Genetic engineering of plants is at the core of sustainability efforts,natural product synthesis,and agricultural crop improvement.The past several decades have brought remarkable progress in biotechnology with the im...Genetic engineering of plants is at the core of sustainability efforts,natural product synthesis,and agricultural crop improvement.The past several decades have brought remarkable progress in biotechnology with the improvement of genome editing and sequencing tools,which stand to advance plant synthetic biology and bioengineering.In agriculture,genetic engineering can be employed to create crops that have in creased yields and nu tritio nal value,are resista nt to herbicides,in sects,diseases,and abiotic stresses,in cludi ng drought and heat .In pharmaceuticals and therapeutics,genetically engineered plants can be used to synthesize valuable small-molecule drugs and recombinant proteins.展开更多
Microscopic imaging of the brain continues to reveal details of its structure, connectivity, and function. To further improve our understanding of the emergent properties and functions of neural circuits, we need to d...Microscopic imaging of the brain continues to reveal details of its structure, connectivity, and function. To further improve our understanding of the emergent properties and functions of neural circuits, we need to directly visualize the relationship between brain structure, neuron activity, and neurochemistry. Advances in the chemical and optical properties of nanomaterials, and developments in deep-tissue microscopy, may help to overcome the current challenges of in-vivo brain imaging, particularly when imaging the brain through optically-dense brain tissue, skull, and scalp. Developments in nanomaterials may enable the implementation of tunable chemical functionality for neurochemical targeting and sensing, and fluorescence stability for long-term imaging. In this review, we summarize the current methods used for brain microscopy and describe the diverse classes of nanomaterials recently offered as contrast agents and functional probes for microscopic optical imaging of the brain.展开更多
文摘Genetic engineering of plants is at the core of sustainability efforts,natural product synthesis,and agricultural crop improvement.The past several decades have brought remarkable progress in biotechnology with the improvement of genome editing and sequencing tools,which stand to advance plant synthetic biology and bioengineering.In agriculture,genetic engineering can be employed to create crops that have in creased yields and nu tritio nal value,are resista nt to herbicides,in sects,diseases,and abiotic stresses,in cludi ng drought and heat .In pharmaceuticals and therapeutics,genetically engineered plants can be used to synthesize valuable small-molecule drugs and recombinant proteins.
文摘Microscopic imaging of the brain continues to reveal details of its structure, connectivity, and function. To further improve our understanding of the emergent properties and functions of neural circuits, we need to directly visualize the relationship between brain structure, neuron activity, and neurochemistry. Advances in the chemical and optical properties of nanomaterials, and developments in deep-tissue microscopy, may help to overcome the current challenges of in-vivo brain imaging, particularly when imaging the brain through optically-dense brain tissue, skull, and scalp. Developments in nanomaterials may enable the implementation of tunable chemical functionality for neurochemical targeting and sensing, and fluorescence stability for long-term imaging. In this review, we summarize the current methods used for brain microscopy and describe the diverse classes of nanomaterials recently offered as contrast agents and functional probes for microscopic optical imaging of the brain.
