Role of the stromal microenvironment in regulation of bone-marrow hematopoiesis after administration of dipyridamole

I. P. Pavlov First Leningrad Medical Institute. Central Roentgeno-Radiological Research Institute, Moscow. Translated from Byulleten' Éksperimental'noi Biologii i Meditsiny, Vol. 110, No. 7, pp. 98–100, July, 1990.     

脊髓损伤后神经修复过程中的细胞微环境北大核心

背景:以往的研究显示单一改变脊髓损伤区域某一基因表达或者某一细胞的状态,对脊髓损伤后功能恢复无显著影响,而大量证据表明调控脊髓损伤后紊乱的细胞微环境是神经功能恢复的关键因素。目的:对脊髓损伤前后细胞微环境的生物学特性,包括多种细胞之间的相互调控以及细胞外组分对损伤神经修复的作用和机制进行综述。方法:由第一作者检索PubMed及Web of Science数据库,英文检索词为“spinal cord injury,glial cell,neuron,immune cell,neural stem cell,extracellular matrix,cytokine,extracellular vesicle,regeneration”。文献检索的时间范围为2000年1月至2021年12月,最终筛选出64篇文献进行分析。结果与结论:①脊髓损伤后,在细胞微环境的细胞组分中,占比最高的胶质细胞间的相互作用,以及与神经元的相互调控作用最为关键。②在脊髓损伤后的细胞外组分中,利用生物相容性良好的水凝胶模仿天然细胞外基质,可有效模拟和重建损伤区域内的细胞微环境,促进轴突伸长。③在脊髓损伤后的细胞外调节因子中,促炎因子如肿瘤坏死因子α和白细胞介素1β等加剧了细胞微环境的炎症反应,应用受体抑制剂或阻断相关通路抑制上述促炎因子的表达是一种有效的治疗方法,同时在脊髓微环境中增加白细胞介素10等抗炎因子的表达,抑制损伤区域炎症发展的研究也陆续出现。④最近被重视起来的细胞外囊泡作为传递信息的载体在细胞微环境中也发挥了重要作用。⑤文章揭示了脊髓损伤后细胞微环境中的包括细胞组分和细胞外组分之间的多组相互调控关系,证实了细胞微环境中各组分之间所发挥的神经修复作用并不是孤立的。     

Regulation of cytokine synthesis in cardiac surgery: Role of extracorporeal circuit and humoral mediators <Emphasis Type="Italic">in vivo</Emphasis> and <Emphasis Type="Italic">in vitro</Emphasis>

Objective and design: Cardiopulmonary bypass (CPB) impairs monocyte and neutrophil proliferation, cytokine synthesis, and antigen presentation. This study compares in vivo data with results from an extracorporeal circulation (ECC) model, distinguishing direct effects on cytokine synthesis from regulatory mechanisms. Patients and methods: Whole blood from 18 patients prior to, during and after CPB was stimulated with lipopolysaccharide (LPS). Tumor necrosis factor (TNF)-α, interleukin (IL)-6, and IL-8 levels were measured. Additionally, blood from 4 volunteers was circulated in an ECC model. Cytokine levels were measured before and during mock ECC. Results: LPS-induced cytokine synthesis was reduced after CPB (TNF-α: 11 %; IL-6: 29 %; IL-8: 48 % of preoperative values, all p < 0.001). In mock ECC, cytokine production (except IL-8) was suppressed: TNF-α production was lowest 60 min after starting ECC, IL-6 synthesis was lowest at 90 min (33 % and 15 % vs. pre-ECC levels; both p < 0.001). Patient sera contained cytokine-inhibitory activity after CPB, an activity not found in mock ECC. Conclusions: (1) In patients, CPB induces early transient LPS hyporesponsiveness; (2) blood contact with foreign surfaces induces LPS hyporesponsiveness; (3) serum cytokineinhibitory activities are released after CPB, but not in mock ECC. Impaired leukocyte function may explain increased susceptibility to infections after CPB. Received 16 September 2006; accepted without revision by K. Visvanathan 18 October 2006     

炎症性肠病动物模型的研究概况

The etiology and pathogenesis of inflammatory bowel disease are up to now still not clear and definite. Establishing the ideal animal model to study its cause and pathogenesis of this disease is very important. The ideal animal model should have the same manifestation with human inflammatory bowel disease on clinical and pathologic feature etc. In this article, the method, the pathologic character isfics and concerning pathogenesis, of a few common useful experiment animal models are discussed.     

神经导管修复周围神经损伤的研究进展

随着神经修复技术特别是显微外科的发展，神经损伤修复的质量有了进一步的提高；利用神经导管桥接神经断端以实现修复周围神经损伤是目前的一个研究热点。本综述了神经导管修复周围神经损伤的发展历史，分析比较了非神经组织、非生物降解材料、可生物降解材料神经导管在神经损伤修复中的效果，讨论了导管的形态及导管内微环境对神经再生的影响。     

Microenvironmental influences on inflammatory cell differentiation

Airways inflammation involves accumulation of inflammatory cells such as eosinophils, basophils and mast cells, which are derived from progenitors in marrow and blood. The inflamed tissue of the airways, through its structural (epithelium, stroma) and inflammatory cell components, produces an array of cytokines which can influence the differentiation of inflammatory cell progenitors. It is particular mechanism that we have investigated, showing that molecules such as GM-CSF, G-CSF, IL-6, IL-8 and SCF can be produced by airways epithelial cells and fibroblasts in quantities sufficient to induce hemopoietic events, either systemically or locally. Corticosteriods may act therapeutically, at least in part, to block inflammatory cell differentiation, and thus recruitment, into the allergic inflammatory process in the airways.     

Functional histology of the human thymus

Summary The thymus develops from a paired epithelial anlage in the neck. This review considers how ectoderm (vesicula cervicalis) and endoderm (third pharyngeal pouch) contribute to the epithelial stroma of the thymus. Stromal elements of mesodermal origin are capillaries, septae and perivascular spaces and single invading cells. These elements separate the thymus into pseudolobuli. The thymus epithelial space and the perivascular spaces are always separated from each other by a closed, flat epithelial cell layer, with a basal lamina which contributes to the blood-thymus barrier. From the 9th gestational week, prethymic precursor cells from hemopoietic centers, begin to invade the thymus anlage. There they finally mature to committed post-thymic T cells. The thymus microenvironment of postnatal thymus is composed of six different types of epithelial cells and several stromal cells of mesodermal origin. The location of these diverse stationary cells is described, and their functional significance is discussed. Obviously these stromal cell types have a special function in providing the proper environment for T-cell maturation. The function of the thymus includes the maturation and/or selection of antigen specific T-cells. The main issue of intra-thymic T-cell differentiation is the development and expression of T-cell-antigen receptors. The great diversity of these receptors is generated by a rearrangement of the T-cell-receptor-genes in order to furnish the host with a mature T-cell repertoire that is capable of recognizing the world of extrinsic antigens. In a synopsis the manyfold interrelationships between the thymus microenvironment and the developing thymocytes are summarised.Abbreviations BALT Bronchus Associated Lymphoid Tissue - CD Cluster of Differentiation - cCD3 cytoplasmic CD3 - mCD3 membranous CD3 - C.R. Crown Rump - GALT Gut Associated Lymphoid Tissue - HLA Human Leucocyte antigen - HLA-DR Gene product of the MHC-class II (this antigen is a surface molecule of numerous stationary and free cells of the immune system) - IDC Interdigitating Cell - IL1 Interleukin 1 (cytokine derived mainly from makrophages, but also from other cell types) - IL2 and IL4 Interleukin 2 and 4 (cytokines derived mainly from T-cell, but also from other cell types) - IL4R Interleukin 4-Receptor - Mab Monoclonal antibody - MHC Major Histocompatibility Complex - p.c. post conception - TCR T-Cell-Receptor - TNC Thymic Nurse Cell - TdT Terminal deoxynucleotidyl Transferase