基于LDA模型的中医药人工智能领域主题演化分析＊

目的 梳理总结中医药人工智能领域近40年的研究情况，分析该领域研究主题演化过程，发现热点主题和研究前沿。方法 本研究检索了CNKI和WOS中中医药人工智能领域的文献，根据生命周期理论划分不同时间片，将文献摘要作为研究对象，采用LDA主题模型挖掘文本主题，分析主题的演化过程，识别热点主题。结果 纳入中英文文献2750篇，根据生命周期理论划分中医药人工智能领域发展阶段，分别建立全局和各阶段的LDA模型，挖掘出全局热点主题有中医专家系统、中医辅助诊断系统、中医药数据挖掘等，发现主题演化路径并进行可视化展示。结论 中医药与人工智能主要的结合点在中医智能系统、中医药知识组织和中医智能诊疗机器人这3方面，这3个方向的研究均离不开神经网络技术的支持，同时也结合了关联规则发现、复杂网络研究等方法。     

The evo-devo origins of the nasopharynx

The process by which upper respiratory tract structures have changed over deep evolutionary time is, in part, reflected in the process of embryologic development. The nasopharynx in particular is a centrally located space bounded by components of the respiratory portion of the nasal cavity, cranial base, soft palate, and Eustachian tube. The development of these components can be understood both in terms of embryologic structures such as the branchial arches and paraxial mesoderm and through fossil evidence dating as far back as the earliest agnathan fish of the Cambrian Period. Understanding both the evolution and development of these structures has been an immeasurable benefit to the otolaryngologist seeking to model disease etiology of both common and rare conditions. This discussion is a primer for those who may be unfamiliar with the central importance of the nasopharynx both in terms of our evolutionary history and early embryological development of vital cranial and upper respiratory tract structures.     

冠状病毒特征与进化优势

冠状病毒是近年来新发突发传染病的重要来源,因家族成员庞大、宿主谱广、突变株多样,在进化中展示了其优越性。本文通过回顾冠状病毒基因组特征、感染宿主动物与受体分布及基因突变等方面的研究进展,对其在进化和传播中存在的优势进行总结和讨论,以期引起对相关病毒防控的重视。     

芍药甘草汤的历史沿革与现代研究

芍药甘草汤最早见于张仲景《伤寒杂病论》,由白芍和甘草(炙)等比例配伍而成,具有养血敛阴、调和肝脾、缓急止痛之功效,用于血虚津伤和筋脉失濡所致的腿脚挛急、脘腹疼痛。被历代医家推崇并沿用至今,并且拓展出了应用范围。现代药理研究表明,芍药甘草汤具有显著的解痉、止痛、镇咳、平喘及抗炎等作用,用于治疗痉挛性疾病、疼痛性疾病、炎症性疾病、支气管哮喘及妇产科疾病等。笔者从芍药甘草汤的历史沿革与方义衍变、组方配伍分析、药理药效学研究、现代临床应用4个方面进行系统阐述,以期为该经典名方的现代研究开发提供理论依据和文献参考,并为其制剂的临床定位提供理论和实践支撑。     

改革开放以来中医药文化发展的演进与特点探析＊

中医药文化是中医药事业发展的根基和灵魂，社会主义文化建设的重要组成。本文考察改革开放40年以来中医药文化发展的演进过程，从“社会矛盾—政策方针—中医药文化发展”的中观视角，构建了中医药文化发展分析模型，发现中医药文化先后经历了资产化发展（1978年-21世纪初）、情景化发展（21世纪初-中国共产党第十八次全国代表大会（中共十八大）前后）、生态化发展（中共十八大至今）三个阶段，每个阶段中医药文化发展的策略、重点和面临的问题具有明显的不同特点。因此，本文提出以社会矛盾为导向，优化政策引导，构建中医药文化生态体系，从个人、社会和国家发展的不同层面采取多元双向发展路径，推进健康中国发展，提升文化自信，打造文化强国。     

＊ 补充基金信息（立项部门，项目类型，课题名称，负责人信息）

病机是认识疾病病变的关键，抓住核心病机演变发展的规律，是中医临床诊疗的主旨和核心。病机兼化理论由中国中医科学院胡镜清研究员提出，用以从病机层面理解疑难复杂疾病病证关系和把握其演变规律，在明确疾病基本矛盾的同时，兼顾疾病的复杂性和多变性。文章通过构建新型冠状病毒肺炎病机兼化框架，揭示其病机演化规律，认为新冠肺炎属于“湿毒疫”范畴，湿毒始终是本病的病变核心，初期寒化，进展期热化，恢复期虚化是本病病机的传变方式。知本病之机，可未病先防，知病机传变，可截断扭转，有利于临床上增强对疾病发生发展趋势的预见性。     

Regeneration in anamniotes was replaced by regengrow and scarring in amniotes after land colonization and the evolution of terrestrial biological cycles

An evolutionary hypothesis explaining failure of regeneration among vertebrates is presented. Regeneration derives from postembryonic processes present during the life cycles of fish and amphibians that include larval and metamorphic phases with broad organ reorganizations. Developmental programs imprinted in their genomes are re-utilized with variations also in adults for regeneration. When vertebrates colonized land adopting the amniotic egg, some genes driving larval changes, and metamorphosis were lost and new genes evolved, further limiting regeneration. These included neural inhibitors for maintaining complex nervous systems, behavior and various levels of intelligence, and adaptive immune cells. The latter, that in anamniotes are executioners of metamorphic reorganization, became intolerant to embryonic-oncofetal-antigens impeding organ regeneration, a process that requires de-differentiation of adult cells and/or expansion of stem cells where these early antigens are formed. The evolution of terrestrial lifecycles produced vertebrates with complex bodies but no longer capable to regenerate their organs, mainly repaired by regengrow. Efforts of regenerative medicine to improve healing in humans should determine the diverse developmental pathways evolved between anamniotes and amniotes before attempting genetic manipulations such as the introduction of “anamniote regenerative genes” in amniotes. This operation may determine alteration in amniote developmental programs leading to teratomes, cancer, or death.     

Nutrition and its role in human evolution

Our understanding of human evolution has improved rapidly over recent decades, facilitated by large‐scale cataloguing of genomic variability amongst both modern and archaic humans. It seems clear that the evolution of the ancestors of chimpanzees and hominins separated 7–9 million years ago with some migration out of Africa by the earlier hominins; Homo sapiens slowly emerged as climate change resulted in drier, less forested African conditions. The African populations expanded and evolved in many different conditions with slow mutation and selection rates in the human genome, but with much more rapid mutation occurring in mitochondrial DNA. We now have evidence stretching back 300 000 years of humans in their current form, but there are clearly four very different large African language groups that correlate with population DNA differences. Then, about 50 000–100 000 years ago a small subset of modern humans also migrated out of Africa resulting in a persistent signature of more limited genetic diversity amongst non‐African populations. Hybridization with archaic hominins occurred around this time such that all non‐African modern humans possess some Neanderthal ancestry and Melanesian populations additionally possess some Denisovan ancestry. Human populations both within and outside Africa also adapted to diverse aspects of their local environment including altitude, climate, UV exposure, diet and pathogens, in some cases leaving clear signatures of patterns of genetic variation. Notable examples include haemoglobin changes conferring resistance to malaria, other immune changes and the skin adaptations favouring the synthesis of vitamin D. As humans migrated across Eurasia, further major mitochondrial changes occurred with some interbreeding with ancient hominins and the development of alcohol intolerance. More recently, an ability to retain lactase persistence into adulthood has evolved rapidly under the environmental stimulus of pastoralism with the ability to husband lactating ruminants. Increased amylase copy numbers seem to relate to the availability of starchy foods, whereas the capacity to desaturase and elongate monounsaturated fatty acids in different societies seems to be influenced by whether there is a lack of supply of readily available dietary sources of long‐chain polyunsaturated fatty acids. The process of human evolution includes genetic drift and adaptation to local environments, in part through changes in mitochondrial and nuclear DNA. These genetic changes may underlie susceptibilities to some modern human pathologies including folate‐responsive neural tube defects, diabetes, other age‐related pathologies and mental health disorders.     

Evolving insights: how DNA repair pathways impact cancer evolution

Viewing cancer as a large, evolving population of heterogeneous cells is a common perspective. Because genomic instability is one of the fundamental features of cancer, this intrinsic tendency of genomic variation leads to striking intratumor heterogeneity and functions during the process of cancer formation, development, metastasis, and relapse. With the increased mutation rate and abundant diversity of the gene pool, this heterogeneity leads to cancer evolution, which is the major obstacle in the clinical treatment of cancer. Cells rely on the integrity of DNA repair machineries to maintain genomic stability, but these machineries often do not function properly in cancer cells. The deficiency of DNA repair could contribute to the generation of cancer genomic instability, and ultimately promote cancer evolution. With the rapid advance of new technologies, such as single-cell sequencing in recent years, we have the opportunity to better understand the specific processes and mechanisms of cancer evolution, and its relationship with DNA repair. Here, we review recent findings on how DNA repair affects cancer evolution, and discuss how these mechanisms provide the basis for critical clinical challenges and therapeutic applications.