下颌下腺脱细胞基质材料的生物相容性及毒理学研究

为探讨下颌下腺脱细胞基质支架材料的生物相容性,应用3%TritonX-100对SD大鼠的下颌下腺组织进行脱细胞处理,制备脱细胞基质支架材料,将该材料的浸提液注入小鼠体内进行全身急性毒性试验,观察小鼠全身反应.将该材料植入Wistar鼠肌内进行体内植入试验,不同时间观察支架材料与组织反应.用传代培养的第2代下颌下腺细胞与支架材料体外复合培养,第7 d时进行MTT检测,观察支架材料对细胞增殖的影响.全身急性毒性试验结果显示,实验组与对照组无显著性差别(P＞0.05),体内植入试验2、4、8 W时光镜下表现与对照组基本相似,MTT检测结果,细胞相对增长率为91.66%,支架材料的毒性为0级.结果可见,经3%TritonX-100脱细胞处理后所制备的下颌下腺生物衍生支架材料具有良好的生物相容性,对机体无毒害作用.     

接种方式对细胞在三维材料中接种率和分布的影响

考察了静态和动态接种方式对成纤维细胞在胶原壳聚糖支架材料中接种率和分布的影响。将人成纤维细胞制成细胞悬液,分别采用静态接种、转瓶接种和灌注接种方式将细胞接入三维胶原壳聚糖海绵。通过MTT法和切片HE染色分别考察细胞接种率及细胞在三维材料中的分布。实验结果表明：在低的接种密度下静态接种有较高的接种率(889%),但随着接种密度的增加接种率下降显著,细胞结团且分布不均匀;转瓶接种的接种率约为60%,细胞分布也不均匀;灌注接种的接种率始终维持在77%以上,能得到高的起始细胞密度,且细胞分布均匀,是一种理想的接种方式。细胞接种方式的优化为改善工程化组织的结构和功能、缩短体外构建时间奠定了基础。     

支架材料对棕色脂肪源性干细胞向起搏细胞诱导分化的影响

目的观察不同三维支架材料对棕色脂肪来源干细胞（BADSCs）诱导分化成起搏细胞的效果,为构建生物起搏器提供实验依据。 方法将培养7 d的原代BADSCs分别种植到胶原海绵、明胶海绵和透明质酸水凝胶3种不同的材料中,在不同时间用光镜和扫描电镜观察细胞-支架复合体中细胞形态学的变化,免疫荧光染色检测心肌细胞、起搏细胞相关蛋白的表达。采用单因素方差分析。 结果细胞在3种支架上均能存活、增殖,LIVE/DEAD检测显示,培养3 d的胶原海绵、明胶海绵和透明质酸水凝胶3种细胞-支架复合物死细胞率分别为（46.35±1.50）%、（47.00±1.60）%和（1.76±1.08）%,其中细胞在透明质酸水凝胶中死亡率最低,并且细胞-透明质酸水凝胶复合物可自发性地搏动,三组比较差异具有统计学意义（F = 37.56,P < 0.05）。培养至2周时,胶原海绵、明胶海绵和透明质酸水凝胶中Connexin45细胞阳性率分别为（10.67±1.25）%、（13.67±1.25）%和（21.00±1.60）%,差异有统计学意义（F = 9.435,P < 0.01）,HCN2细胞阳性率分别为（11.00±1.60）%、（14.00±2.16）%和（34.33±3.68）%,差异有统计学意义（F = 17.52,P < 0.01）,HCN4细胞阳性率分别为（18.67±2.05）%、（13.00±1.60）%和（66.00±2.94）%,差异有统计学意义（F = 27.96,P < 0.01）,Sr细胞阳性率分别为（13.00±1.63）%、（14.33±1.24）%和（75.33±3.30）%,差异有统计学意义（F = 36.40,P < 0.01）,水凝胶中Connexin45、HCN2、HCN4和Sr的细胞阳性率均高于胶原海绵和明胶海绵,差异均具有统计学意义（P < 0.05）。 结论BADSCs在胶原海绵、明胶海绵和透明质酸水凝胶中均能很好地生长和分化,但透明质酸水凝胶更适用于组织工程化起搏器的构建。     

雪旺氏细胞与同种异体骨支架的体外共培养研究

目的:探讨雪旺细胞(Schwann’s cells,SCs)在同种异体骨支架上的生物相容性,体外构建组织工程骨神经化模型。方法:利用新鲜人体骨骼制备同种异体骨支架材料,检测其物理性能;采用优化方法提取新生SD大鼠坐骨、臂丛神经培养SCs,实验分为三维培养实验组(SCs+同种异体骨)、二维培养对照组(SCs+胶原玻片),S-100抗体免疫荧光染色鉴定SCs纯度;细胞计数法检测两组细胞增殖特点;细胞接种后第3、7天取样,扫描电镜观察。结果:同种异体骨支架具有良好的三维孔隙结构,适宜细胞贴附生长;S-100免疫荧光染色证实SCs纯度95%;扫描电镜检测显示两组SCs均可正常粘附增殖,细胞间排布规律相似,培养早期实验组SCs胞体更加细长,伪足更加明显,随着培养时间的延长表现出较强的迁移能力;细胞增殖检测:两组SCs生长曲线特征基本一致,支架材料对SCs无毒性作用。结论:同种异体骨支架SCs具有良好的生物相容性,其三维立体多孔结构有利于SCs的粘附与迁移,初步构建了体外组织工程骨神经化模型。     

以人胎盘来源干细胞为种子细胞构建组织工程软骨

通过胰酶消化法分离培养人胎盘来源干细胞（human placenta-derived stem cells,hPDSCs）,对其生物学性状进行检测,在一定条件下使其向软骨细胞诱导分化;将hPDSCs和制备的胶原海绵支架材料复合体外构建组织工程软骨组织,移植到裸鼠体内后观察其形成软骨组织的能力,为以hPDSCs作为种子细胞进行组织工程软骨组织的构建提供理论基础.研究发现hPDSCs具有间充质干细胞性状和良好的增殖能力,能连续培养30代以上保持未分化状态;将hPDSCs培养于软骨细胞诱导培养基中,可以分化形成具有生物学功能的软骨细胞.将hPDSCs与胶原海绵支架材料在诱导培养基中复合,7天后可以观察到有软骨样结构形成,Ⅱ型胶原表达阳性;裸鼠体内移植实验证实,hPDSCs与胶原海绵复合后可以在体内形成软骨组织,组织学观察软骨陷窝形成,并且Ⅱ型胶原阳性表达.研究结果表明hPDSCs具有向软骨细胞分化的潜能,与胶原海绵支架材料复合后可以构建形成具有生物学功能的软骨组织,为临床工作中软骨缺损的修复治疗提供了新的治疗策略,具有广阔的临床应用前景。     

PHB/PLLA组织工程前交叉韧带支架材料改性的实验研究

目的:探索体外构建组织工程前交叉韧带(anterior cruciate ligament,ACL)的三维支架材料。方法:以聚羟基丁酸已酯/聚左旋乳酸(PHB/PLLA1:1)制备"三明治"样结构共聚物并测量其孔隙率等指标。以I型胶原对制备的PHB/PLLA支架进行杂化,获得PHB/PLLA胶原杂化支架。扫描电镜观察其表面结构。将兔皮肤成纤维细胞(SF)接种于PHB/PLLA支架与PHB/PLLA胶原杂化支架,观察其在材料上生长情况。结果:PHB/PLLA支架杂化后胶原填充于纤维空隙,分布比较均匀。体外培养的胶原杂化支架材料上要比PHB/PLLA支架有更多的皮肤成纤维细胞生长。结论:胶原杂化有利于细胞种植和生长,PHB/PLLA胶原杂化支架具有良好的三维构型和生物相容性,有望为前交叉韧带损伤的修复提供了一种新型的支架材料。     

利用新型聚羟丁酸酯材料构建组织工程软骨

目的:研究新型聚羟丁酸酯作为组织工程软骨支架材料的可行性.方法:取幼兔软骨组织中软骨细胞体外培养扩增.实验组接种软骨细胞于支架材料上,体外培养两周后埋植于新西兰大白兔背部皮下;对照组埋入未接种细胞的支架材料.扫描电镜观察材料表面形态及细胞生长情况.分别于第4、8、12周取出标本,大体观察后进行HE和Masson染色,观察组织工程软骨形成情况.结果:扫描电镜观察可见裸材料孔隙分布均匀,形状不规则;细胞材料复合体体外培养两周后材料表面爬满细胞且生长状态良好.埋植材料取出后可见不同时间点实验组标本大小无明显变化,对照组标本逐渐变小.HE和Masson染色显示各组支架材料至12周时已被完全吸收;实验组12周时可见较成熟软骨组织;对照组支架材料被吸收后最终被纤维结缔组织取代.结论:此新型聚羟丁酸酯材料可作为组织工程软骨支架材料.     

成熟软骨细胞促进小鼠胚胎干细胞向软骨分化

为诱导胚胎干细胞向软骨细胞分化,采用胚胎干细胞与成熟软骨细胞共培养的方法以提供软骨诱导微环境．小鼠胚胎干细胞经初步分化,形成类胚体后,从中分选出Flk-1阳性细胞,其与猪关节软骨细胞混合后,接种于可降解材料支架,并植入裸鼠皮下．4周后经组织学检查及Ⅱ型胶原抗体免疫荧光检查证实,细胞材料复合物形成软骨组织．经小鼠主要组织相容性抗原染色,证实其中部分软骨细胞源自于小鼠胚胎干细胞．本研究建立了胚胎干细胞定向诱导分化的新方法．     

自组装IKVAV多肽纳米纤维支架凝胶及其对嗅鞘细胞的作用

旨在观察自组装IKVAV多肽纳米纤维支架凝胶对鼠嗅鞘细胞(OECs)的作用。通过调整IKVAV溶液pH值并加入培养液触发多肽自组装为支架凝胶, 用原子力显微镜检测IKVAV分子可以自组装成编织状纳米纤维(直径为3~5 nm)。采用原代分离培养方法获得OECs单细胞悬液后, 使用差速贴壁法两次纯化OECs且在第12天通过免疫染色计数OECs纯度为85%。将IKVAV多肽纳米纤维支架凝胶与OECs复合培养, 倒置显微镜下观察OECs生长良好, Calcein-AM/PI活、死细胞染色表明活细胞数达95%。CCK-8法间接细胞计数证实IKVAV多肽可促进OECs的黏附, 对OECs增殖没有影响。由此可见IKVAV多肽可以自组装成纳米纤维支架凝胶且对OECs有良好的生物相容性及黏附作用, 可作为神经组织工程支架材料。     

四种显微技术观测大鼠颌下腺细胞与丝素-壳聚糖体外共培养的形态学特点

目的采用倒置显微镜、扫描电镜（scanning electron microscopy,SEM）、荧光显微镜和激光共聚焦显微镜（（laser scanning confocal microscopy,LSCM））技术对大鼠颌下腺细胞（rat submandibular gland cells,RSMGs）与丝素-壳聚糖（silk fibroin-chitosan,SFCs）的体外复合培养进行形态学观察。为观测、评估种子细胞在三维支架的内部生长情况提供技术支持。方法取0～8 d龄SD大鼠的颌下腺,对大鼠颌下腺细胞进行原代培养、分离纯化并传代;用抗细胞角蛋白单克隆抗体（CK8）及淀粉酶抗体的免疫细胞化学染色鉴定细胞来源。选取传至第二代的对数生长期的RSMGs作为种子细胞,选取SFCs共混膜（5×5×2）mm作为支架材料构建组织工程化涎腺样结构。将种子细胞与支架材料复合培养并分别于倒置显微镜、SEM、荧光显微镜和LSCM下观察二者复合生长情况。结果倒置显微镜可以直接观察活细胞与支架复合生长情况,方法简单易行。SEM可以较精确的展示细胞支架复合生长的表面超微结构。经过荧光染料的着色,荧光显微镜和LSCM都可以观察到支架上锚定的种子细胞。荧光显微镜可见细胞核的荧光信号均匀的分布在支架孔隙内。LSCM通过层扫描及三维重建技术对较厚的标本获取图像;并可以通过旋转图像,从不同角度观察细胞支架复合物的三维剖面或整体结构,得到更为准确的定位信息。结论四种显微技术均可应用于RSMGs与SFCs体外共培养的形态学观测。LSCM的三维重建技术结合荧光染料标记可以较好地获得RSMGs与SFCs复合生长的情况,有着较广泛的应用价值。     

Spatial and temporal expression of c-Kit in the development of the murine submandibular gland

The c-Kit pathway is important in the development of many mammalian cells and organs and is indispensable for the development of hematopoiesis, melanocytes, and primordial germ cells. Loss-of-function mutations in c-Kit lead to perinatal death in mouse embryos. Previously, c-Kit has been used as one of salivary epithelial stem or progenitor cell markers in mouse, its specific temporo-spatial expression pattern and function in developing murine submandibular gland (SMG) is still unclear. Here we used quantitative real-time PCR, in situ hybridization, and immunohistochemistry analysis to detect c-Kit expression during the development of the murine SMG. We found that c-Kit was expressed in the epithelia of developing SMGs from embryonic day 11.5 (E11.5; initial bud stage) to postnatal day 90 (P90; when the SMG is completely mature). c-Kit expression in the end bud epithelium increased during prenatal development and then gradually decreased after birth until its expression was undetectable in mature acini at P30. Moreover, c-Kit was expressed in the SMG primordial cord at the initial bud, pseudoglandular, canacular, and terminal end bud stages. c-Kit was also expressed in the presumptive ductal cells adjacent to the developing acini. By the late terminal end bud stage on P14, c-Kit expression could not be detected in ductal cells. However, c-Kit expression was detected in ductal cells at P30, and its expression had increased dramatically at P90. Taken together, these findings describe the spatial and temporal expression pattern of c-Kit in the developing murine SMG and suggest that c-Kit may play roles in epithelial histo-morphogenesis and in ductal progenitor cell homeostasis in the SMG.     

Cell cycle analysis of primary sponge cell cultures

Proliferation of sponge cells is generally measured via cell counts or viability assays. However, more insight into the proliferative state of a sponge cell population can be obtained from the distribution of the cells over the different phases of the cell cycle. Cell cycle distribution of sponge cells was measured via flow cytometry after staining the DNA with propidium iodide. The five sponges studied in this paper all showed a large fraction of cells in G1/G0 compared to G2/M and S, indicating that cells were not actively dividing. In addition, some sponges also showed a large apoptotic fraction, indicating cell death. Additional apoptosis measurements, based on caspase activity, showed that harvesting and dissociation of sponge tissue to initiate a primary cell culture was directly correlated with an increase in apoptotic cells. This indicates that for the development of cell cultures, more attention should be given to harvesting, dissociation, and quality of starting material. Finally, cultivation conditions used were ineffective for proliferation, since after 2 d of cultivating Haliclona oculata cells, most cells shifted towards the apoptotic fraction, indicating that cells were dying. For development of in vitro sponge cell cultures, flow cytometric cell cycle analysis is a useful method to assess the proliferative state of a sponge cell culture and can be used to validate improvements in harvesting and dissociation, to select sponges with good proliferative capacities and to study the influence of culture conditions for stimulating cell growth.     

Alterations in the dynamics of inflammation, proliferation and apoptosis in subcutaneous implants of lupus-prone mice

Wound repair is a complex process that involves inflammation, proliferation, extracellular matrix deposition/remodeling and apoptosis. Autoimmune diseases profoundly affect the healing process. We have used histological parameters to characterize the recruitment of mast cells and the proliferative activity and apoptosis in the fibrovascular tissue induced by subcutaneous polyether-polyurethane sponge implants in lupus-prone New Zealand White (NZW) and in control Balb/c mouse strains at days 10 and 21 post implantation. Fibrovascular tissue infiltration (hematoxylin and eosin staining), mast cell number (Dominici staining) and cellular proliferation (AgNOR staining) peaked early (day 10) but collagen deposition (picrosirius red staining) and apoptosis remained high in implants of NZW mice during the experimental period. In contrast, implants of Balb/c animals showed a progressive increase in mast cell recruitment and cellular proliferation but apoptosis fell from day 10 to 21 post-implantation. This divergent response early mast cells recruitment, excessive collagen deposition and disturbed removal of apoptotic cells from the site of injury in NZW mice implies that the genotype trait of NZW mice is a determining factor in abnormal healing response.     

Keratin distribution in precancerous stages of experimental carcinogenesis in mouse submandibular glands

The immunohistochemical distribution of keratin is reported in experimental carcinogenesis in the mouse submandibular gland (SMG). The initial changes included degranulation of granular convoluted tubule (GCT) cells and the appearance of keratin in the degranulated cells. There was a gradual increase in the area showing keratin staining in the altered tubule cells. Duct-like and cystic structures exhibited an intense keratin staining of their lining epithelium. The squamous cell carcinomas induced varying degrees of keratinization and positive immunohistochemical keratin staining. The latter technique provided a useful marker for distinguishing tumor cells of segmental duct origin in the salivary gland.     

Identification of Cell Types in the Developing Goat Mammary Gland

The goat was chosen as the model system for investigating mammary gland development in the ruminant. Histological and immunocytochemical staining of goat mammary tissue at key stages of development was performed to characterize the histogenesis of the ruminant mammary gland. The mammary gland of the virgin adult goat consisted of a ductal system terminating in lobules of ductules. Lobuloalveolar development of ductules occurred during pregnancy and lactation which was followed by the regression of secretory alveoli at involution. The ductal system was separated from the surrounding stroma by a basement membrane which was defined by antisera raised against laminin and Type IV collagen. Vimentin, smooth-muscle actin and myosin monoclonal antisera as well as antisera to cytokeratin 18 and multiple cytokeratins stained a layer of myoepithelial cells which surround the ductal epithelium. Staining of luminal epithelial cells by monoclonal antibodies to cytokeratins was dependent on their location along the ductal system, from intense staining in ducts to variable staining in ductules. The staining of epithelial cells by monoclonals to cytokeratins also varied according to the developmental status of the goat, being maximal in virgin and involuting glands, lowest at lactation and intermediate during gestation. In addition, cuboidal cells, situated perpendicular to myoepithelial cells and adjacent to alveolar cells in secretory alveoli, were also stained by cytokeratin monoclonal antibodies and antisera to the receptor protein, erbB-2, in similar fashion to luminal epithelial cells. These results demonstrate that caprine mammary epithelial cell differentiation along the alveolar pathway is associated with the loss of certain types of cytokeratins and that undifferentiated and secretory alveolar epithelial cells are present within lactating goat mammary alveoli.     

Cellular proliferation, differentiation and apoptosis in polyether-polyurethane sponge implant model in mice

The integration of implanted material to host organism requires spatial and temporal organization of several cellular processes, such as proliferation, differentiation and apoptosis. Despite the clinical relevance of these processes, there is little information regarding the sequence of such events in synthetic matrices. Here, we present a combination of techniques used to characterize the fibrovascular response in subcutaneous polyether-polyurethane sponge implants in mice at days 4, 7, 10 and 14 postimplantation. The AgNOR technique was modified and used as a surrogate marker for proliferating and activated cells invading the implant. The number of AgNOR-stained cells increased progressively from day 4 (606+/-76) to day 14 (2146+/-71) postimplantation. The number of TUNEL-positive (apoptotic index) cells also increased progressively from day 4 (459+/-40) to day 14 (1157+/-119) postimplantation. However, the ratio of TUNEL-labeled/proliferating cells had its highest peak in the early phase of the process remaining stable until day 14. Using Picrosirius staining it was shown that thin collagen increased from day 4, peaking at day 10 and falling markedly at day 14, whereas dense collagen increased progressively during the whole period. These experiments hold potential to investigate not only distinct phases of tissue repair induced by synthetic matrices but also to study underlying mechanisms involved.     

Cell shape and gene expression in human intervertebral disc cells: in vitro tissue engineering studies

The objective of the present study was to examine the relation between gene expression and the shape of human intervertebral disc cells cultured in vitro in three-dimensional (3D) scaffolds. Disc cells from 19 subjects were seeded into either a collagen sponge or collagen gel and cultured for 10 days. In situ hybridization was performed on serial sections of paraffin embedded specimens and assessed for expression of selected genes important for extracellular matrix formation: Types I and II collagen, aggrecan and chondroitin-6 sulfotransferase. Rounded cells grown in collagen gel showed expression of Types I and II collagen, aggrecan and chondroitin-6 sulfotransferase; expression of these genes was absent in spindle shaped cells. Cells in the collagen sponge that lay on the sponge margin were frequently spindle shaped; these cells expressed type I collagen, but not type II collagen, aggrecan or chondroitin-6 sulfotransferase. Results presented here provide novel data concerning disc cell gene expression with collagen 3D constructs. This information is useful for future tissue engineering studies that have the challenging goal of selectively modulating gene expression.     

Cell shape and gene expression in human intervertebral disc cells: in vitro tissue engineering studies

The objective of the present study was to examine the relation between gene expression and the shape of human intervertebral disc cells cultured in vitro in three-dimensional (3D) scaffolds. Disc cells from 19 subjects were seeded into either a collagen sponge or collagen gel and cultured for 10 days. In situ hybridization was performed on serial sections of paraffin embedded specimens and assessed for expression of selected genes important for extracellular matrix formation: Types I and II collagen, aggrecan and chondroitin-6 sulfotransferase. Rounded cells grown in collagen gel showed expression of Types I and II collagen, aggrecan and chondroitin-6 sulfotransferase; expression of these genes was absent in spindle shaped cells. Cells in the collagen sponge that lay on the sponge margin were frequently spindle shaped; these cells expressed type I collagen, but not type II collagen, aggrecan or chondroitin-6 sulfotransferase. Results presented here provide novel data concerning disc cell gene expression with collagen 3D constructs. This information is useful for future tissue engineering studies that have the challenging goal of selectively modulating gene expression.