口腔未培养微生物分离培养策略的研究进展

口腔微生物是人体微生物组的重要组成部分,其群落组成丰富且独特。现有研究显示,口腔微生物与龋病、牙周炎等口腔健康问题有直接的联系,因而具有重要的研究价值。随着高通量测序技术的发展,人们对口腔中未培养微生物多样性的认识不断加深,这进一步催生对微生物分离培养技术需求的增加。为此,本文将围绕口腔未培养微生物及其分离培养策略的研究进展,首先介绍口腔中未培养微生物的研究现状;其次分析口腔微生物分离培养中可能的限制因素;最后综述微生物分离培养技术发展及其在口腔未培养微生物研究中的应用。全文旨在为口腔未培养微生物的分离培养提供思路和技术参考。     

Rodent and germplasm trafficking: risks of microbial contamination in a high-tech biomedical world

High-tech biomedical advances have led to increases both in the number of mice used for research and in exchanges of mice and/or their tissues between institutions. The latter are associated with the risk of dissemination of infectious agents. Because of the lack of international standardization of health surveillance programs, health certificates for imported rodents may be informative but may not address the needs of the importing facility. Preservation of mouse germplasm is achieved by cryopreservation of spermatozoa, embryos, or ovaries, and embryonic stem cells are used for the production of genetically engineered mice. After embryo transfer, recipients and rederived pups that test negative in microbiological screening for relevant microorganisms are released into full barrier holding areas. However, current research shows that embryos may also transmit microorganisms, especially viruses, to the recipient mice. In this article, we discuss regulations and practical issues in the shipping of live mice and mouse tissues, including spermatozoa, embryos, ovaries, and embryonic stem cells, and review work on microbial contamination of these biological materials. In addition, we present ways to reduce the risk of transmission of pathogens to mice under routine conditions.     

Galectins: an evolutionarily conserved family of animal lectins with multifunctional properties; a trip from the gene to clinical therapy.

Galectins constitute a family of evolutionarily conserved animal lectins, which are defined by their affinity for poly-N-acetyllactosamine-enriched glycoconjugates and sequence similarities in the carbohydrate recognition domain. During the past decade, attempts to dissect the functional role for galectins in vivo have been unsuccessful in comparison to the overwhelming information reached at the biochemical and molecular levels. The present review deals with the latest advances in galectin research and is aimed at validating the functional significance of these carbohydrate-binding proteins. Novel implications of galectins in cell adhesion, cell growth regulation, immunomodulation, apoptosis, inflammation, embryogenesis, metastasis and pre-mRNA splicing will be particularly discussed in a trip from the gene to the clinical therapy. Elucidation of the molecular mechanisms involved in galectin functions will certainly open new avenues not only in biomedical research, but also at the level of disease diagnosis and clinical intervention, attempting to delineate new therapeutic strategies in autoimmune diseases, inflammatory processes, allergic reactions and tumor spreading.     

Characterization of Functional Primary Cilia in Human Induced Pluripotent Stem Cell-Derived Neurons

Neurochemical Research - Recent advances in human induced pluripotent stem cells (hiPSCs) offer new possibilities for biomedical research and clinical applications. Neurons differentiated from...     

Why is revitalizing clinical research so important, yet so difficult?

We believe that support for academic clinical research has greatly declined in recent decades. Here we discuss our views on why this has happened. We define clinical or patient-oriented research as limited to the study of human beings or populations of individuals, and argue that its eclipse in favor of basic and "translational" research is the result of inappropriate conceptual paradigms or "models" for medical advances. We believe that medical history shows that the "bench-to-bedside" model is inadequate to explain most recent progress and that clinical advances themselves often lead to new basic research. Discussion of alternate conceptual frameworks for biomedical research should help lead to changes in funding and organizational structures that might finally revitalize clinical research.     

活体生物药：生物技术推动的创新药研发前沿

随着微生物组学研究的深入,越来越多的研究证据显示微生物与人体的健康密切相关。20世纪,人们发现了益生菌,并将其作为有健康功效的食品或膳食补充剂使用。21世纪以来,随着人体微生物组学、DNA合成与测序,以及基因编辑等技术的飞速发展,微生物在人体健康方面展示出更为广阔的应用前景。近年来,在新药研发上,提出了“下一代益生菌”的概念,将微生物作为“活体生物药(live biotherapeutic products,LBP)”进行研究和开发。简单地说,LBP是活菌药物,可以用于预防或治疗人类的某些疾病和适应症。LBP因其独特的优势,成为了新药研发领域的前沿方向,具有十分广阔的发展前景。本文着重从生物技术角度介绍LBP的类型和研究进展,并总结了LBP开发所面临的挑战以及对未来的展望,以期为LBP技术的发展与产品开发提供参考。     

Ethical issues in translational research

The translation of biomedical research knowledge to effective clinical treatment is essential to the public good and is a main focus of current health policy. However, recent health policy initiatives intended to foster the translation of basic science into clinical and public health advances must also consider the unique bioethical issues raised by the increased focus on translational research. Safety of study participants and balancing of risk due to treatment with the potential benefits of the research is tantamount. This article synthesizes theory from clinical ethics, operational design, and philosophy to provide a bioethical framework for the health policy of translational research.     

微藻趋向运动及其靶向运输应用研究进展

微藻主要是指一类能进行光合自养的微生物,且很多藻株还兼具运动特性.因而将微藻与微流控芯片结合,实现精确靶向,或用于分子药物递送,在生物医学治疗和药效学分析等领域有重要的潜在应用价值,也是当今的研究热点之一.然而,目前关于微藻趋向运动的研究及潜在的应用的综述报道却相对较少.本文主要以模式微藻莱茵衣藻为例,概述基于微藻细胞...     

Recent progress in mass spectrometry proteomics for biomedical research

Proteins are the key players in many cellular processes. Their composition, trafficking, and interactions underlie the dynamic processes of life. Furthermore, diseases are frequently accompanied by malfunction of proteins at multiple levels. Understanding how biological processes are regulated at the protein level is critically important to understanding the molecular basis for diseases and often shed light on disease prevention, diagnosis, and treatment. With rapid advances in mass spectrometry (MS) instruments and experimental methodologies, MS-based proteomics has become a reliable and essential tool for elucidating biological processes at the protein level. Over the past decade, we have witnessed great expansion of knowledge of human diseases with the application of MS-based proteomic technologies, which has led to many exciting discoveries. Herein we review the recent progress in MS-based proteomics in biomedical research, including that in establishing disease-related proteomes and interactomes. We also discuss how this progress will benefit biomedical research and clinical diagnosis and treatment of disease.     

The clinical impact of recent advances in LC-MS for cancer biomarker discovery and verification

Mass spectrometry (MS) -based proteomics has become an indispensable tool with broad applications in systems biology and biomedical research. With recent advances in liquid chromatography (LC) and MS instrumentation, LC–MS is making increasingly significant contributions to clinical applications, especially in the area of cancer biomarker discovery and verification. To overcome challenges associated with analyses of clinical samples (for example, a wide dynamic range of protein concentrations in bodily fluids and the need to perform high throughput and accurate quantification of candidate biomarker proteins), significant efforts have been devoted to improve the overall performance of LC–MS-based clinical proteomics platforms. Reviewed here are the recent advances in LC–MS and its applications in cancer biomarker discovery and quantification, along with the potentials, limitations and future perspectives.     

宏基因组技术在开拓天然产物新资源中的应用

微生物代谢产物具有巨大的化学多样性,是多种抗生素和其它药物的重要来源。由于现有培养手段的局限性,可培养的微生物不到微生物总数的1％,使绝大部分微生物资源的开发利用受到制约。近年来．直接提取环境样品中混合微生物总基因组DNA,利用可培养的宿主细菌构建宏基因组文库,通过筛选目的克隆,寻找活性代谢产物,取得瞩目进展。对这一新领域的研究进展结合我们的研究概况进行了简要综述。     

嗜盐微生物在生物医药领域的应用研究进展

近年来抗生素耐药性问题日趋严重,患癌人数也在逐年增加,亟需开发新型药物。嗜盐微生物作为一类特殊的极端环境微生物,具有代谢多样性丰富、营养需求较低和能适应恶劣条件等特点,是发现新型药物的希望。目前,国内外学者已从嗜盐微生物中分离出了多种代谢产物和酶,具有明显的抗菌和/或抗肿瘤等活性。文中综述了嗜盐微生物及其相关产物在抗菌、抗炎、抗肿瘤、抗氧化、生物医学材料以及药物载体等生物医学方面的作用,尤其对近年来在嗜盐微生物中发现的新型抗菌和抗肿瘤物质以及嗜盐微生物特有的代谢产物四氢嘧啶等进行了总结,并对其后续在生物医药领域的开发和产业化应用进行了展望。     

Hairpins in bookstacks: information retrieval from biomedical text

Current advances in high-throughput biology are accompanied by a tremendous increase in the number of related publications. Much biomedical information is reported in the vast amount of literature. The ability to rapidly and effectively survey the literature is necessary for both the design and the interpretation of large-scale experiments, and for curation of structured biomedical knowledge in public databases. Given the millions of published documents, the field of information retrieval, which is concerned with the automatic identification of relevant documents from large text collections, has much to offer. This paper introduces the basics of information retrieval, discusses its applications in biomedicine, and presents traditional and non-traditional ways in which it can be used.     

Educating health-care professionals about genetics and genomics

To biomedical researchers, this is the 'genome era'. Advances in genetics and genomics such as the sequence of the human genome, the human haplotype map, open access databases, cheaper genotyping and chemical genomics have already transformed basic and translational biomedical research. However, for most clinicians, the genome era has not yet arrived. For genomics to have an effect on clinical practice that is comparable to its impact on research will require advances in the genomic literacy of health-care providers. Here we describe the knowledge, skills and attitudes that genomic medicine will require, and approaches to integrate them into the health-care community.     

Passive antibody therapy for infectious diseases

Antibody-based therapies are currently undergoing a renaissance. After being developed and then largely abandoned in the twentieth century, many antibody preparations are now in clinical use. However, most of the reagents that are available target non-infectious diseases. Interest in using antibodies to treat infectious diseases is now being fuelled by the wide dissemination of drug-resistant microorganisms, the emergence of new microorganisms, the relative inefficacy of antimicrobial drugs in immunocompromised hosts and the fact that antibody-based therapies are the only means to provide immediate immunity against biological weapons. Given the need for new antimicrobial therapies and many recent technological advances in the field of immunoglobulin research, there is considerable optimism regarding renewed applications of antibody-based therapy for the prevention and treatment of infectious diseases.     

微生物的遗传多样性

微生物是生物圈中不可或缺的重要组成部分, 维系着自然界生态平衡。随着分子生物学技术的发展, 微生物遗传多样性的研究从形态学水平、蛋白水平进入到了DNA水平。而高通量测序技术和宏基因组技术的发展, 不仅为我们理解微生物的遗传多样性提供了更加丰富的信息和有力的证据, 也对于合理利用生物资源、保护生态平衡等方面具有重要意义。文章就微生物遗传多样性研究的相关内容, 如物种的分离鉴定、微生物群体遗传结构、物种形成以及系统发育和进化等方面的研究进展进行综述。     

In Vivo NMR Studies of Neurodegenerative Diseases in Transgenic and Rodent Models

In vivo magnetic resonance spectroscopy (MRS) and magnetic resonance imaging (MRI) provide unique quality to attain neurochemical, physiological, anatomical, and functional information noninvasively. These techniques have been increasingly applied to biomedical research and clinical usage in diagnosis and prognosis of diseases. The ability of MRS to detect early yet subtle changes of neurochemicals in vivo permits the use of this technology for the study of cerebral metabolism in physiological and pathological conditions. Recent advances in MR technology have further extended its use to assess the etiology and progression of neurodegeneration. This review focuses on the current technical advances and the applications of MRS and MRI in the study of neurodegenerative disease animal models including amyotrophic lateral sclerosis, Alzheimer's, Huntington's, and Parkinson's diseases. Enhanced MR measurable neurochemical parameters in vivo are described in regard to their importance in neurodegenerative disorders and their investigation into the metabolic alterations accompanying the pathogenesis of neurodegeneration.     

Interactomics: toward protein function and regulation

Protein–protein interactions are central to all cellular processes. Understanding of protein–protein interactions is therefore fundamental for many areas of biochemical and biomedical research and will facilitate an understanding of the cell process-regulating machinery, disease causative mechanisms, biomarkers, drug target discovery and drug development. In this review, we summarize methods for populating and analyzing the interactome, highlighting their advantages and disadvantages. Applications of interactomics in both the biochemical and clinical arenas are presented, illustrating important recent advances in the field.     

Nonhuman primates are relevant models for research in hematology, immunology and virology

Nonhuman primates have been used for biomedical research for several decades. They have proved to be models that are relevant to humans because of the high level of gene homology which underlies physiological and biochemical similarities. The similarity of monkeys to humans has been used to investigate pathophysiological mechanisms in hematology, immunology and virology. New therapeutic procedures can be assessed in primates by using materials, in particular pharmacological reagents, and methods designed for humans. The relevance of these models also relies on the use of species-specific pathogens and the availability of recombinant, homologous cytokines. The introduction of more and more sophisticated cell and gene therapy protocols in hematopoietic cell transplantation and immunotherapy requires the development of preclinical trials similar to clinical settings. For several decades now, baboons and cynomolgus/rhesus monkeys have been the most useful primate models in experimental hematology, and this has contributed to numerous therapeutic advances. Primate models of AIDS have been developed to study the pathogenesis, transmission and immune responses to infection, and to test vaccines and drugs. Primate research should be restricted in quantity, and mainly designed with the aim of removing uncertainty as to the safety and clinical benefit to the patient, of new biomedical protocols.