This book aims to provide an overview of the challenges and available technologies to improve rice and provide a response to the challenge posed by increasing world population and the resultant food shortages. Nutritional aspects of rice products and omics and the molecular technologies currently being used are covered in depth. As a staple food for over 50% of the worlds population, an estimated 9 billion people will need to be fed by 2050, and healthy and uncontaminated foods need to reach consumers in developed and developing countries.This makes quality beyond productivity incredibly important and is one of the overriding themes of this work. The Future of Rice Demand: Quality Beyond Productivity offers researchers a better understanding of the nutritional aspects of rice. Omics technologies applied to cereal grain quality have been scarce in the literature published to date, making this text an excellent single source for researchers in regions where rice is a major crop. The first section of the book focuses on the major aspects of the industrial processing of all rice types. Further sections look at contamination prevention and biofortification, special rice types, and omics and other molecular tools used in the mass production and processing of healthy rice products.

This book aims to provide an overview of the challenges and available technologies to improve rice and provide a response to the challenge posed by increasing world population and the resultant food shortages. Nutritional aspects of rice products and omics and the molecular technologies currently being used are covered in depth. As a staple food for over 50% of the worlds population, an estimated 9 billion people will need to be fed by 2050, and healthy and uncontaminated foods need to reach consumers in developed and developing countries.This makes quality beyond productivity incredibly important and is one of the overriding themes of this work. The Future of Rice Demand: Quality Beyond Productivity offers researchers a better understanding of the nutritional aspects of rice. Omics technologies applied to cereal grain quality have been scarce in the literature published to date, making this text an excellent single source for researchers in regions where rice is a major crop. The first section of the book focuses on the major aspects of the industrial processing of all rice types. Further sections look at contamination prevention and biofortification, special rice types, and omics and other molecular tools used in the mass production and processing of healthy rice products.

With the predicted increase of the human population and the subsequent need for larger food supplies, root health in crop plants could play a major role in providing sustainable highly productive crops that can cope with global climate changes. While the essentiality of roots and their relation to plant performance is broadly recognized, less is known about their role in plant growth and development. "Root Genomics" examines how various new genomic technologies are rapidly being applied to the study of roots, including high-throughput sequencing and genotyping, TILLING, transcription factor analysis, comparative genomics, gene discovery and transcriptional profiling, post-transcriptional events regulating microRNAs, proteome profiling and the use of molecular markers such as SSRs, DArTs, and SNPs for QTL analyses and the identification of superior genes/alleles. The book also covers topics such as the molecular breeding of crops in problematic soils and the responses of roots to a variety of stresses.

With the predicted increase of the human population and the subsequent need for larger food supplies, root health in crop plants could play a major role in providing sustainable highly productive crops that can cope with global climate changes. While the essentiality of roots and their relation to plant performance is broadly recognized, less is known about their role in plant growth and development. Root Genomics examines how various new genomic technologies are rapidly being applied to the study of roots, including high-throughput sequencing and genotyping, TILLING, transcription factor analysis, comparative genomics, gene discovery and transcriptional profiling, post-transcriptional events regulating microRNAs, proteome profiling and the use of molecular markers such as SSRs, DArTs, and SNPs for QTL analyses and the identification of superior genes/alleles. The book also covers topics such as the molecular breeding of crops in problematic soils and the responses of roots to a variety of stresses.