Chondroinduction of mouse mesenchymal stem cells in three-dimensional highly porous matrix scaffolds

Porous polyvinyl formal (PVF) resin and poly(lactide-caprolactone) [P(LA/CL)] sponges were examined as three-dimensional matrices for chondroinduction of cultured bone marrow mesenchymal stem cells (MSCs). Approximately 5 x 10(5) mouse MSCs were seeded in porous PVF resin or P(LA/CL) sponges and were cultured for up to 1 month in serum-free high-glucose Dulbecco's modified Eagle's medium containing 10 ng/mL transforming growth factor-beta3 and 100 nM dexamethasone for chondroinduction. After the 1-month culture period, the PVF resin and P(LA/CL) sponges contained approximately twice the amount of glycosaminoglycans compared with the control pellet. Safranin-O staining of PVF and P(LA/CL) after 1 month of culture revealed a cartilage-like extracellular matrix containing glycosaminoglycans and collagen. When implanted into nude mice, PVF and P(LA/CL) seeded with MSCs were found to be both biocompatible and chondroinductive. These highly porous scaffolds can maintain a large number of cells in a three-dimensional structure. Both are potentially promising for the chondroinduction of bone marrow MSCs for research and clinical applications.     

Biomimetic collagen scaffolds for human bone cell growth and differentiation

Type I collagen provides a structural framework for connective tissues and plays a central role in the temporal cascade of events leading to the formation of new bone from progenitors. The aim of this study was to examine the ability of the cell-binding domain of type I collagen (P-15 peptide) to promote human bone marrow stromal cell adhesion, proliferation, and differentiation on three-dimensional scaffolds. Human bone marrow stromal cells were selected, expanded, and cultured on particulate microporous ABM ("pure" hydroxyapatite) phase adsorbed with or without P-15 under basal or osteogenic conditions. Immobilized P-15 increased alkaline phosphatase activity and bone morphogenetic protein 2 (BMP-2) gene expression after 1 and 5 days as determined by real-time polymerase chain reaction. P-15 promoted human bone marrow stromal cell attachment, spreading, and alignment on ABM as well as alkaline phosphatase-specific activity in basal and osteogenic cultures. The presence of mineralized bone matrix, extensive cell ingrowth, and cellular bridging between three-dimensional matrices adsorbed with P-15 was confirmed by confocal microscopy, scanning electron microscopy, and alizarin red staining. Negligible cell growth was observed on ABM alone. In vivo diffusion chamber studies using MF1-nu/nu mice showed bone matrix formation and organized collagen formation after 6 weeks. These studies indicate the potential of P-15 to generate appropriate biomimetic microenvironments for osteoblasts and demonstrate the potential for the exploitation of extracellular matrix cues for osteogenesis and, ultimately, bone regeneration.     

Syngenic bone marrow cells restore hepatic function in carbon tetrachloride-induced mouse liver injury

Progenitor cells in bone marrow have been explored for the treatment of liver injury. Stem cell homing to the injured tissue is regulated through stromal cell derived factor-1 (SDF-1) and its receptor CXCR4. We hypothesized that syngenic bone marrow cells (BMCs) would restore hepatic function in the injured liver through the regulation by SDF-1/CXCR4 system. After injecting carbon tetrachloride (CCl(4)), the mice were injected with syngenic BMCs or normal saline. Morphological and functional analysis of the liver was performed. Flow cytometry for the stem cell markers and CXCR4 was done with the liver, BM, and spleen cells from each group. Carboxyfluorescein diacetate succinimidyl ester was used to trace the homing of transplanted BMCs. The SDF-1 expression of the liver was assessed by immunohistochemistry. Hepatosplenomegaly and necrosis of the CCl(4)-injected mouse liver were improved after BMCs transplantation The hepatic enzymes were increased after injury and then decreased after BMCs transplantation. The expression of stem cell markers and CXCR4 was exclusively increased in the damaged liver compared to the BM and spleen, and even more elevated after BMCs transplantation. SDF-1 expression in the liver was observed after CCl(4) injection and it was elevated after BMCs transplantation. The intrinsic and extrinsic BMCs migrate specifically to the injured liver rather than BM or spleen, and the transplanted BMCs contribute to the repair of the damaged liver. SDF-1/CXCR-4 interaction plays a role in stem cell homing toward the damaged organ, and transplanted BMCs are involved in the up-regulated SDF-1 expression seen in the injured liver.     

Angiogenesis after Transplantation of Auto- and Allogenic Cells

Neoangiogenesis after transplantation of auto- and allogenic mononuclears and multipotent stromal cells from the bone marrow was studied on the model of inflammatory angiogenesis. Transplanted auto- and allogenic cells stimulate the formation of new blood vessels in the granulation tissue, this manifesting in an increase in the quantity and volume density of blood vessels. The most pronounced angiogenesis was observed after transplantation of allogenic mononuclears and multipotent stromal cells. It was associated with intense inflammatory infiltration, with less numerous and mature collagen fibers in the granulation tissue. Injection of allogenic cells led to stimulation and chronization of inflammation, infiltration with inflammatory and poorly differentiated cells, and more pronounced and lasting angiogenesis. However, neither auto-, nor allogenic transplanted labeled cells were detected in the walls of new blood vessels. Hence, it seems that bone marrow mononuclears and multipotent stromal cells stimulated angiogenesis mainly at the expense of production of angiogenic factors, and after transplantation of allogenic cells also by stimulating the inflammation.     

Effects of fluid flow and calcium phosphate coating on human bone marrow stromal cells cultured in a defined 2D model system

In this study, we investigated the effect of the long-term (10 days) application of a defined and uniform level of fluid flow (uniform shear stress of 1.2 x 10(-3) N/m(2)) on human bone marrow stromal cells (BMSC) cultured on different substrates (i.e., uncoated glass or calcium phosphate coated glass, Osteologictrade mark) in a 2D parallel plate model. Both exposure to flow and culture on Osteologic significantly reduced the number of cell doublings. BMSC cultured under flow were more intensely stained for collagen type I and by von Kossa for mineralized matrix. BMSC exposed to flow displayed an increased osteogenic commitment (i.e., higher mRNA expression of cbfa-1 and osterix), although phenotype changes in response to flow (i.e., mRNA expression of osteopontin, osteocalcin and bone sialoprotein) were dependent on the substrate used. These findings highlight the importance of the combination of physical forces and culture substrate to determine the functional state of differentiating osteoblastic cells. The results obtained using a simple and controlled 2D model system may help to interpret the long-term effects of BMSC culture under perfusion within 3D porous scaffolds, where multiple experimental variables cannot be easily studied independently, and shear stresses cannot be precisely computed.     

Combined transplantation of bone marrow stromal cell-derived neural progenitor cells with a collagen sponge and basic fibroblast growth factor releasing microspheres enhances recovery after cerebral ischemia in rats

Bone marrow stromal cells (MSCs) are a useful source of cells because of their abundant supply and few associated ethical problems. We have previously reported that neural progenitor cells (NS-MSCs) can be effectively induced from MSCs and differentiate into neurons to contribute to functional recovery when transplanted into the rat stroke model. In this study, we attempted to enhance the therapeutic effects of NS-MSCs with a collagen sponge and basic fibroblast growth factor (bFGF) releasing microspheres. NS-MSCs were generated from MSCs by transfection of Notch-1 intracellular domain followed by culturing the cells in a free-floating culture system. The resulting NS-MSCs were transplanted into the rats with induced brain ischemia by using collagen sponges as scaffolds for transplanted cells, and with bFGF incorporated into gelatin microspheres to aid neovascularization around the transplanted region and proliferation of neural stem cells/neural progenitor cells. In culture, NS-MSCs successfully formed spheres containing cells highly expressing neural progenitor markers. Cell survival, neovascularization, and proliferation of host neural stem cells/neural progenitor cells were improved in animals that received NS-MSCs together with these biomaterials. Behavioral analysis also revealed significant functional recovery. These observations demonstrate that transplantation of NS-MSCs in combination with a collagen sponge and bFGF releasing microspheres significantly improves histological and functional recovery in the rat stroke model. When used with these biomaterials, NS-MSCs would be a promising cell source for treating stroke and neurodegenerative diseases.     

Reduced intensity conditioning compared to standard conditioning preserves the in vitro growth capacity of bone marrow stroma, which remains of host origin

The ability of bone marrow (BM) samples to generate confluent stromal layers in long-term BM cultures (LTBMC) was used as a surrogate assay to determine the in vivo toxic effects of different conditionings on stromal cells. Here, 32 patients receiving a fludarabine-based reduced intensity conditioning regimen (FBM) were compared to those in a control group of 23 patients treated with standard busulfan/cyclophosphamide (BuCy; 14 patients) or TBI-based (TBI 12 Gy/VP16/cyclophosphamide; 9 patients) conditioning. BM was aspirated before conditioning, and at day +30 and/or at day +100, obtaining positive stromal cell growth in vitro in 58%, 47%, and 65%, respectively. FBM conditioning did not alter the ability of BM to generate stromal layers both early (day +30, 75%+) or late (day +100, 80%+) after hematopoietic cell transplantation (HCT) as compared to pre-HCT (66.6%+). FBM-treated patients formed confluent stroma significantly more often than standard-treated patients (85% vs. 38% patients; p < 0.05). In an univariate analysis, standard conditioning remained the only factor predicting stromal growth impairment after allogeneic HCT. The ex vivo-generated stromal layers from 5 female, FBM treated, sex-mismatched, and peripheral blood stem cell (PBSC) transplanted patients were analyzed by combined FISH-Y and immunofluorescence stains (Vimentin, CD14, CD45) and found to be exclusively of recipient origin. We conclude that FBM reduced intensity conditioning results in reduced, if any, stromal damage as compared to standard myeloablative treatment. The novel, donor-derived, hematopoiesis in FBM patients after allogeneic transplantation is supported and maintained by a host-derived BM stromal microenvironment.     

Transplantation of Human Embryonic Myoblasts and Bone Marrow Stromal Cells into Skeletal Muscle of C57BL/10J-mdx Mice

We studied expression of dystrophin in skeletal muscles of C57BL/10J-mdx mice after transplantation of human embryonic and fetal myoblasts and bone marrow stromal cells. Dystrophin-positive areas corresponding to the location of transplanted cell were detected in muscles of all recipient mice after transplantation of different cell cultures, but the distribution of dystrophin characteristic of normal muscle fibers was detected only after transplantation of embryonic myoblasts. Dystrophin distribution in muscle fibers after transplantation of fetal myoblasts and bone marrow stromal cells was atypical.     

Effect of culture substrates and fibroblast growth factor addition on the proliferation and differentiation of rat bone marrow stromal cells

This study is an investigation of the proliferation and differentiation of bone marrow stromal cells (BMSCs) on film substrates with different surface properties. Films of noncharged polymers with several water wettabilities; cell culture plates coated with collagen type I or IV, gelatin, or basic fibroblast growth factor (bFGF); and glass were used. BMSCs isolated from rat bone marrow were cultured on the various substrates in medium with dexamethasone [Dex(+)] or without dexamethasone [Dex(-)] to assess cell proliferation and differentiation. The number of proliferated BMSCs depended on the water wettability of substrates, although the cell number was greater in Dex(-) medium than in Dex(+) medium. Protein-coated substrates exhibited a high proliferation rate compared with noncoated substrates. Alkaline phosphatase (ALP) activity increased with increasing cell number, whereas ALP activity per cell correlated well with cell number. When cultured in Dex(+) medium containing bFGF or on culture plates coated with bFGF, BMSC proliferation tended toward enhancement with an increase in the amount of bFGF added in solution form, whereas it did not depend on the amount of bFGF in coated form. On the other hand, ALP activity and calcium content of BMSCs became maximal with bFGF coated at about 1 x 10(3) to 2 x 10(3) ng, in contrast to bFGF in solution form. Irrespective of the amount of bFGF, ALP activity and calcium content levels for bFGF in coated form were higher than for bFGF in solution form. It is concluded that the type of culture substrate and the manner of addition of bFGF affect the proliferation and differentiation of BMSCs.     

A high-density culture of hepatocytes using porous substrate for use as a bioartificial liver

High-density, large-scale culture of hepatocytes is a key requirement in the development of a bioartificial liver that can replace liver functions in patients with severe liver insufficiency. We have applied a porous polymer, polyvinyl formal (PVF) resin, as a cell-supporting material for hepatocyte culture. We evaluated the performance of the culture system using PVF resin under three different culture conditions: a shake culture on conventional dishes, perfusion culture with sheet-shaped PVF, and a packed-bed-type module. Among them, the packed-bed reactor using PVF resin enabled high-density culture of hepatocytes (2×10⁷ cells/cm³-PVF). The hepatocytes immobilized in the PVF resin maintained satisfactory metabolic functions (ammonium metabolism and albumin secretion) comparable to those of the monolayer dish cultures. Furthermore, by maintaining dissolved oxygen concentration at a relatively high level (260–460μM), the metabolic functions of the hepatocytes were improved. It was concluded that the packed-bed reactor using PVF resin is a promising system for developing a bioartificial liver using hepatocytes.     

Kinetics of thymocyte regeneration in adult adriamycin treated rats: evidence for an exclusive role of bone marrow derived cells

This paper describes a new, less toxic and more selective approach to study the adult thymus. An adriamycin (ADR), sparing bone marrow (BM) stem cells and nontoxic to cells that are not in cycle during treatment, was used as a depleting agent in conjunction with vascular thymus transplantation. We were able to deplete the thymus of thymocytes without damaging its microenvironment as witnessed by intact antigen profiles of stromal cells. Two models were used in this study, (1) regeneration after ADR induced depletion with or without BM reconstitution either systemically or intrathymically and (2) thymocyte turnover or regeneration in vascularly transplanted thymi. In the latter model either normal thymus was grafted into ADR treated recipient or ADR depleted thymus was grafted into normal recipient. These experiments clearly show that intact BM function is a prerequisite for intact continued cellularity of the adult thymus. Although the resident thymocyte population possesses some limited proliferating potential, it clearly does not seem to have a permanent self-renewing capacity of intrathymic stem cells.     

Autocrine/paracrine regulation of human endometrial stromal remodeling by laminin and type IV collagen

The biological roles of laminin and type IV collagen in human endometrial stromal tissues were investigated by the evaluation of the expression levels in human endometrial tissues using immunohistochemistry. In addition, normal human endometrial stromal cells were cultured in vitro on laminin- or type IV collagen-coated plates and subjected to cytological analyses. Cyclic production of laminin and type IV collagen were detected and the two productions were significantly increased in late proliferative and late secretory endometrial stromal cells. Unstimulated endometrial stromal cells proliferated with specific growth structures that varied depending on the extracellular matrix component coated on the culture plates. The expression levels of integrin subunits on endometrial stromal cells were sufficiently enhanced by 8Br-cAMP treatment to mask any differences in the growth structures induced by the extracellular matrix components. 8Br-cAMP-stimulating stromal cells exhibited significant survival on laminin-coated plates, while 8Br-cAMP-deprived stromal cells, after 8Br-cAMP stimulation, showed significant survival on type IV collagen-coated plates. In conclusion, human endometrial stromal cells produce laminin and type IV collagen, and these productions are possibly regulated by ovarian estrogen and progesterone. Human endometrial stromal cells specifically bind to laminin and type IV collagen via integrins, and regulate endometrial stromal cell structures, viability and differentiation. Thus, laminin and type IV collagen may autoregulate human endometrial stromal remodeling during the menstrual cycle in an autocrine and paracrine fashion.     

Prevention of senile osteoporosis in SAMP6 mice by intrabone marrow injection of allogeneic bone marrow cells

The SAMP6 mouse (a substrain of senescence-accelerated mice) spontaneously develops osteoporosis early in life and is, therefore, a useful model for examining the mechanisms underlying osteoporosis. We have recently established a new bone marrow transplantation (BMT) method: the bone marrow cells (BMCs) of normal allogeneic mice are directly injected into the bone marrow (BM) cavity of irradiated (5.5 Gy x 2) recipients (IBM-BMT). Using IBM-BMT, we attempted to prevent osteoporosis in SAMP6 mice. The hematolymphoid system was completely reconstituted with donor-type cells after IBM-BMT. Thus-treated SAMP6 mice showed marked increases in trabecular bones even at 12 months of age, and the bone mineral density remained similar to that of normal B6 mice. In concordance with these findings, urinary deoxypyridinoline also remained continuously low until 10 months of age, indicating that IBM-BMT was effective in the prevention of bone absorption. In addition to the above, BM stromal cells in the treated SAMP6 mice were replaced with donor stromal cells, and the message level of interleukin-11 (IL-11), which is produced by the BM stromal cells and is known as an important factor in the regulation of bone remodeling, was restored to a level similar to that observed in normal B6 mice. Furthermore, the message level of IL-6, which is known to enhance osteoclastogenesis, was also restored to normal. These results indicate that the BM microenvironment was normalized after IBM-BMT and that the increased production of IL-11 and IL-6 ameliorated the imbalance between bone absorption and formation, resulting in the prevention of osteoporosis in SAMP6 mice.     

Transplanted hematopoietic cells seed in clusters in recipient bone marrow in vivo

The process of hematopoietic stem and progenitor cell (HSPC) seeding in recipient bone marrow (BM) early after transplantation is not fully characterized. In vivo tracking of HSPCs, labeled with PKH dyes, through an optical window surgically implanted on the mouse femur revealed that transplanted cells cluster in the recipient BM. Within the first day after intravenous injection, 86 +/- 6% of the cells seeded in clusters (p < 0.001 versus scattered cells) in the endosteal surfaces of the epiphyses. The primary clusters were formed by concomitant seeding of 6-10 cells over an area of approximately 70 microm, and secondarily injected cells did not join the already existing clusters but formed new clusters. Major antigen-disparate HSPCs participated in formation of the primary clusters, and T lymphocytes were also incorporated. After 4 to 5 days, some cellular clusters were observed in the more central regions of the BM, where the brightness of PKH fluorescence decreased, indicating cellular division. These later clusters were classified as secondary, assuming that the mechanisms of migration in the BM might be different from those of primary seeding. Some clusters remained in the periphery of the BM and retained bright fluorescence, indicating cellular quiescence. The number of brightly fluorescent cells in the clusters decreased exponentially to two to three cells after 24 days (p < 0.001). The data suggest that the hematopoietic niche is a functional unit of the BM stromal microenvironment that hosts seeding of a number of transplanted cells, which form a cluster. This may be the site where auxiliary non-HSPC cells, such as T lymphocytes, act in support of HSPC engraftment.     

Gene-expression profiling of CD34+ hematopoietic cells expanded in a collagen I matrix

CD34+ hematopoietic stem/progenitor cells (HSCs) reside in the bone marrow in close proximity to the endosteal bone surface, surrounded by osteoblasts, stromal cells, and various extracellular matrix molecules. We used a bioartificial matrix of fibrillar collagen I, the major matrix component of bone, as a scaffold for ex vivo expansion of HSCs. CD34+ HSCs were isolated from umbilical cord blood and cultivated within reconstituted collagen I fibrils in the presence of fms-like tyrosine kinase-3 ligand, stem cell factor, and interleukin (IL)-3. After 7 days of culture, the cell number, number of colony-forming units (CFU-C), and gene-expression profile of the cultured cells were assessed. Although the total expansion factor of CD34+ cells was slightly lower when cells were cultivated in the collagen I gel, the frequency of CFU-C was greater than in control suspension cultures. Gene-expression analysis with microarray chip technology revealed the upregulation of more than 50 genes in the presence of collagen I. Among these, genes for several growth factors, cytokines, and chemokines (e.g., IL-8 and macrophage inhibitory protein 1alpha) could be confirmed using quantitative polymerase chain reaction. Furthermore, greater expression levels of the negative cell-cycle regulator BTG2/TIS21 and an inhibitor of the mitogen-activated protein kinase pathway, DUSP2, underline the regulatory role of the extracellular matrix. Together, these data show that the expansion of CD34+ cord blood cells in a culture system containing a three-dimensional collagen I matrix induces a qualitative change in the gene-expression profile of cultivated HSCs.     

Three-dimensional engineered bone from bone marrow stromal cells and their autogenous extracellular matrix

Most bone tissue-engineering research uses porous three-dimensional (3D) scaffolds for cell seeding. In this work, scaffold-less 3D bone-like tissues were engineered from rat bone marrow stromal cells (BMSCs) and their autogenous extracellular matrix (ECM). The BMSCs were cultured on a 2D substrate in medium that induced osteogenic differentiation. After reaching confluence and producing a sufficient amount of their own ECM, the cells contracted their tissue monolayer around two constraint points, forming scaffold-less cylindrical engineered bone-like constructs (EBCs). The EBCs exhibited alizarin red staining for mineralization and alkaline phosphatase activity and contained type I collagen. The EBCs developed a periosteum characterized by fibroblasts and unmineralized collagen on the periphery of the construct. Tensile tests revealed that the EBCs in culture had a tangent modulus of 7.5 +/- 0.5 MPa at 7 days post-3D construct formation and 29 +/- 9 MPa at 6 weeks after construct formation. Implantation of the EBCs into rats 7 days after construct formation resulted in further bone development and vascularization. Tissue explants collected at 4 weeks contained all three cell types found in native bone: osteoblasts, osteocytes, and osteoclasts. The resulting engineered tissues are the first 3D bone tissues developed without the use of exogenous scaffolding.     

人源化NOD/SCID小鼠免疫细胞的动态变化与鉴定

目的： 比较脐血干细胞与单个核细胞移植NOD/SCID鼠所建立的人源化SCID模型，分析人源化淋巴细胞重建。方法： 磁珠分选法分离脐血中CD34⁺细胞，淋巴细胞分层液分离脐血单个核细胞，分别经尾静脉输入NOD/SCID小鼠。每隔2周采血至10周，流式细胞术动态检测人源淋巴细胞CD45、CD19、CD3抗原。第10周处死小鼠收集外周血、骨髓、胸腺组织，RT-PCR检测模型鼠组织中人β₂M基因及RAG2基因。结果： 两种类型细胞移植均可重建人源免疫细胞，人源淋巴细胞表达水平均在第8周达高峰。骨髓中人源淋巴细胞表达水平明显高于外周血。RT-PCR在外周血与骨髓检测到人β₂M基因及RAG2基因标志。结论： CD34⁺细胞移植重建人源化NOD/SCID免疫系统模型效果要好于脐血单个核细胞。人源T淋巴细胞在模型鼠骨髓中分化成熟。     

Long-term culture of fetal liver cells using a three-dimensional porous polymer substrate

To develop a bioartificial liver, long-term culture of fetal liver cells over a month's time was performed under three different culture conditions, i.e., stationary cultures and shaken-flask cultures, both by using a substratum made of porous polyvinyl formal (PVF) resin and conventional monolayer dish cultures as controls. Time course changes in cell numbers and albumin secretion were evaluated in cultures using Williams' E medium (WE) or minimum essential medium alpha (aMEM) supplemented with serum and hormones. In the WE medium, the numbers of fetal liver cells in all culture conditions gradually decreased with time, and albumin secretion rates rapidly decreased. In the stationary cultures using PVF, however, a significant increase in albumin secretion was observed after two weeks of culture. When cells were cultured in aMEM, the fetal liver cells exhibited sufficient proliferation in stationary and monolayer cultures, although albumin secretion rates per single cell were lower than those in WE. On the basis of these results, another series of culture experiments were performed, in which aMEM was used for the first 10 days to encourage cell proliferation, and the medium was changed to WE afterward. In these cultures, albumin secretion rates in the stationary cultures dramatically increased after the medium exchanges and were maintained at these high levels throughout the remaining culture period.