Implant-stimulated interface reactions during collagenous bone matrix-induced bone formation

The sequential cellular reactions in the interface of collagenous bone matrix implants are described. The multistep cascade in response to bone matrix implantation include: binding of fibrin and fibronectin to the implanted matrix, chemotaxis of cells, proliferation of fibroblasts, differentiation into chondroblasts, cartilage formation, vascular invasions, bone formation, remodeling, and bone marrow differentiation. The mechanisms of action is not known. However, several properties governing the implant-cell interface are described. It is possible that bone matrix is a suitable biomaterial with potential applications in periodontal and orthopedic practice.     

试剂对脱钙骨基质成骨能力影响的实验研究

目的 :研究异体骨基质制备过程中常用的脱脂和脱钙试剂溶液对其成骨能力的影响。方法 :8周鼠龄的Wistar雌鼠作为供体 ,切取胫股骨 ,碾磨成 12 5～ 80 0微米的颗粒 ,分成四组 ,分别用丙酮 -盐酸、丙酮 -乙二胺四乙酸 (EDTA)、三氯甲烷 -甲醇 -EDTA或三氯甲烷 -甲醇 -盐酸 (控制组 )脱脂和脱钙。冷冻干燥处理后 ,每 3 0mg装入一胶囊中。 60只 6周鼠龄的Wistar雌鼠作为受体 ,植入腰背肌中 ,每只鼠接受同一组植入材料 2枚。术后 6周取标本测定重量、干燥后的重量、钙含量、碱性磷酸酶含量和组织形态学定量测定。结果 :丙酮 -盐酸组的干燥重量 (P <0 .0 1)和钙含量 (P <0 .0 5 )明显高于控制组。结论 :用丙酮清除脂质的异体骨基质成骨能力优于用三氯甲烷 -甲醇混合液。EDTA或盐酸脱钙对其成骨能力无明显影响。     

Stromal components in rat bone marrow frozen sections compared to long-term rat bone marrow cultures

The haematopoietic microenvironment is believed to play an important role in controlling the haematopoietic process. Ultrastructural studies have shown that the haematopoietic stroma is composed of cellular as well as extracellular components. Relatively little is known about the distribution of the different stromal components in the bone marrow. The knowledge on the bone marrow microenvironment is mainly based on studies in which in vitro long-term bone marrow cultures have been used. Although this culture system offers a unique possibility to study haematopoietic in vitro, it does not fully represent the complexity of intact bone marrow.In the present study we describe the immunohistochemical distribution of different cellular and extracellular stromal components in frozen sections of rat bone marrow as well as in long-term bone marrow cultures, in order to compare the haematopoietic microenvironment used in in vitro studies in the in situ situation. We found that in situ a specific compartmentalization of stromal components exists in the bone marrow. Under culture conditions however, most stromal components are indeed present but the architecture present in the in situ situation had almost completely disappeared. The interaction between the different stromal elements was studied in the long-term bone marrow cultures. It appeared that under the chosen conditions, nodules were formed with a core of reticular cells and extracellular matrix. In close contact with this core immature macrophages appeared to proliferate and differentiate into mature, non-dividing macrophages.     

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.     

B cell development in the bone marrow

Recent years have produced considerable progress in defining stages in the development of B cells in vivo, and in revealing interactions with regulatory molecules and cells. Studies of the phenotype and population dynamics of precursor B cells in mouse bone marrow have quantitated cell production at sequential steps of differentiation and have also indicated a substantial cell death. The proliferation of precursor B cells is influenced both by systemic factors and by cytokines derived from bone marrow stromal cells. In situ immunolabeling has revealed that early precursor B cells are closely associated with subosteal stromal cells, aberrant B lineage cells appear to be deleted by macrophages and terminal B cells mature within the lumen of vascular sinusoids before being released. The findings lead to working models of the in vivo differentiation, regulation and microenvironmental organization of B cell genesis in the bone marrow.     

Osteoclast formation in vitro from bone marrow mononuclear cells in osteoclast-free bone

Recent evidence points to the fact that osteoclasts are derived from mononuclear cells of hematopoietic bone marrow. In this study we have examined the formation of osteoclasts from mononuclear cells in vitro. The mononuclear cells were isolated after 7 days from cultures of mouse bone marrow cells. The isolated cells were co-cultured with osteoclast-free, fetal-mouse calvaria. After 10 to 14 days of co-culture, multinucleated cells which have all the characteristics of osteoclasts were found in juxtaposition to seams of woven bone. These data strongly suggest that bone marrow mononuclear cells, when suitably induced, can give rise to osteoclasts in vitro.     

Replacement of bone marrow by bone in rat femurs: the bone bioreactor

During development and repair of bone, two distinct yet complementary mechanisms, intramembranous and endochondral, mediate new bone formation via osteoblasts. Because mechanical bone marrow ablation leads to the rapid and transient formation of new bone in the marrow cavity, we postulated that parathyroid hormone (PTH), which is a bone anabolic hormone, enhances the formation of new bone that forms after marrow ablation. We subjected the left femur of rats to mechanical marrow ablation, or sham operation, and injected the animals daily with PTH or vehicle for 1, 2, or 3 weeks in a first experiment, then with PTH, parathyroid hormone-related peptide (PTHrP), or vehicle for 3 weeks in a second experiment. We subjected both femurs from each rat to soft X-ray, peripheral quantitative computed tomography, computed tomography on a microscale, and histological analysis, and determined the concentration of serum osteocalcin. In addition, in the second experiment, we determined the serum concentration of calcium, tartrate-resistant acid phosphatase (TRAP), and receptor activator of NF-kappaB ligand (RANKL) at 3 weeks, and subjected femurs to biomechanical testing. Following treatment with PTH or PTHrP for 3 weeks, bone filled the marrow cavity of the shafts whose marrow had been ablated. PTH increased trabecular density in the right femur, but failed to induce bone formation in the medullary region of the right unoperated femoral shafts. The newly formed bone endowed left femoral shafts with improved biomechanical properties when compared to those of right femurs and left femurs from control, sham-operated, and vehicle-treated rats. PTHrP, like PTH, increased serum osteocalcin, but neither increased serum calcium, TRAP, or RANKL at 3 weeks. Our results reveal that the newly formed bone that follows marrow ablation is responsive to PTH, expand the role of PTH in bone, and might open new avenues of investigations to the field of regenerative medicine and tissue engineering. Local bone marrow removal in conjunction with pharmacologic intervention with an anabolic agent might provide a technique for rapid preferential site-directed bone growth in areas of high bone loss.     

Antigenic stimulation of bone marrow colony forming cells: I. Effect of antigens on normal bone marrow cells in vitro

The incorporation of some antigens such as bacterial endotoxin, heterologous erythrocytes and bacterial flagellin preparations can enhance the formation of colonies in cultures of normal mouse bone marrow or foetal liver cells in vitro. Other antigens such as foreign serum proteins and haemocyanin are inactive. This effect depends on the reaction of antigen with a component of normal mouse serum.     

大鼠骨髓间质干细胞对同种骨髓移植后造血重建和免疫重建的作用

目的：探讨大鼠骨髓间质干细胞（MSC）对 同种异体骨髓移植造血重建和免疫重建的影响。方法:建立大鼠同种异 体骨髓移植模型，通过生存率分析、外周血象检测、免疫细胞计数和受体免疫功能检测，综 合评价MSC对骨髓移植(bone marrow transplantation,BMT)后造血重建和免疫重建的作用。 结果：(1) MSC可促进BMT后造血重建：移植后30 d，共移植组外周血白 细胞、淋巴细胞和血小板数均高于单纯骨髓移植组；共移植组骨髓细胞数也高于对照组。(2 )MSC可促进BMT后免疫重建：移植后30 d，共移植组胸腺细胞数、脾细胞总数均高于骨髓单 纯移植组；共移植组对ConA、LPS 刺激的淋巴细胞增殖反应以及对第三体来源的同种混合淋 巴细胞反应均强于单纯BMT组。结论：大鼠MSC与骨髓共移植对同种异体 骨髓移植造血重建和免疫重建有一定促进作用。     

Adipocytic proportion of bone marrow is inversely related to bone formation in osteoporosis

AIMS: Preliminary studies have suggested that there is an increase in adipocytic tissue in osteoporotic (OP) bone, supporting in vitro evidence for a switch in differentiation of stromal cells from the osteoblastic to the adipocytic lineage. To investigate this the variation of the ratio of adipose tissue to haemopoietic/stromal tissue in OP bone was measured. METHODS: The ratio of adipocytic to haemopoietic/stromal tissue (A/H) was measured by semi-automated image analysis in iliac crest biopsies from 127 patients with osteoporosis (84 female patients, 48 male patients; mean age, 55 years; range, 5-80). Fourteen patients with normal histomorphometric data (nine women; five men; mean age, 48 years; range 21-70) acted as controls. RESULTS: The ratio of A/H was higher in OP bone than in the normal controls (OP mean 43.06% v normal mean 22.4%; p < 0.001). Multiple regression analysis showed that 98.5% of the variability in the A/H ratio was the result of age and several measures of bone formation, including cancellous wall thickness, osteoid volume, cancellous thickness, cortical wall thickness, cancellous apposition rate, and bone formation rate, together with cancellous separation (each significant at p < 0.001). Those with the greatest effect on the A/H ratio (in decreasing order) were cancellous apposition rate, osteoid volume, and age. CONCLUSIONS: Cancellous apposition rate, osteoid volume, and age were associated with the increase in the proportion of adipose tissue present in OP bone. Of these, cancellous apposition rate reflects osteoblast activity, indicating that the increase in the volume of adipose tissue in osteoporosis is associated with reduced bone formation, supporting the postulated switch in differentiation of stromal cells from the osteoblastic to the adipocytic pathway in osteoporosis.     

Fate of bone marrow stromal cells in a syngenic model of bone formation

Bone marrow stromal cells (BMSCs) have been demonstrated to induce bone formation when associated to osteoconductive biomaterials and implanted in vivo. Nevertheless, their role in bone reconstruction is not fully understood and rare studies have been conducted to follow their destiny after implantation in syngenic models. The aim of the present work was to use sensitive and quantitative methods to track donor and recipient cells after implantation of BMSCs in a syngenic model of ectopic bone formation. Using polymerase chain reaction (PCR) amplification of the Sex determining Region Y (Sry) gene and in situ hybridization of the Y chromosome in parallel to histological analysis, we have quantified within the implants the survival of the donor cells and the colonization by the recipient cells. The putative migration of the BMSCs in peripheral organs was also analyzed. We show here that grafted cells do not survive more than 3 weeks after implantation and might migrate in peripheral lymphoid organs. These cells are responsible for the attraction of host cells within the implants, leading to the centripetal colonization of the biomaterial by new bone.     

Humoral nature of the colony-stimulating action of bone marrow cells on stromal colony formation in bone marrow culture

N. F. Gamaleya Research Institute of Epidemiology and Microbiology, Academy of Medical Sciences of the USSR, Moscow. (Presented by Academician of the Academy of Medical Sciences of the USSR D. S. Sarkisov.) Translated from Byulleten' Éksperimental'noi Biologii i Meditsiny, Vol. 110, No. 11, pp. 509–510, November, 1990.