Heparinized cadaveric organ donors (HCOD)--a potential source of hematopoietic cells for transplantation and gene therapy

BACKGROUND: Hematopoietic stem cells (HSC) from unrelated HLA-matched heparinized cadaveric organ donors (HCOD) are a new potential source of cells for transplantation and gene therapy. In addition, these cells could also be used as adjuvant therapy to increase microchimerism and graft tolerance after transplantations of various solid organs. Our purpose was to develop an efficient method for harvesting hematopoietic cells from HCODs, METHODS: Bone marrow cells were harvested from pelvic bones and/or vertebral bodies from 50 adult HCODs before or up to 3 hr after disconnecting the donor from the respirator. Subsequently, we evaluated the hematological and gasometric parameters of aspirated marrow samples as well as the proliferative potential, viability, and expression of CD34 and AC133 antigens on these cells. RESULTS: We noticed that up to 2-3 hr after disconnecting the donor from the respirator bone marrow cavities do not clot and remain uninfected and that it is possible to aspirate bone marrow mononuclear cells in quantities sufficient to perform allotransplantation. Nevertheless, due to the developing hypoxia and acidosis of the hematopoietic microenvironment the number and proliferative potential of CD34+ and AC133+ cells gradually decreases. Hence, to obtain viable early hematopoietic cells, bone marrow should be aspirated without delay; optimally before HCOD is disconnected from the respirator or at the very latest 2 hr after organ harvest. CONCLUSIONS: Collectively, our results show that early hemopoietic cells may be efficiently harvested from HCOD in large quantities and used for research and/or transplantation purposes. We postulate to create an international network of banks in which hemopoietic stem cells from HCODs could be preserved for therapeutic purposes.     

The phenotypic characteristic of liver-derived stem cells from adult human deceased donor liver

Liver transplantation is the only effective treatment for end-stage liver disease. Because of the limited donor availability, attention has been focused on the possibility to restore liver mass and function through cell transplantation. Stem cells are a promising source for liver repopulation after cell transplantation, but whether or not the adult liver contains hepatic stem cells is highly controversial. Several studies have suggested the presence of stem cells in the adult normal human liver. However, a population with stem cell properties has not yet been isolated. The purpose of this study was to identify and characterize progenitor cells in normal adult human liver. We isolated and expanded human liver stem cells (HLSCs) from a donated liver not suitable for liver transplantation or characterizing them by fluorescence-activated cell sorter, polymerase chain reaction, and immunofluorescence assay. HLSCs expressed the mesenchymal stem cell markers CD29, CD73, CD44, CD90, CD105, and CD166 but not the hematopoietic stem cell markers CD34, CD45, and CD117. HLSCs were also positive for vimentin and nestin, a stem cell marker. The absence of staining for cytokeratin-19, CD117, and CD34 indicated that HLSCs were not oval stem cells. In addition, HLSCs expressed CD26, and in a small percentage of cells, cytokeratin-8 and cytokeratin-18, indicating a partial commitment to hepatic cells. We concluded that HLSCs expressed several mesenchymal but not hematopoietic stem cell markers as well as CD26 and CK18, indicating a partial commitment to hepatic cells.     

Expression of stem cell markers on fetal and tumoral human liver cells in primary culture

Hepatic stem cells can be identified by the expression of putative markers such as CD117 (c-kit), CD90 (Thy-1), CD34, and HLA-DR. We have identified populations expressing these markers in both fetal and tumoral human liver by flow cytometry, using monoclonal antibodies against CD90, CD117, CD34, and HLA-DR. In tumoral liver CD117+/CD90+ cells were found in decreasing number from the neoplastic (2.48 +/- 0.67) and peritumoral region (0.88 +/- 0.12) to the area of para-tumoral (normal) parenchyma (0.13 +/- 0.04). The CD117+/CD34+ cells showed the following distribution: 0.35 +/- 0.05% in the tumoral region, 1.01 +/- 0.23% in the peritumoral region and 0.35 +/- 0.01 in the para-tumoral region. Using the same markers on fetal liver cells we have also identified small populations of CD117+/CD90+ cells (0.28 +/- 0.07%) and CD117+/CD34+ cells (1.13 +/- 0.24%), presumably resident stem cells or hematopoietic stem cells. Immunomagnetic negative separation was then performed on fetal liver cells using monoclonal antibodies against specific markers of hematopoietic lineages such as CD3, 14, 16, 19, 22, and CD56 to eliminate this population. The remaining cells were then incubated with fluorescently labeled monoclonal antibodies against CD90 and CD117 and analyzed using fluorescence microscopy. As expected these markers were expressed on the majority of the selected cells (89.28 +/- 9.56%). Isolation using appropriate markers and initiation of primary cultures is a first step to the therapeutic use of fetal stem cells and for the study of adult liver stem cells involvement in carcinogenesis.     

Successful generation of donor specific hematopoietic stem cell lines from co-cultured bone marrow with human embryonic stem cell line: a new methodology

We report the generation of 30 healthy human embryonic stem cell (h-ESC) lines from 33 voluntary oocyte donors using a donor somatic cell nuclear transfer (SCNT) technique on 190 oocytes. Our aim was to coculture them with their own bone marrow (BM) to generate hematopoietic progenitor cells for therapeutic purposes. Pluripotency and undifferentiated stage were confirmed using molecular cell surface markers. Normal karyotype of these cell lines was confirmed. Here we demonstrate that SCNT-h-ESCs differentiate to hematopoietic precursors when cocultured with unmodified, nonirradiated donor BM. We did not use any xenogeneic material for this hematopoietic differentiation. Hematopoietic precursors derived from them expressed cell surface antigens CD45/34. When further cultured with hematopoietic growth factors these hematopoietic precursors formed characteristic myeloid, erythroid, and megakaryocyte lineages. Phenotypic CD34+ cells derived from NT-h-ESCs were functionally similar to their counterparts in primary hematopoietic tissues like BM, umbilical cord, and blood. More terminally differentiated hematopoietic cells derived from h-ESCs under these culture conditions also expressed normal surface antigens like glycophorin A on erythroid cells, CD15 on myeloid cells, and CD41 on megakaryocytes. We report generation of hematopoietic progenitor cells from h-ESC lines by a SCNT technique, with differentiation into further lineages with structural and functional similarities to their adult counterparts in vivo. This novel alternative source of CD34+ stem cells from h-ESC lines generated without any xenogeneic material might be used to create transplantation tolerance, to implement regenerative medicine, and to treat autoimmune disorders.     

CD34+ selected bone marrow grafts are radioprotective and establish mixed chimerism in dogs given high dose total body irradiation.

BACKGROUND: Canine stem cell transplantation models have provided important preclinical information for human clinical studies. The recent cloning of cDNA for canine CD34 and the production of monoclonal antibodies that recognize canine CD34 have been the basis for the development of techniques for the large-scale enrichment of canine hematopoietic progenitor cells. In this study, we evaluated the in vivo functional properties of canine bone marrow CD34+ cells after a myeloablative conditioning regimen. METHODS: After 920 cGy total body irradiation, three dogs received infusion of autologous CD34+ selected cells from the marrow, three dogs CD34+ depleted autologous marrow cells, and two dogs received CD34+ autologous marrow cells that were immunomagnetically selected and then further purified by cell sorting. In addition, four dogs received allogeneic marrow enriched for CD34+ cells from dog leukocyte antigen-identical littermates to investigate long-term repopulating function of CD34+ cells. Chimerism studies were performed using polymerase chain reaction to detect highly polymorphic microsatellite markers. RESULTS: In three recipients of autologous marrow enriched for CD34+ cells to between 29% and 70% (1.6 x 10(6) to 3.4x10(6) CD34+ cells/kg), prompt and full hematopoietic recovery occurred, whereas in three dogs that received marrow depleted of CD34+ cells (1 x 10(7) cells/kg), no hematopoietic recovery was achieved. In two dogs that received highly purified CD34+ cells (purity: 98% and 96%, 0.79x10(6) to 0.547x 10(6) CD34+ cells/kg), delayed but full hematopoietic recovery was seen. Three of four allograft recipients of 1.75x10(6) to 6.8x10(6) CD34+ cells/kg engrafted and showed full hematopoietic recovery, whereas one dog rejected the graft. The three long-term survivors showed stable mixed hematopoietic chimerism with predominantly donor hematopoiesis. CONCLUSION: Transplantation of canine CD34+ cells after lethal total body irradiation provides radioprotection and gives rise to long-term hematopoietic reconstitution. Stable donor/host mixed chimerism was observed in allograft recipients most likely as a result of T-cell depletion of the grafts. Our findings suggest a future role for canine preclinical transplant studies involving in vitro manipulation of hematopoietic pro.     

人脐血造血干/祖细胞的生物反应器大规模扩增及移植实验

目的 利用生物反应器大规模扩增人脐血造血干/祖细胞,并通过动物移植实验检验该方法的有效性.方法 采集抗凝脐血10份,分离出单个核细胞(MNC),分别进行生物反应器扩增培养和静态扩增培养.检测扩增前后细胞表面CD34、CD38、CD133、CD184和CD62L分子的表达,并进行造血干/祖细胞集落的培养.取非肥胖糖尿病重症联合免疫缺陷小鼠,以X射线照射后,分为4组,其中MNC组小鼠注射未经扩增培养的MNC;静态扩增组小鼠注射经过静态扩增培养的细胞;反应器扩增组小鼠注射经过生物反应器扩增培养的细胞;空白对照组小鼠注射生理盐水.移植后6周处死存活小鼠,收集骨髓细胞,检测其中CD45+、CD3+、CD19+和CD33+细胞的含量以及人特异的Cart-Ⅰ和Alu基因的表达.结果 生物反应器扩增前MNC为(1.2～2.8)×108个,扩增后为(3.7～12.6)×108个,扩增后的细胞数明显高于静态扩增培养者(P<0.01).经生物反应器扩增后所形成的红系集落形成单位、粒-巨噬细胞集落形成单位数明显高于经静态扩增者(P<0.05).移植6周后,空白对照组小鼠均死亡,MNC组存活率为35%,静态扩增组存活率为30%,反应器扩增组存活率为62.9%,后者明显高于前二者(P<0.05).各组存活小鼠骨髓细胞中均检测到Alu基因和Cart-Ⅰ基因的表达以及人源CD33+、CD45+、CD3+及CD19+细胞.结论 利用生物反应器可大规模扩增人脐血造血干/祖细胞,所得细胞能植入小鼠体内,并能获得造血功能重建.     

人脐血造血干/祖细胞的磁力搅拌悬浮培养及移植实验

目的 探讨磁搅拌大规模培养体系对人脐血造血祖细胞的扩增效果以及扩增的人造血祖细胞植入动物体内后的造血重建情况.方法 从新鲜抗凝脐血中分离出单个核细胞(MNC),以添加干细胞因子、酪氨酸激酶受体3配基及血小板生成素的无血清培养体系进行培养.静态扩增组的细胞置于T25培养瓶中培养,磁搅拌悬浮扩增组(磁搅拌扩增组)的细胞采用Celstir装置进行培养,培养体系为50～100 ml.培养7 d后进行细胞计数、集落培养检测和细胞表面分子表达的测定.以不进行培养者为对照组.非肥胖糖尿病重症联合免疫缺陷(NOD/SCID)小鼠在接受2.5 Gy的亚致死剂量X射线照射后分别从尾静脉输入上述静态扩增组、磁搅拌扩增组和对照组的MNC(5×106个),另设不移植的空白对照组.观察小鼠的存活情况,6周后处死存活小鼠,检测骨髓细胞中CD34+细胞、CD3+细胞、CD19+细胞、CD33+细胞及CD45+细胞的含量以及人特异的Cart-Ⅰ和Alu基因的表达.结果 经过7天的培养,磁搅拌扩增组的造血祖细胞扩增倍数为(2.8±0.45)倍,明显高于静态扩增组的(2.1±0.48)倍(P<0.01).磁搅拌扩增组形成的红系集落、粒-巨噬细胞集落数均明显高于静态扩增组(P<0.05).静态扩增组扩增后的CD34+细胞、CD34+CD38-细胞和CD133+细胞含量均高于磁搅拌扩增组(P<0.05),而CD184+细胞和CD62L+细胞含量低于磁搅拌扩增组(P<0.01).移植后6周,对照组、静态扩增组和磁搅拌扩增组分别有3、4、5只小鼠存活,三组间两两比较,6周存活率的差异无统计学意义(P>0.05).存活6周的小鼠,其骨髓中能检人特异性CD34+细胞,以及CD3+细胞、CD19+细胞、CD33+细胞及CD45+细胞,也检测到人Alu基因和Cart-Ⅰ基因的表达.结论 磁搅拌培养能大规模扩增脐带血造血祖细胞,扩增的细胞能植入x射线照射的NOD/SCID小鼠,并重建其多系造血.     

Transplantation of human peripheral blood stem cells into fetal rhesus monkeys (Macaca mulatta)

BACKGROUND: Methods for assessing engraftment efficiency have been explored in a primate xenogeneic model of in utero hematopoietic stem cell transplantation. METHODS: Human peripheral blood stem cells (PBSC) were obtained by leukapheresis from a human male donor after 4 days of administration of recombinant human granulocyte-colony stimulating factor (5 microg/kg/ day). PBSC were enriched for the CD34+ population with and without T-cell depletion. The resulting mononuclear cells consisted of two cell populations, one that was stem cell enriched (0.83% CD3+ cells, 95% CD34+; group 1) and one that was stem cell enriched and T-cell depleted (<0.03% CD3+ cells, 98% CD34+; group 2). Four fetal monkeys (two per group) received either two or four i.p. injections (approximately 5x10(6) cells/injection) via ultrasound guidance every other day over a 7-day period (gestational days 50, 52, 54, and 56). One fetus in each group also received i.p. recombinant human stem cell factor (25 microg/kg) and recombinant human granulocyte-colony stimulating factor (10 microg/kg) posttransplant every 10 days from gestational day 60-150. RESULTS: Four healthy newborns were delivered at term, and specimens were analyzed by polymerase chain reaction for the human Y chromosome (birth, monthly to 6 months; blood, marrow, progenitor assays). Polymerase chain reaction results were positive for all four newborns in all specimens assessed, and flow cytometric analysis for human CD45 in marrow showed engraftment ranging from 0.1-1.7%. There was no evidence of graft-versus-host disease in any of the animals. CONCLUSION: These studies show that (1) multilineage engraftment of human PBSC can be achieved in the fetal rhesus recipient, (2) the rhesus fetus appears to tolerate relatively high numbers of human CD3+ cells, and (3) healthy chimeric rhesus infants can be delivered at term after multiple in utero procedures.     

Mobilization of endothelial precursor cells: systemic vascular response to musculoskeletal trauma.

Postnatal vasculogenesis, the process by which vascular committed bone marrow stem cells or endothelial precursor cells (EPC) migrate, differentiate, and incorporate into the nacent endothelium contributing to physiological and pathological neovascularization, has stimulated much interest. Its contribution to tumor nonvascularization, wound healing, and revascularization associated with skeletal and cardiac muscles ischaemia is established. We evaluated the mobilization of EPCs in response to musculoskeletal trauma. Blood from patients (n = 15) following AO type 42a1 closed diaphyseal tibial fractures was analyzed for CD34 and AC133 cell surface marker expression. Immunomagnetically enriched CD34+ mononuclear cell (MNC(CD34+)) populations were cultured and examined for phenotypic and functional vascular endothelial differentiation. Circulating MNC(CD34+) levels increased sevenfold by day 3 postinjury. Circulating MNC(AC133+) increased 2.5-fold. Enriched MNC(CD34+) populations from day 3 samples in culture exhibited cell cluster formation with sprouting spindles. These cells bound UEA-1 and incorporated fluorescent DiI-Ac-LDL intracellularily. Our findings suggest a systemic provascular response is initiated in response to musculoskeletal trauma. Its therapeutic manipulation may have implications for the potential enhancement of fracture healing.     

脐血单个核细胞体外扩增的实验研究

目的 探讨含有细胞因子的无血清培养基对脐血单个核细胞(MNC)体外培养后的扩增情况和用于移植的安全性.方法 从新鲜脐血中分离出的MNC,在含细胞因子的无血清培养体系中培养.分别将培养前和培养第10天时的造血细胞进行细胞计数、细胞活力分析、集落分析、流式细胞仪检测表面标记、彗星试验分析DNA的损伤情况、无菌性分析及移植至NOD/SCID小鼠体内等项研究.结果 经过体外短期培养,脐血中MNC、CD34+、CD133+、CD34+CXCR4+及CD34+ VLA-4+细胞扩增倍数均比培养前增高(P<0.05);半固体培养基可支持多系集落的生长;培养前和培养第10天时脐血细胞DNA损伤率均低于5%;无菌性分析提示细胞未受污染.将体外扩增后的脐血造血细胞移植入NOD/SCID小鼠体内,与新鲜脐血移植相比,小鼠的存活时间及植入能力的差异均无统计学意义(P>0.05).结论 脐血造血细胞体外扩增是解决脐血造血细胞数量不足的有效方法.脐血造血细胞经短期培养能为造血干细胞移植提供安全而具植入能力的造血细胞.     

Human umbilical cord blood cells can be induced to express markers for neurons and glia

Rare cells are present in human umbilical cord blood that do not express the hematopoietic marker CD45 and in culture do not produce cells of hematopoietic lineage. These umbilical cord multipotent stem cells (UC-MC) behave as multilineage progenitor cells (stem cells) and can be expanded in tissue culture. Exposure to basic fibroblast growth factor (bFGF) and human epidermal growth factor (hEGF) for a minimum of 7 days in culture induces expression of neural and glial markers. Western immunoblots demonstrate expression of both beta-tubulin III and glial fibrillary acidic protein (GFAP). Immunocytochemistry of the cells showed intense labeling to both compounds on the intracellular cytoskeleton. The oligodendrocyte cell surface marker galactocerebroside (Gal-C) was present on most cells. Many cells show dual labeling, expressing both neuronal and glial markers.     

Rapid isolation of human CD34 hematopoietic stem cells--purging of human tumor cells.

Human CD34+ hematopoietic stem cells were purified using a new technology in which monoclonal antibodies are covalently immobilized on polystyrene surfaces. The CD34+ cell isolation scheme involved three sequential processes: (1) purification of bone marrow mononuclear cells; (2) enrichment of CD34+ cells using covalently immobilized soybean agglutinin; and (3) positive selection of CD34+ cells using polystyrene surfaces coated with the anti-CD34 monoclonal antibody ICH3. CD34+ cells purified by this process have both low-to-medium forward light scatter and low 90 degrees light-scatter properties. Moreover, the purified CD34+ cells are greater than 85% viable, express appropriate characteristic surface antigens, and are 10-50-fold enriched in short- and long-term hematopoietic activity. CD34+ cells collected in this manner from bone marrow samples contaminated with radiolabeled breast carcinoma, neuroblastoma, acute myelogenous leukemia, or small cell lung carcinoma cells were 99.9% depleted of the tumor cells. The CD34+ cell selection devices are sterile and are easily scaled-up to process clinical scale bone marrow samples.     

Expression of SDF-1/CXCR4 in injured human kidneys

The chemokine SDF-1α is involved in migration, survival, and development of multiple cells, most notably of hematopoietic stem cells (HSC) expressing its ligand CXCR4. Recently, we have shown engraftment of human HSC in the ischemically injured murine kidney, presumably mediated by SDF-1α. To further investigate a possible role of SDF-1α in the recruitment of CXCR4⁺ cells in human renal disease of varying etiologies, we immunostained human biopsies of immunoglobulin (Ig)A nephropathy, minimal-change nephrotic syndrome, focal segmental glomerulosclerosis, membranoproliferative glomerulonephritis, chronic pyelonephritis, and acute tubular necrosis (ATN) for SDF-1α, CXCR4, and CD45, a pan-hematopoietic marker. Irrespective of the diagnosis, intense SDF-1α immunoreactivity was localized to distal tubules and collecting ducts, whereas CXCR4 showed intense staining in both distal and proximal tubules. In addition, whereas varying degrees of CD45⁺ cell infiltrates were observed in all biopsies, we found focal infiltrates of CXCR4⁺ cells mostly localized to the corticomedullary junction only in ischemic ATN. This correlated with more extensive staining for SDF-1α in these sites. In all investigated renopathologic conditions, CD45+ leukocyte recruitment to the kidney seems not to be driven by SDF-1α/CXCR4 interaction. A contribution of SDF-1α for influx of CXCR4⁺ cells in the vicinity of arcuate vessels is suggested only in human ATN.     

Identification of hematopoietic cell populations from the dermal papillae of human hair follicles

Hematopoietic stem cell (HSC) activity has been identified from the hair follicles (HFs) in mice; however, it has not been identified in human HFs. We used immunohistochemistry and flow cytometry to identify cultured dermal papilla (DP) cells expressing CD45 to test for hematopoietic activity in colony-forming assays of granulocyte/macrophage hematopoietic progenitors (CFU-GM). Occasional CD45-positive cells were detected in cultured DP cells. After in vitro stimulation with IL-3, granulocyte-macrophage colony-stimulating factor (GM-CSF) and granulocyte colony-stimulating factor (G-CSF) for 7 days, about 1% of the cells were CD45-positive by flow cytometry analysis, an fifty-fold expansion in cell numbers. We further examined whether mesenchymal stem/progenitor cells reside in human dermal papillae. Cultured DP papilla cells incubated with monoclonal antibodies to remove the CD45 positive cells were induced into multilineage differentiation with the formation of CFU-GM. Our findings preliminarily indicate that human dermal papilla contain at least a CD45-positive hematopoietic cell population and a mesenchymal stem/progenitor cell population.     

Expression of neuronal markers in differentiated marrow stromal cells and CD133+ stem-like cells

Bone marrow stromal cells, which normally give rise to bone, cartilage, adipose tissue, and hematopoiesis-supporting cells, have been shown to differentiate in vitro and in vivo into neural-like cells. In this study, we examined the expression of neuronal and glial markers in human marrow stromal cells under culture conditions appropriate for neural stem cells, and compared the unsorted cell population to bone marrow CD133+ stem-like cells using immunofluorescence, Western blot, and functional patch-clamp analysis. Overall, the expression of the early neuronal marker beta3-tubulin was most pronounced in the presence of DMEM/F12 and neurotrophin 3 (NT3) or brain-derived neurotrophic factor (BDNF), when marrow stromal cells were cultured onto fibronectin. Electrophysiological examination, however, could not show fast sodium currents or functional neurotransmitter receptors in differentiated marrow stromal cells. CD133+ mesenchymal stem-like cells, but not CD34+/CD133- cells, generally showed a higher expression of neuronal markers than did unsorted marrow stromal cells, and differentiated CD133+ cells more resembled neuron-like cells.     

CD133、CXCR4共表达与胆囊癌转移特性的相关性研究

目的探讨CD133、CXCR4共表达与胆囊癌转移特性之间的关系。方法培养胆囊癌GBC~-SD细胞,并经免疫磁珠分选法分选得到CXCR4~+和CXCR4~-亚群胆囊癌GBC~-SD细胞,分为CD133~-CXCR4~-、CD133~-CXCR4~+、CD133~+CXCR4~-及CD133~+CXCR4~+四组,以Transwell法检测四组胆囊癌GBC~-SD细胞侵袭能力。Western~-blot法检测CD133~+CXCR4~+组与CD133~+CXCR4~-组细胞上皮间质转化相关因子表达。Western blot法检测21例胆囊癌原发灶组织标本中CD133与CXCR4蛋白表达与淋巴结转移、肝脏侵犯、胆管侵犯及TNM分期之间的关系。结果 CD133~+CXCR4~+组平均穿膜细胞数为(32.49±9.45),显著高于CD133~+CXCR4~-组的(16.17±8.55),差异具有统计学意义(P=0.02)。CD133~+CXCR4~+组N~-cadherin蛋白灰度值为(0.8321±0.1259),显著高于CD133~+CXCR4~-组的(0.4572±0.0775),差异有统计学意义(P=0.004)。CD133~+CXCR4~+组E~-cadherin蛋白灰度值为(0.4712±0.0736),显著低于CD133~+CXCR4~-组的(0.8439±0.1339),差异有统计学意义(P=0.006)。CD133~+CXCR4~+组Snail蛋白相对灰度值为(0.9455±0.1228),显著高于CD133~+CXCR4~-组的(0.3219±0.0934),差异有统计学意义(P=0.003)。胆囊癌标本淋巴结转移组、肝脏侵犯组、胆管侵犯组CXCR4蛋白表达值显著高于对应阴性组(P=0.013,P=0.024,P=0.037),Ⅰ/Ⅱ分期组显著低于Ⅲ/Ⅳ组,差异有统计学意义(P=0.016)。淋巴结转移组CD133蛋白表达显著高于对应阴性组,差异有统计学意义(P=0.009),Ⅰ/Ⅱ分期组显著低于Ⅲ/Ⅳ组,差异有统计学意义(P=0.018)。肝脏侵犯组、胆管侵犯组与相应对照组CD133蛋白相对表达差异无统计学意义(P=0.443,P=0.371)。CD133蛋白与CXCR4蛋白表达存在明显正相关(r=0.693,P0.01)。结论 CD133、CXCR4共表达预示胆囊癌具有较强的转移特性。