Stress-Resilient Crops

Dr. Jen-Tsung Chen is a professor of cell biology at the National University of Kaohsiung in Taiwan. He teaches cell biology, genomics, proteomics, plant physiology, and plant biotechnology. Dr. Chen's research interests include bioactive compounds, chromatography techniques, plant molecular biology, plant biotechnology, bioinformatics, and systems pharmacology. He is an active editor of academic books and international journals to advance the exploration of multidisciplinary knowledge involving plant physiology, plant biotechnology, nanotechnology, materials science, ethnopharmacology, and systems biology. He serves as an associate editor, editorial board member, and guest editor in reputed journals. Dr. Chen has published books in collaboration with international publishers and is currently handling book projects on diverse topics, including AI technologies, drug discovery, drug development, herbal medicine, medicinal biotechnology, nanotechnology, bioengineering, plant functional genomics, plant speed breeding, epigenetics, functional RNAs, and CRISPR-based genome editing. Dr. Chen is a productive author in academic publications and was recognized as one of the World's Top 2% Scientists between 2023 to 2025 by Elsevier and Stanford University. Dr. Chen received the Springer Nature Editor of Distinction Award in 2025.

Chapter 1: Developing Nutritionally-Enhanced Crop through Approaches of Functional Genomic and CRISPR/Cas Technologies Chapter 2: High-Yield Crops Developed by Climate-Resilient Strategies Chapter 3: Disease-Resistant Crops: Plant Protection through Nanotechnology and CRISPR- Enhanced Plant Immunity Chapter 4: Salinity-Resilient Crops Reprogramed Using Modern Molecular-Nanotechnology Tools Chapter 5: Future Crop Designing: Anti-Stress Capacities Gained by CRISPR-mediated Releasing the Potent of Functional Genomes Chapter 6: Mitigating Abiotic Stress using Nanoparticles and Involved Cellular Processes studied by Multiple Omics Chapter 7: Smart and Stress-Resilient Agriculture Achieved by Engineered Nanomaterials and Nanobiotechnology Chapter 8: Abiotic Stress Resilience of CRISPR-Edited Crops and Underlying Mechanisms Dissected by High-Throughput Omics Technologies Chapter 9: Food and Nutritional Security Achieved by Coordinated Nanotechnology-Omics-CRISPR Strategies Chapter 10: Exploring the Interaction of Nanomaterials with Crops Based on Multiple OMICS Tools Chapter 11: Stress Resilient Crops: Advanced Breeding Using Coordinated Strategies against Changing Climate Chapter 12: Integrated Omics and CRISPR Tools for Speed and Precision Genetic Engineering in Crops Chapter 13: Reprograming Epigenomes by CRISPR-Based Technology Against Plant Diseases Chapter 14: Profiling Plant-Pathogen Interactions by Integrative Omics Tools Leads to Speed Breeding of CRISPR-Edited Disease-Tolerant Crops Chapter 15: Revealing Complicated Plant-microbial-nanoparticle Interactions using Bioinformatics and Multi-omics Tools Chapter 16: Dissecting Stress-Tolerant Traits of CRISPR-Edited Crops by High-Throughput Omics Technologies Chapter 17: Molecular Insights into CRISPR-Edited Pest Resistant Crops Studied by Multiple Omics Approaches Chapter 18: Multiple Omics Evaluation on Stress-Resilient CRISPR-Edited Crops in Single Cell and Spatially Resolution Chapter 19: Transgene-Free CRISPR-Edited Crops for Stress-Resilient Agriculture: Technological Advancements and Applications Chapter 20: Resilient Capacity against Rising Temperature gained by Coordinated Approaches of CRISPR/Cas with Functional Genomics Chapter 21: Multi-Stress Tolerant Crops: Identification and Functional Analysis of Hub Genes and Regulating Responses of Complicated Stressors Chapter 22: Climate-Smart Crops: Delivering Tolerant Genes Based on Engineered Nanocarriers and CRISPR/Cas Genome Editing System Chapter 23: Metagenomic Insights into Plant-Probiotic Bacterial Interactions Boosting Crop Growth and Yield Chapter 24: Plant Disease Resistance through CRISPR/Cas Genome Editing: Opportunities and Challenges