Visible Light Photocatalysis

可见光光催化

• 批准号: 8021452
• 负责人: TEHSHIK P YOON
• 金额: $ 28.29万
• 依托单位: UNIVERSITY OF WISCONSIN-MADISON
• 依托单位国家: 美国
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-12-01 至 2014-11-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8021452
• 关键词: Acids; Architecture; Biological; Chemicals; Chemistry; Communities; Complex; Cyclobutanes; Development; Dioxanes; Disease; Electrons; Equipment; Exhibits; Goals; Investigation; Ions; Island; Libraries; Life; Ligands; Light; Methodology; Methods; Modern Medicine; Modification; Molecular; Molecular Medicine; Molecular Structure; Oxidation-Reduction; Pattern; Pharmaceutical Preparations; Pharmacologic Substance; Phase; Process; Property; Reaction; Reagent; Relative (related person); Research; Role; Ruthenium; Source; Structure; Sunlight; System; Techniques; Ultraviolet Rays; Visible Radiation; base; catalyst; chemical reaction; chemical synthesis; combat; cost; cycloaddition; design; drug candidate; drug structure; fighting; human disease; innovation; insight; interest; next generation; novel; novel strategies; oxidation; programs; small molecule; stereochemistry

DESCRIPTION (provided by applicant): Photochemical methods are unique because (1) they enable the synthesis of unusual, strained molecular frameworks that cannot be synthesized by other methods, and (2) they use light, which is cleaner, less expensive, and more renewable than conventional chemical reagents. Nevertheless, pharmaceutical companies rarely take advantage of photochemical synthesis because the need for specialized photochemical equipment is an impractical impediment and because very few methods to control the stereochemistry of photochemical reactions exist. Therefore, the structures of the molecules that are produced by photochemical synthesis have essentially not been examined as possible drug candidates. This Proposal describes an innovative new strategy to perform photochemical reactions using readily available sources of visible light such as a consumer light bulb or ambient sunlight instead of a specialized photochemical reactor. Research will proceed in two phases: 1. Development of a photocatalytic system that is able to efficiently convert visible light energy into chemical reactivity with high levels of stereochemical control. 2. Application of this system to a variety of new chemical reactions that produce unusual molecular structures. These methods are powerful, robust, and simple to perform on large, industrially relevant scales. Thus, the research described in this proposal will significantly impact both the academic chemistry community and the broader community of medicinal chemists who require new methods of molecule construction to discover the next generation of life-saving drugs. PUBLIC HEALTH RELEVANCE: The function of a drug is determined by its structure, and drugs with similar structures tend to have similar effects on human disease. The discovery of new drugs that could treat currently incurable diseases, therefore, relies upon the ability of chemists to construct different kinds of molecules that differ significantly in structure from known medicinal agents. We are developing a conceptually novel approach to chemical synthesis that takes advantage of the clean, renewable energy in sunlight to construct complex, structurally unique molecules that may serve as templates for the discovery of the next generation of disease-fighting drugs.

描述（由申请人提供）：光化学方法是独特的，因为（1）它们能够合成其他方法无法合成的不寻常的、紧张的分子框架，（2）它们使用光，更清洁、更便宜，并且更有效。比传统化学试剂可再生。然而，制药公司很少利用光化学合成，因为需要专门的光化学设备是一个不切实际的障碍，而且控制光化学反应立体化学的方法很少。因此，通过光化学合成产生的分子的结构基本上尚未作为可能的候选药物进行检查。该提案描述了一种创新的新策略，使用现成的可见光源（例如消费者灯泡或环境阳光）而不是专门的光化学反应器来进行光化学反应。研究将分两个阶段进行： 1. 开发光催化系统，能够有效地将可见光能量转化为具有高水平立体化学控制的化学反应活性。 2.将该系统应用于各种产生不寻常分子结构的新化学反应。这些方法功能强大、稳健且易于在工业相关的大规模规模上执行。因此，该提案中描述的研究将对学术化学界和更广泛的药物化学家产生重大影响，他们需要新的分子构建方法来发现下一代救生药物。 公共卫生相关性：药物的功能由其结构决定，结构相似的药物往往对人类疾病具有相似的作用。因此，能够治疗目前无法治愈的疾病的新药的发现依赖于化学家构建结构与已知药剂显着不同的不同种类分子的能力。我们正在开发一种概念上新颖的化学合成方法，该方法利用阳光中的清洁、可再生能源来构建复杂、结构独特的分子，这些分子可以作为发现下一代抗病药物的模板。