, and Synthetic BiologyRead more
CRISPR
In Vivo Delivery: Applications in Gene Therapy, Tumor Targeting, and Personalized Medicine
In Vivo Delivery: Applications in Gene Therapy, Tumor Targeting, and Personalized Medicine In vivo delivery refers to the direct administration of bioactive substances (e.g., gene-editing tools, nucleic acid drugs, proteins) into target tissues or cells within a living organism. Its core value lies … In Vivo Delivery: Applications in Gene Therapy, Tumor Targeting, and Personalized MedicineRead more
Self-Healing Materials in Life Sciences: Definitions, Mechanisms, and Applications
Self-Healing Materials in Life Sciences: Definitions, Mechanisms, and Applications Self-healing materials are intelligent substances capable of autonomously repairing physical damage (e.g., cracks, fractures) or functional degradation through intrinsic or extrinsic mechanisms. In life sciences, this … Self-Healing Materials in Life Sciences: Definitions, Mechanisms, and ApplicationsRead more
Bio AI Genome: AI-Driven Systems for Genome Analysis, Editing, and Simulation
Bio AI Genome: AI-Driven Systems for Genome Analysis, Editing, and Simulation Bio AI Genome represents the convergence of artificial intelligence (AI) and genomics, leveraging machine learning (ML), deep learning (DL), and large language models (LLMs) to enable precise genome decoding, efficient edi … Bio AI Genome: AI-Driven Systems for Genome Analysis, Editing, and SimulationRead more
Splice Genes: The Architecture and Functional Core of Eukaryotic Genomes
Splice Genes: The Architecture and Functional Core of Eukaryotic Genomes Splice genes—characterized by protein-coding exons interspersed with non-coding introns—are a hallmark of eukaryotic genomes. These genes require RNA splicing to remove introns and generate mature mRNA, serving as both a regula … Splice Genes: The Architecture and Functional Core of Eukaryotic GenomesRead more
Cure Genome: Permanent Genomic Defect Repair via Gene-Editing Technologies
Cure Genome: Permanent Genomic Defect Repair via Gene-Editing Technologies Breakthroughs in gene-editing technologies, particularly CRISPR-Cas9 system optimizations, have enabled precise strategies to permanently repair pathogenic genomic defects. By directly modifying DNA sequences or regulating ge … Cure Genome: Permanent Genomic Defect Repair via Gene-Editing TechnologiesRead more
Velo mRNA: Decoding Dynamic mRNA Patterns via RNA Velocity Theory
Velo mRNA: Decoding Dynamic mRNA Patterns via RNA Velocity Theory RNA velocity is a computational method that quantifies the relative abundance of unspliced and spliced mRNAs to reveal dynamic gene expression changes. By modeling transcriptional kinetics, it predicts future cellular states, enabling … Velo mRNA: Decoding Dynamic mRNA Patterns via RNA Velocity TheoryRead more
mRNA Velocity in Cancer: Advances in Transcription Rate Mutations and Therapeutic Prospects
mRNA Velocity in Cancer: Advances in Transcription Rate Mutations and Therapeutic Prospects mRNA velocity—defined as the elongation rate of RNA polymerase during transcription and the dynamic lifecycle of mRNA from synthesis to degradation—has emerged as a critical factor in cancer biology. Aberrant … mRNA Velocity in Cancer: Advances in Transcription Rate Mutations and Therapeutic ProspectsRead more