石蜡包埋对兔肝、肾组织块的收缩影响

本实验是调查石蜡包埋对兔肝、肾组织块的收缩影响。用米尺和下端封闭、带刻度的玻璃管对新鲜组织块到石蜡包埋全过程中组织块长、宽、厚及体积的变化进行测量并进行统计学处理。结果表明从固定、脱水、透明到浸蜡每一步骤都使组织块发生了收缩 ,而浸蜡使其收缩最为明显 ,肝组织块收缩了 5 0 .0 0 % ,肾组织块收缩了 5 8.13%。因此包埋过程要尽可能的缩短时间 ,尤其浸蜡要最大限度地降低温度和缩短时间。石蜡切片在镜下不能精确地反应正常组织结构的大小。

脱细胞化肝脏生物衍生支架的制备及鉴定

背景:肝细胞在体外迅速失去极性及合成代谢障碍成为肝脏组织工程研究需要克服的一个难题,在体外寻找一个有利于肝细胞生长与功能维持的细胞外基质微环境成为目前研究的焦点。目的:制备肝脏去细胞化细胞外基质生物衍生支架,并对该生物衍生支架进行初步鉴定。设计、时间及地点:观察性实验,于2008-02-15/05-01在广东省脑功能修复与再生研究所完成。材料:10只雄性SD大鼠用于制备去细胞肝脏细胞外基质支架。10只雄性SD大鼠用于制备原代肝细胞。方法:将SD大鼠肝脏切成10mm×5mm的组织片后,经过胰酶-乙二胺四乙酸作用24h、去垢剂曲拉通×10072h后得到肝脏去细胞化生物衍生支架。每只大鼠获取2×108个肝细胞,将所得原代细胞与肝脏去细胞化生物衍生支架放入含DMEM-F12,体积分数为10%胎牛血清,胰岛素0.5U/mL,地塞米松1×10-7mmol/L,表皮生长因子10μg/L的培养基中共培养,并与单纯原代细胞培养相比较。主要观察指标:培养14d时组织块行苏木精-伊红染色,Masson染色进行组织学分析。并行扫描电镜观察。对培养1,3,5,7,9,14d上清液进行白蛋白及尿素水平检测。结果:组织学检查未见明显细胞核残存,大量胶原纤维得到保留,扫描电镜示纤维成网状排列。支架与原代肝细胞共培养上清液白蛋白和尿素水平高于单纯原代肝细胞培养(P<0.05)。结论:利用去垢剂与胰酶-乙二胺四乙酸低渗溶液处理可以有效完整去除肝脏组织块的细胞成分,较完整地保留细胞外基质;该生物衍生支架有利于肝细胞的生长及功能维持。

不同形式大鼠肝脏标本在压痕松弛实验中的黏弹性参数的差异

目的通过压痕松弛实验,研究三种形式大鼠肝脏的黏弹性参数的差异,探索黏弹性参数的影响因素。方法雄性SD大鼠10只,体重(180±20)g,10%水合氯醛3 ml/kg腹腔注射麻醉后,每只大鼠的肝脏依次在三种检测条件(在体检测、离体检测、将肝脏切成小块后体外检测)下分别进行压痕松弛实验,进行肝脏黏弹性的力学检测。使用Prony模型分别获取3种检测条件下的黏弹性参数:τ1、τ2、g 1、g 2。结果在体肝脏的黏弹性参数g 1、g 2、τ1、τ2分别为0.508±0.071、0.194±0.055、0.754±0.218、23.524±9.233,离体肝脏的黏弹性参数g 1、g 2、τ1、τ2分别为0.384±0.072、0.256±0.041、1.062±0.250、29.254±2.852,肝脏组织块的黏弹性参数g 1、g 2、τ1、τ2分别为0.359±0.030、0.246±0.027、1.070±0.137、30.204±3.250。离体肝脏及肝脏组织块与在体肝脏的黏弹性参数差异具有统计学意义(P<0.05)。结论离体肝脏和肝脏组织块的黏弹性与在体肝脏的黏弹性有着较大差异,对肝脏的黏弹性进行研究时,应注意不同检测状态对肝脏黏弹性的影响。

Laser capture microdissection and genetic analysis of carbon-labeled Kupffer cells

AIM： To develop a method of labeling and microdissecting mouse Kupffer cells within an extraordinarily short period of time using laser capture microdissection （LCM）. METHODS： Tissues are complex structures comprised of a heterogeneous population of interconnected cells. LCM offers a method of isolating a single cell type from specific regions of a tissue section. LCM is an essential approach used in conjunction with molecular analysis to study the functional interaction of cells in their native tissue environment. The process of labeling and acquiring cells by LCM prior to mRNA isolation can be elaborate, thereby subjecting the RNA to considerable degradation. Kupffer cell labeling is achieved by injecting India ink intravenously, thus circumventing the need for in vitro staining. The significance of this novel approach was validated using a cholestatic liver injury model. RESULTS： mRNA extracted from the microdissected cell population displayed marked increases in colonystimulating factor-1 receptor and Kupffer cell receptor message expression, which demonstrated Kupffer cell enrichment. Gene expression by Kupffer ceils derived from bile-duct-ligated, versus sham-operated, mice was compared. Microarray analysis revealed a significant （2.5-fold, q value 〈 10） change in 493 genes. Based on this fold-change and a standardized PubMed search, 10 genes were identified that were relevant to the ability of Kupffer cells to suppress liver injury. CONCLUSION; The methodology outlined herein provides an approach to isolating high quality RNA from Kupffer cells, without altering the tissue integrity.