Polypyrrole-based Anion-Binding Agents

聚吡咯基阴离子结合剂

• 批准号: 6683516
• 负责人: Jonathan L Sessler
• 金额: $ 30.32万
• 依托单位: UNIVERSITY OF TEXAS AT AUSTIN
• 依托单位国家: 美国
• 财政年份: 1999
• 资助国家: 美国
• 起止时间: 1999-01-01 至 2008-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6683516
• 关键词: anions; antineoplastics; biohazard detection; biomaterial development /preparation; biotechnology; bioterrorism /chemical warfare; chemical binding; chemical kinetics; chloride ion; drug design /synthesis /production; drug receptors; fluorescent dye /probe; fluoride ion; hydrogen ions; immunosuppressive; ion transport; nerve gas; optics; oxalates; phosphates; pyrroles; reagent /indicator; spectrometry; thermodynamics

DESCRIPTION (provided by applicant): This ongoing project involves the use of pyrrole NH hydrogen bonding interactions to bind, transport, and sense anions of biological relevance. It builds on an approach to anion recognition that was first put forward by the P.I. and his coworkers almost a decade ago and which has evolved to the point where it is now being adopted by an increasing number of academic laboratories world-wide. Meanwhile, pyrrole-based anion recognition events have been invoked recently to explain the mode of action of prodigiosin, a naturally occurring tripyrrolic entity with promising immunosuppressive and anticancer activity. Similar NH-anion interactions are implicated in pathways promoted by L-pyrrolysine, a new genetically encoded amino acid discovered earlier this year. Thus, the incentive to make and study pyrrole-based anion receptors is greater than ever. This is true both with regard to probing the basic determinants of anion binding and in terms of generating systems capable of targeting problems of medical and public health importance. These latter are represented by such diverse challenges as anionic metabolite sensing, chemical warfare agent detection, control of phosphate and oxalate concentrations in patients suffering from kidney failure, and multiple opportunities in drug development. Work to date has established that i) pyrrole-based receptors can bind and sense such physiologically important anions as phosphate, chloride, and oxalate, as well as fluoride, in polar media, ii) the strength and selectivity of the binding process can be fine-tuned through structural modifications, and iii) polymers containing pyrrolic receptors can be made. It has also led to the finding that several polypyrrole systems developed in the P.l.'s laboratory display cytotoxicities that meet or exceed those of prodigiosin. The proposed research will thus focus on using new and extant pyrrole-based receptors to i) probe more fully the kinetics and thermodynamics of anion recognition, ii) generate phosphate and oxalate binding materials for treating end-stage renal disease, iii) create supported sensors for detecting the hydrolysis products of organophosphate nerve gases, and iv) develop lead compounds that can be taken forward as potential new anti-cancer drugs and immunosuppressive agents.

描述（由申请人提供）：该正在进行的项目涉及使用吡咯NH氢键相互作用来结合、运输和感知生物相关阴离子。它建立在一种阴离子识别方法的基础上，这种方法首先由P.I.和他的同事们在大约十年前提出的，并且已经发展到现在被世界范围内越来越多的学术实验室采用的地步。 同时，吡咯为基础的阴离子识别事件最近已被调用来解释灵菌红素，一种天然存在的triprophyrolic实体有前途的免疫抑制和抗癌活性的作用模式。 类似的NH-阴离子相互作用也与L-吡咯赖氨酸（今年早些时候发现的一种新的遗传编码氨基酸）促进的途径有关。 因此，制造和研究基于吡咯的阴离子受体的动机比以往任何时候都要大。 无论是在探索阴离子结合的基本决定因素方面，还是在生成能够针对医学和公共卫生重要性问题的系统方面，都是如此。 后者的代表是各种挑战，如阴离子代谢物传感，化学战剂检测，控制磷酸盐和草酸盐浓度的患者患有肾衰竭，并在药物开发的多重机会。 迄今为止的工作已经确定，i）吡咯基受体可以在极性介质中结合和感测生理学上重要的阴离子，如磷酸根、氯离子和草酸根以及氟离子，ii）结合过程的强度和选择性可以通过结构修饰进行微调，和iii）可以制备含有吡咯受体的聚合物。 这也导致了在P.I.的实验室显示细胞毒性达到或超过灵菌红素。 因此，拟议的研究将集中于使用新的和现存的吡咯基受体来i）更充分地探测阴离子识别的动力学和热力学，ii）产生用于治疗终末期肾病的磷酸盐和草酸盐结合材料，iii）创建用于检测有机磷酸盐神经气体的水解产物的支持传感器，和iv）开发可作为潜在的新抗癌药物和免疫抑制剂的先导化合物。