化学信息学及其课程建设

化学信息学是化学学科的新兴分支 ,本文简单介绍了化学信息学的起源与现状 ,并对化学信息学的定义、研究内容以及化学信息学课程的建设进行了探讨     

第九届全国计算（机）化学学术会议（第一轮通知）

主办单位:中国化学会计算机化学专业委员会协办单位:化学生物传感与计量学国家重点实验室(湖南大学)承办单位:四川大学国际计算机化学包括化学信息学研究的发展方兴未艾,近几年来伴随着理论与计算化学、分子模拟与设计、数据挖掘技术,因特网资源综合利用以及化学计量学等领域的发展,取得了令世人瞩目的重要进展.我国的计算(机)化学包括化学信息学研究也伴随着这些学科的飞速进步得到快速发展,通过学科相互交叉、相互渗透,目前发展快速、成效显著,在某些研究方面接近或达到国际先进水平.为更好地总结、交流我国在计算(机)化学包括化学信息学…     

化学基元组学与药物创新

化学基元组学（chemomics）是与化学信息学、生物信息学、合成化学等学科相关的交叉学科．生物系统从内源性小分子（天然砌块）出发,通过酶催化的化学反应序列制造天然产物．生物系统通过化学反应和天然砌块向目标天然产物“砌入”一组原子,这样的一组原子称为化学基元（chemoyl）．化学基元组（chemome）是生物组织中所含有的化学基元的全体．化学基元组学研究各种化学基元的结构、组装与演化的基本规律．在生存压力和繁衍需求的驱动下,生物系统已经进化出有效手段来合成天然产物以应付环境的变化,并产生了丰富多彩的生物和化学多样性．近年来,人们意识到药物创新的瓶颈之一是药物筛选资源的日益枯竭．化学基元组学可以解决这个瓶颈问题,它通过揭示生物系统制备化学多样性的规律,发展仿生合成方法制备类天然化合物库（quasi natural product libraries）以供药物筛选．本文综述了化学基元组学的主要研究内容及其在药物创新各领域中的潜在应用．     

化学基元组学与药物创新

化学基元组学(chemomics)是与化学信息学、生物信息学、合成化学等学科相关的交叉学科.生物系统从内源性小分子(天然砌块)出发,通过酶催化的化学反应序列制造天然产物.生物系统通过化学反应和天然砌块向目标天然产物"砌入"一组原子,这样的一组原子称为化学基元(chemoyl).化学基元组(chemome)是生物组织中所含有的化学基元的全体.化学基元组学研究各种化学基元的结构、组装与演化的基本规律.在生存压力和繁衍需求的驱动下,生物系统已经进化出有效手段来合成天然产物以应付环境的变化,并产生了丰富多彩的生物和化学多样性.近年来,人们意识到药物创新的瓶颈之一是药物筛选资源的日益枯竭.化学基元组学可以解决这个瓶颈问题,它通过揭示生物系统制备化学多样性的规律,发展仿生合成方法制备类天然化合物库(quasi natural product libraries)以供药物筛选.本文综述了化学基元组学的主要研究内容及其在药物创新各领域中的潜在应用.     

计算(机)化学学科进展(2011-2013)

计算(机)化学已成为化学学科的重要组成部分,在理论计算、分子模拟、数据挖掘以及复杂体系分析中发挥了重要作用。本文总结了近年来化学信息学的研究进展,包括化学信息学方法、软件及数据库技术以及化学信息学在结构、性质、相互作用、反应机理,蛋白质及功能材料的性能研究,复杂体系化学数据分析中的应用。共引用参考文献78篇。     

药物化学教学中引入精准教学策略的探索与研究*

从提高学生学习积极性、改良教学方法、优化评价考核方式等方面对药物化学教学进行了探索与研究。提出基于LBL和PBL教学法,在药物化学教学中引入精准教学策略。分析了PBL和LBL 教学法相结合的优点,以及在药物化学教学中的应用情况。事实证明,在药物化学教学中引入精准教学策略,有助于弥补传统教学方法的不足,在提高学生学习积极性和主动性、提高教学质量、改善教学效果、培养学生综合能力等方面具有重要意义。     

化学信息学网络化教学系统的研制

本文介绍了化学信息学的基本概念与基本内容 ,并重点介绍了我们建立的基于Internet的网络化教学系统。该系统包括课堂教学系统、作业系统以及教学需要的其他内容 ,由HTML文件构成 ,可通过浏览器 (Netscape或InternetExplorer等 )直接调用 ,用于化学信息学课程的教学工作。     

Internet推动的化学信息学重要进展*

Internet的普及为专业人员获取数据信息、利用计算工具提供了统一的平台,由此为化学信息学的发展带来了新的空间,推动了化学信息学以网络为基础,以化学相关的数据、信息及计算资源共享为目标的快速发展。本文将从不同侧面回顾近10年来化学信息学的重要进展, 包括：(1) 网络化学信息检索：索引对象从化学浅层网向化学深层网发展;检索工具从Web化学信息资源导航向化学专业搜索引擎(包括文本信息和化合物标识信息)、及化学深层网检索引擎 (化合物物性数据提取)发展;索引粒度从Web站点向页面、乃至页面中的特定内容发展,一般页面特定内容的数据提取(即非结构化数据提取)是未来发展的方向。(2)可共享的化学数据库：从可免费访问和使用的化学数据库向数据库内容通过集成多来源数据(包括数据库拥有者主动收集、多来源数据主动提交达到共享的方式,repository)实现数据库内容免费下载和共享,以及不同数据库之间的相关内容实现无缝连接的方向发展(如NIH建成的药物小分子共享数据库PubChem)。(3) 开源(open source)化学软件工具包：从化学结构基本处理模块如CDK、JOELib向集成开发环境如化学信息学与生物信息学集成环境Bioclipse发展。(4) 与化合物及其数据共享相关的推荐标准：包括用于共享数据交换的化学标记语言CML、IUPAC推荐的学术论文相关热力学实验数据提交标准ThermoML及化合物结构唯一描述码InChI。(5) 计算化学资源共享及基于网格的应用：从可执行程序的下载向在线计算、基于网格的应用发展。(6) eChemistry和虚拟研究环境：网络也成为化学相关日常的科学活动中不可缺少的平台。构建以网络为平台、支持开展科研活动的数字化基础设施和服务的eChemstry探索开始出现,根据需要自主集成多来源数据和计算资源,形成不同层次的支持协同工作的虚拟研究环境是未来数据和计算资源共享方式的发展方向。     

化学教育研究:基本特征与方法设计

在综述相关国际文献的基础上,通过对化学教育研究与化学研究、一般教育研究、其他化学教育活动的辨析,讨论了化学教育研究的特征、化学教育研究者的专业要求以及化学教育研究设计在理论基础、研究问题和研究方法等方面所应遵循的基本规范,以期提高对化学教育研究的认识,提升我国化学教育研究的科学化水平,促进化学教育研究领域的发展。     

大学本科化学信息学课程的设计与优化

在分析了化学信息学课程基本内容与特点的基础之上,结合近年来我院相关课程的教学改革与实践,提出了大学化学信息学教学的两个层次;重点探讨了本科生化学信息学课程体系的设计与优化,为推进化学信息学教学改革抛砖引玉。     

Quantifying the relationships among drug classes

The similarity of drug targets is typically measured using sequence or structural information. Here, we consider chemo-centric approaches that measure target similarity on the basis of their ligands, asking how chemoinformatics similarities differ from those derived bioinformatically, how stable the ligand networks are to changes in chemoinformatics metrics, and which network is the most reliable for prediction of pharmacology. We calculated the similarities between hundreds of drug targets and their ligands and mapped the relationship between them in a formal network. Bioinformatics networks were based on the BLAST similarity between sequences, while chemoinformatics networks were based on the ligand-set similarities calculated with either the Similarity Ensemble Approach (SEA) or a method derived from Bayesian statistics. By multiple criteria, bioinformatics and chemoinformatics networks differed substantially, and only occasionally did a high sequence similarity correspond to a high ligand-set similarity. In contrast, the chemoinformatics networks were stable to the method used to calculate the ligand-set similarities and to the chemical representation of the ligands. Also, the chemoinformatics networks were more natural and more organized, by network theory, than their bioinformatics counterparts: ligand-based networks were found to be small-world and broad-scale.     

The Blue Obelisk-interoperability in chemical informatics

The Blue Obelisk Movement (http://www.blueobelisk.org/) is the name used by a diverse Internet group promoting reusable chemistry via open source software development, consistent and complimentary chemoinformatics research, open data, and open standards. We outline recent examples of cooperation in the Blue Obelisk group: a shared dictionary of algorithms and implementations in chemoinformatics algorithms drawing from our various software projects; a shared repository of chemoinformatics data including elemental properties, atomic radii, isotopes, atom typing rules, and so forth; and Web services for the platform-independent use of chemoinformatics programs.     

Schrödinger药物虚拟筛选流程模块在大学生物和化学信息学教学中的应用

介绍了Schr?dinger药物虚拟筛选的基本原理和流程,结合大学生物和化学信息学课程的相关教学内容,分别描述了蛋白受体的预处理、类药性五原则、毒药物动力学(ADME)、泛筛选干扰化合物(PAINS)、高通量虚拟筛选、标准精度筛选、高精度筛选和MM/GBSA的打分排序原理和使用方法。该软件可以在大学生物和化学信息学的教学中演示,有助于提高学生对蛋白结构、分子构象、药物虚拟筛选和计算机辅助分子设计的理解,该软件有很好的图形界面,可以给学生直观的体验,大大丰富了大学课堂的教学内容。此外,该软件在药物设计领域里面也有很好的应用价值,大大节约了药物筛选的成本,提高了药物发现的效率。     

Molecular property diagnostic suite (MPDS): Development of disease-specific open source web portals for drug discovery$

Abstract

Molecular property diagnostic suite (MPDS) is a Galaxy-based open source drug discovery and development platform. MPDS web portals are designed for several diseases, such as tuberculosis, diabetes mellitus, and other metabolic disorders, specifically aimed to evaluate and estimate the drug-likeness of a given molecule. MPDS consists of three modules, namely data libraries, data processing, and data analysis tools which are configured and interconnected to assist drug discovery for specific diseases. The data library module encompasses vast information on chemical space, wherein the MPDS compound library comprises 110.31 million unique molecules generated from public domain databases. Every molecule is assigned with a unique ID and card, which provides complete information for the molecule. Some of the modules in the MPDS are specific to the diseases, while others are non-specific. Importantly, a suitably altered protocol can be effectively generated for another disease-specific MPDS web portal by modifying some of the modules. Thus, the MPDS suite of web portals shows great promise to emerge as disease-specific portals of great value, integrating chemoinformatics, bioinformatics, molecular modelling, and structure- and analogue-based drug discovery approaches.     

Web service infrastructure for chemoinformatics

The vast increase of pertinent information available to drug discovery scientists means that there is a strong demand for tools and techniques for organizing and intelligently mining this information for manageable human consumption. At Indiana University, we have developed an infrastructure of chemoinformatics Web services that simplifies the access to this information and the computational techniques that can be applied to it. In this paper, we describe this infrastructure, give some examples of its use, and then discuss our plans to use it as a platform for chemoinformatics application development in the future.     

Chemomics and drug innovation

Chemomics is an interdisciplinary study using approaches from chemoinformatics,bioinformatics,synthetic chemistry,and other related disciplines.Biological systems make natural products from endogenous small molecules (natural product building blocks) through a sequence of enzyme catalytic reactions.For each reaction,the natural product building blocks may contribute a group of atoms to the target natural product.We describe this group of atoms as a chemoyl.A chemome is the complete set of chemoyls in an organism.Chemomics studies chemomes and the principles of natural product syntheses and evolutions.Driven by survival and reproductive demands,biological systems have developed effective protocols to synthesize natural products in order to respond to environmental changes;this results in biological and chemical diversity.In recent years,it has been realized that one of the bottlenecks in drug discovery is the lack of chemical resources for drug screening.Chemomics may solve this problem by revealing the rules governing the creation of chemical diversity in biological systems,and by developing biomimetic synthesis approaches to make quasi natural product libraries for drug screening.This treatise introduces chemomics and outlines its contents and potential applications in the fields of drug innovation.     

Some solved and unsolved problems of chemoinformatics

The field of chemoinformatics has developed from different roots, starting in the 1960s. These branches have now merged into a scientific discipline of its own, exchanging ideas and methods across different areas of chemistry. In the last 40 years chemoinformatics has achieved a lot. Without access to the databases in chemistry developed with chemoinformatics methods, modern chemical research would not be able to work at its present high level of competence. However, there are quite a few challenges, such as drug design and understanding the effect of chemicals on human health and on the environment, as well as furthering our knowledge of chemistry and of biological systems, that can benefit from a more intensive use of chemoinformatics methods. Approaches to meet these challenges will be briefly outlined. All this emphasizes that chemoinformatics has matured into a scientific discipline of its own that reaches out to many other chemical fields and will increase in attractiveness to students and researchers.     

Progress on open chemoinformatic tools for expanding and exploring the chemical space

Journal of Computer-Aided Molecular Design - The concept of chemical space is a cornerstone in chemoinformatics, and it has broad conceptual and practical applicability in many areas of chemistry,...