Bone Intrinsic Material Properties in Three Inbred Mouse Strains

This study assessed genetically based differences in intrinsic material properties of both cortical and cancellous bone in adult females of three inbred mouse strains [C57BL/6J (B6), DBA/2J (D2), C3H/HeJ (C3)]. These mouse strains have previously been shown to differ in bone mineral content (BMC) and density (BMD). Distal femoral cancellous bone and midshaft cortical bone in femurs and tibias were assessed for intrinsic material properties using nanoindentation technique. The intrinsic material properties tested were modulus (E_b) and hardness (H) of the midshaft femoral and tibial cortical bone cross sections and of cancellous bone in the distal femur. Both femoral and tibial cortical bone intrinsic material properties were different among the three inbred mouse strains. Femoral modulus and tibial hardness in cortical bone and hardness in cancellous bone were either greatest or showed greater trends in C3 mice as compared to both D2 and B6. Cancellous bone modulus was similar among the three mouse strains. With the exception of the D2 mice, the femoral and tibial cortical modulus were similar within each mouse strain. The tibial cortical modulus was smaller than the femoral cortical modulus for D2 mouse strain. The cortical hardness was greater in tibiae compared with that in femora within each mouse strain. The nanoindentation data suggest that cortical and cancellous intrinsic material properties are influenced by the genetic background of the inbred mouse strains. The inbred mouse strain-related intrinsic material property phenotype can be used to locate responsible quantitative trait loci (QTLs) in future studies of recombinant inbred mouse strains.     

Supraphysiologic levels of testosterone affect cancellous and cortical bone in the young female Cynomolgus monkey

The goal of this study was to evaluate the effects of chronically-elevated male levels of the potent androgen testosterone on the quality and quantity of both cancellous and cortical bone in a young (mean age 8.0 years), nonhuman female primate model (M. fascicularis). Thirteen intact female monkeys received continuous testosterone supplementation via subcutaneous implants over a 24-month period. A group of 16 untreated, intact, age-matched female monkeys served as controls. At sacrifice, the lumbar vertebrae and femora were recovered in order to analyze the bone mineral quality and quantity of cancellous and cortical bone, respectively, and compared to the control group. Mineralization profiles of the vertebrae and femora were obtained using the density fractionation technique. Chemical analysis of the three largest fractions retrieved by density fractionation was performed to evaluate differences in %Ca, %P, Ca/P ratio, and mineral content (%Ca + %PO₄) between the control and experimental groups. In addition, unfractionated bone powder was examined by X-ray diffraction to identify any changes in crystal size. Coronal sections of vertebrae were analyzed for structural parameters using histomorphometry and image analysis. Cross sections taken at the midshaft diaphyseal femora were analyzed for structural macroscopic and intracortical parameters. A nonsignificant shift in the mineralization profile of the vertebrae was observed whereas there was a significant shift in the mineralization profile towards more dense bone in the treated femora as compared with controls (P < 0.05). There was no difference in terms of size/strain of the cortical or cancellous bone crystal as detected by X-ray diffraction. There was a trend towards an increase in cancellous bone area (B.Ar.) in the testosterone-treated vertebrae (P= 0.08) as compared with controls. The architecture of the cancellous bone remained nonsignificantly different between the treatment and control groups as evaluated by image analysis. There was a decrease in osteoid perimeter (P= 0.05) in the experimental group as compared with controls. There was a significant decrease in eroded perimeter measurements in the experimental group as compared with controls (P < 0.03). Although there was a trend towards an increase in cancellous bone area, mineralization was not significantly different in the vertebrae of testosterone-treated female monkeys, indicating that the newly-formed bone tissue became relatively normally mineralized over the two-year period. An increase in bone area, with indices of an overall decreased remodelling pattern as compared with controls, suggests that cancellous bone in the young, nonhuman female primate had been receptive to supraphysiologic levels of testosterone supplementation over the two-year period. There was a trend for an increase in cortical bone area and width with an increased periosteal perimeter in the testosterone-treated group as compare with controls. There was an increase in intracortical remodelling activity with a significant increase in percent porosity (P < 0.05), osteonal bone (P < 0.05), and mean wall width (P < 0.05) in the testosterone-treated group. In conclusion, the cancellous bone from female monkeys appeared to respond to the antiresorptive stimulus of male levels of testosterone with significantly diminished turnover parameters in this compartment. In contrast, the cortical bone compartment responded by displaying significant intracortical remodelling over a two-year period. Received: 22 December 1995 / Accepted: 3 April 1996     

Dramatic increase in cortical thickness induced by femoral marrow ablation followed by a 3‐month treatment with PTH in rats

We previously reported that following mechanical ablation of the marrow from the midshaft of rat femurs, there is a rapid and abundant but transient growth of bone, and this growth is enhanced and maintained over a 3‐week period by the bone anabolic hormone parathyroid hormone (PTH). Here, we asked whether further treatment with PTH or bisphosphonates can extend the half‐life of the new bone formed in lieu of marrow. We subjected the left femur of rats to mechanical marrow ablation and treated the animals 5 days a week with PTH for 3 weeks (or with vehicle as a control) to replace the marrow by bone. Some rats were euthanized and used as positive controls or treated with vehicle, PTH, or the bisphosphonate alendronate for a further 9 weeks. We subjected both femurs from each rat to soft X‐ray, peripheral quantitative computed tomography (pQCT), micro‐computed tomography (µCT), dynamic histomorphometry analysis, and biomechanical testing. We also determined the concentrations of serum osteocalcin to confirm the efficacy of PTH. Treatment with PTH for 3 months dramatically enhanced endosteal and periosteal bone formation, leading to a 30% increase in cortical thickness. In contrast, alendronate protected the bone that had formed in the femoral marrow cavity after marrow ablation and 3 weeks of treatment with PTH but failed to promote endosteal bone growth or to improve the biomechanical properties of ablated femurs. We further asked whether calcium‐phosphate cements could potentiate the formation of bone after marrow ablation. Marrow cavities from ablated femurs were filled with one of two calcium‐phosphate cements, and rats were treated with PTH or PBS for 84 days. Both cements helped to protect the new bone formed after ablation. To some extent, they promoted the formation of bone after ablation, even in the absence of any anabolic hormone. Our data therefore expand the role of PTH in bone engineering and open new avenues of investigation to the field of regenerative medicine and tissue engineering. Local bone marrow aspiration in conjunction with an anabolic agent, a bisphosphonate, or a calcium‐phosphate cement might provide a new platform for rapid preferential site‐directed bone growth in areas of high bone loss. © 2010 American Society for Bone and Mineral Research     

Depression of osteoblastic activity in immobilized limbs of suckling rats

Recently we characterized the immobilization-related osteopenia in adult rats and showed that it is caused by increased bone resorption and decreased bone formation (Weinreb et al. 1989 Bone 10:187). To assess the effect of age on disuse osteopenia, this study investigated the effects of immobilization on bone turnover in very young, suckling rats. The 15-day-old rats underwent unilateral hind limb immobilization by sciatic neurectomy; the contralateral limb was left intact and served as control. Experimental or sham-operated animals were killed after 0, 2, 4, or 12 days postsurgery. Dry, fat-free weight and ash weight were determined in both femora, and both tibiae were subjected to static and dynamic histomorphometry. Immobilization caused a progressive deficit in bone mass in the immobilized limb compared to the contralateral intact limb but did not affect femoral longitudinal growth. The total mineral content in the immobilized femora was 13.6% less than that in the intact limb by day 12. Concomitantly, tibial cancellous bone area and perimeter declined in the immobilized limb by 37.3 and 32.2%, respectively. This reduction in bone mass in the tibiae of immobilized limbs was associated with increased bone resorption, expressed as osteoclast perimeter, number of osteoclasts per mm surface, and number of osteoclasts per mm2 tissue area. Bone formation was reduced as a result of impaired osteoblast activity as evidenced by (1) decreased endocortical and trabecular mineral apposition rate; (2) reduced trabecular mineral formation rate; (3) decreased percentage of ash of the femoral dry weight; and (4) increased volume of unmineralized osteoid in the tibial metaphysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bone Mineral Density and Turnover Following Forelimb Immobilization and Recovery in Young Adult Dogs

The purpose of this experiment was to study changes in bone mass, structure, and turnover in the canine forelimb after unilateral immobilization and recovery. The right forelimbs of 14 adult mongrel dogs were immobilized for 16 weeks. Six dogs served as controls. Seven immobilized and three control dogs were euthanized at the end of the immobilization period. Recovery consisted of 16 weeks of kennel confinement followed by 16 weeks of treadmill exercise. Seven once-immobilized and three control dogs were euthanized at the end of the recovery period. Bone mineral density of both the proximal (PBMD) and central (CBMD) radius was determined by dual X-ray absorptiometry. Standard histomorphometric endpoints for bone mass and turnover were determined in the cancellous bone of the proximal radius. After immobilization, PBMD, CBMD, and trabecular thickness were lower in the immobilized limb than in either the contralateral or control limbs (P < 0.05). Only CBMD remained significantly lower (P < 0.05) after recovery. At the end of immobilization, bone formation endpoints were significantly higher in the immobilized limb than both the contralateral and control limbs. Bone turnover was also significantly lower in the contralateral limb than in the immobilized and control limbs. After recovery, all differences in bone turnover had resolved. Immobilization of 16 weeks duration caused an elevation in cancellous bone formation rate and reduced bone density in both cortical and cancellous bone. After 32 weeks of recovery, turnover abnormalities disappeared, cancellous bone normalized, but cortical bone mass remained low. Recovery of cortical bone from immobilization takes longer than recovery of cancellous bone. Received: 28 January 1996 / Accepted: 3 May 1996     

High-fat diet decreases cancellous bone mass but has no effect on cortical bone mass in the tibia in mice

Body mass has a positive effect on bone health. Whether mass derived from an obesity condition or excessive fat accumulation is beneficial to bone has not been established; neither have the mechanisms by which obesity affects bone metabolism. The aim of this study was to examine the effects of obesity on bone structure and osteoblastic expression of key markers involved in bone formation and resorption in a diet-induced obesity mouse model. Six-wk-old male C57BL/6 mice (n = 21) were assigned to two groups and fed either a control (10 kcal% energy as fat) or high-fat diet (HFD, 45 kcal% energy as fat) for 14 weeks. Bone marrow stromal/osteoblastic cells (BMSC) were cultured. Osteoprogenitor activity [alkaline phosphatase (ALP) positive colonies] and mineralization (calcium nodule formation) were determined. Gene expression was measured using quantitative real-time PCR. Bone structure of proximal and midshaft tibia was evaluated by micro-computed tomography. Mice fed the HFD were 31% heavier (P < 0.01) than those fed the control diet. There were more ALP positive colony forming units at d 14 and calcium nodules at d 28 of culture by BMSC from HFD mice than from control mice (P < 0.01). Receptor activator of NF-κB ligand (RANKL) mRNA levels and the ratio of RANKL to osteoprotegerin expression in HFD animals was higher (P < 0.01) than in control diet animals. Serum tartrate-resistant acid phosphatase levels were higher in HFD fed mice when compared to control diet fed mice (P < 0.05). There were no significant differences in tibial fat-free weight, length, and cortical parameters of midshaft between the two groups. Compared with control mice, tibial trabecular bone volume was reduced, and trabecular separation was increased in HFD mice. Trabecular number was lower (P < 0.05) and connectivity density tended to be less (P = 0.07) in HFD mice than in control mice. In conclusion, our data indicate that obesity induced by a high-fat diet decreases cancellous bone mass but has no effect on cortical bone mass in the tibia in mice.     

Androgen resistance and deficiency have different effects on the growing skeleton of the rat

Mature male, female, and androgen-resistant testicular feminized (Tfm) male rats of the same strain were sacrificed at the age of 120 days. Young male and Tfm rats were orchidectomized (orch) at 1 month of age and sacrificed at 120 days. The right femora were dissected, cleaned, defatted, and scanned with the Hologic QDR-1000. Orch and Tfm rats had similar body weights that were intermediate between body weights of their normal male and female littermates. Serum IGF-I concentrations were lowest in Tfm rats; IGF-1 concentrations in orch rats were not lower than in males. Dual-energy X-ray absorptiometry yielded the following results: Total femoral mass and area were lower in female, Tfm rats and in both orch groups compared with intact male rats. Femoral bone density was, however, only decreased in orch rats. Bone density measured in an area containing only cortical bone was not different between groups. However, the density was lower in orch rats in an area containing both cancellous and cortical bone. This finding is consistent with a ±50% decrease of cancellous bone volume in orch rats compared with all other groups at the proximal tibial metaphysis (an area containing mainly cancellous bone). These data show that Tfm rats, despite having lower IGF-I levels in serum, low body weight, and decreased femoral areas, manage—in contrast with orchidectomized rats—to maintain similar trabecular bone densities and volumes during growth. We conclude that trabecular bone densities can be preserved in androgen-resistant male rats independent of bone or body growth velocity or IGF-I secretion. We postulate that the modest increase of estrogen concentration in this animals and/or in situ aromatization may be responsible for the maintenance of the cancellous bone.     

The Effect of Androstenedione/Estrone Supplementation on Cortical and Cancellous Bone in the Young Intact Female Monkey: A Model for the Effects of Polycystic Ovarian Disease on the Skeleton?

The goal of this study was to determine the effects of chronically elevated blood androstenedione and estrone levels on the quality and quantity of both cancellous (trabecular) and cortical bone in a young (mean age 9.4 years) female primate model (M. fascicularis). Thirteen intact female monkeys received continuous androstenedione/estrone supplementation via subcutaneous implants over a 24-month period to simulate the human condition known as polycystic ovarian disease (PCOD). A group of 16 untreated intact age-matched female monkeys served as controls. Lumbar spine and whole body bone mineral density (BMD) status was determined mid-study by dual photon absorptiometry (DPA); subsequent analysis of the bone related to data obtained following the 2-year treatment period without further BMD measurement. Bone markers, including serum acid phosphatase, total bone alkaline phosphatase, bone gla protein and tartrate-resistant acid phosphatase were measured at the end of the study. At necropsy, the lumbar vertebrae and femora were recovered in order to analyze the bone mineral quality and quantity of cancellous and cortical bone respectively and to compare these with the control group. Mineralization profiles of the vertebrae and femora were obtained using the density fractionation technique. Chemical analysis of the three largest fractions retrieved by density fractionation was performed to evaluate differences in %Ca, %P, Ca/P ratio and mineral content (%Ca+%PO₄) between control and experimental groups. In addition, unfractionated bone powder was examined by X-ray diffraction to identify any changes in crystal size. Coronal sections of vertebrae were analyzed for structural parameters using histomorphometry and image analysis. Cross-sections taken at the midshaft diaphyseal femora were analyzed for structural macroscopic and intracortical parameters. There was a significant increase in BMD at the L2–L4 region in the treatment group compared with the control groups (p<0.005) as measured at 1 year into the trial. Serum acid phosphatase was significantly lower (p<0.05) in the treatment group compared with the controls near study termination. A nonsignificant shift in the mineralization profile of the vertebrae towards less dense bone was observed in the treatment group, while there was a significant shift in the mineralization profile towards more dense bone in the treated femora compared with controls (p<0.05) after a 2-year period. There was no difference between treatment and control groups in terms of size/strain of the cortical or cancellous bone crystal as detected by X-ray diffraction. There was a significant increase in cancellous bone area (B.Ar.) (p<0.02) and a significant increase (p<0.05) in mean trabecular width with a corresponding decrease in trabecular separation (p<0.03) in the experimental group compared with the controls. There were no significant changes in osteoid parameters (perimeter, area or width) or eroded perimeter measurements in the experimental group compared with the controls. In the experimental group, trabecular strut analysis showed a significant increase in the number of nodes (p<0.02) and in the total strut length (p<0.003) compared with the controls. There was also a significant increase in the node to node (p<0.04) and node to terminus (p<0.004) strut length in the treatment group compared with the controls. A significant increase in B.Ar. without concurrent indices of ongoing remodeling differing from controls suggests that cancellous bone of the vertebral body in the treated young female primate had been receptive to the anabolic stimulus of androstenedione/estrone supplementation over the 2-year period. In contrast, macroscopic parameters of cortical bone such as perimeter, area and width were preserved over the 2-year course, while intracortical remodeling was evident with increased percent porosity (p<0.001), osteonal bone (p<0.01) and osteonal density (p<0.01) observed in the treatment group compared with the controls. The endocrine profile of both elevated androstenedione and estrone levels in an intact female primate of reproductive age may identify differential effects of the condition known as polycystic ovarian disease on the skeletal compartments. Received: 24 November 1999 / Accepted: 4 April 2000     

Bone particles disturb new bone formation on the interface of the titanium implant after reaming of the marrow cavity

Histomorphometric studies were conducted in rats to determine whether bone particles would disturb new bone formation on the interface of titanium implants inserted after reaming of the marrow cavity. In eighty 10-week-old female Wistar rats, smooth-surfaced titanium alloy implants were inserted bilaterally into the marrow cavity after reaming in the distal femur. There were three experimental groups: in the irrigated femora, sterile saline was flushed through the medullary canal; in the particle femora, autologous bone particles were inserted into the intramedullary cavity; and in the reamed femora, the implant was inserted without procedures after reaming. The rats were sacrificed at one, two, four or eight weeks postoperatively, and Villanueva bone staining was applied for histomorphometric studies. The bone volume of new bone on the interface of the implant in the irrigated femora was greater than that in the particle or the reamed femora throughout the study period. The results suggest that clearance of bone particles by irrigation after reaming of the marrow cavity significantly facilitates new bone formation on the interface of implants by one week. The findings also suggest the potential clinical application of total canal irrigation prior to insertion of cementless femoral components as well as cemented prosthesis.     

Effects of basic fibroblast growth factor on osteoblast-related gene expression in the process of medullary bone formation induced in rat femur

 The effects of basic fibroblast growth factor (bFGF) on osteogenic differentiation in-vivo were investigated using a rat bone marrow ablation model. bFGF was infused directly into rat femora for 6 days after bone marrow ablation. The contralateral femur was infused with vehicle only and used as control. Bone formation was induced in the rat femoral cavity, and the gene expression of osteoblast markers was examined. Treatment with bFGF at 50 and 100 ng/day significantly enhanced the mRNA levels of osteopontin compared with the levels in the control leg, with increases of 25% and 24%, respectively. In contrast, bFGF infusion at 50 ng/day provoked a significant (nearly 20%) inhibition of expression for type I collagen. Infusion of bFGF at a higher dose exhibited an inhibitory tendency for bFGF action on gene expression. There were no significant changes in alkaline phosphatase and osteocalcin mRNA levels in response to any dose of bFGF. The findings presented here suggest that bFGF modulates osteogenic differentiation in-vivo and may play an important role in the process of bone remodeling. Received: February 22, 2002 / Accepted: October 7, 2002 Offprint requests to: H. Tanaka     

Effect of cortisone on cells at the bone-marrow interface

Summary A study of the association between the rate of proliferation of marrow fibroblast-like stromal cells (in vitro) and the rate of endosteal bone mineralization (EsMR) (in vivo) was undertaken in an osteopenic rat model. We report than 200 g male rats treated with cortisone acetate (5 mg/day for 7 days) exhibit decreases in marrow fibroblast colony-forming units (FCFU) and tetracycline-based measurements of EsMR at the level of the femoral midshaft. In cortisone-treated rats recovering for 1–3 weeks, the FCFU census and EsMR normalized during the first posttreatment week, remained at control levels after 2–3 weeks, and exhibited a relapse in the third week which signified only partial recovery. These changes were unrelated to patterns of body weight gain. The data indicate that the FCFU census can serve to index endosteal osteoblast vigor.     

Damaging Fatigue Loading Stimulates Increases in Periosteal Vascularity at Sites of Bone Formation in the Rat Ulna

Bone formation in a variety of contexts depends on angiogenesis; however, there are few reports of the vascular response to osteogenic skeletal loading. We used the rat forelimb compression model to characterize vascular changes after fatigue loading. The right forelimbs of 72 adult rats were loaded cyclically in vivo to one of four displacement levels, to produce four discrete levels of ulnar damage. Rats were killed 3–14 days after loading, and their vasculature was perfused with silicone rubber. Transverse histological sections were cut along the ulnar diaphysis. We quantified vessel number, average vessel area, total vessel area, and bone area. On day 3, we observed a dramatic periosteal expansion near the ulnar midshaft, with significant increases in periosteal vascularity; total vessel area was increased 250–450% (P < 0.001). Vascularity remained elevated on days 7 and 14. Vessel number and average vessel area were not correlated (P = 0.09) and contributed independently to total vascular increases. Bone area was not increased on day 3 but on days 7 and 14 was increased significantly in all displacement groups (P < 0.01) due to periosteal woven bone formation. Vascular and bone changes depended on longitudinal location (P < 0.001), with peak increases 2 mm distal to the midshaft. Vascular and bone changes also depended on displacement level (P < 0.005), with greater increases at higher levels of fatigue displacement. We conclude that skeletal fatigue loading induces a rapid increase in periosteal vascularity, followed by an increase in bone area. The angiogenic-osteogenic response is spatially coordinated and scaled to the level of the mechanical stimulus.     

Effects of long-term daily administration of prostaglandin-E2 on maintaining elevated proximal tibial metaphyseal cancellous bone mass in male rats

Summary The effects of long-term prostaglandin E₂ (PGE₂) on cancellous bone in proximal tibial metaphysis were studied in 7-month-old male Sprague-Dawley rats given daily subcutaneous injections of 0, 1, 3, and 6 mg PGE₂/kg/day and sacrificed after 60, 120, and 180 days. Histomorphometric analyses were performed on double fluorescent-labeled undecalcified bone specimens. After 60 days of treatment, PGE₂ produced diffusely labeled trabecular bone area, increased trabecular bone area, eroded and labeled trabecular perimeter, mineral apposition rate, and bone formation rate at all dose levels when compared with age-matched controls. In rats given PGE₂ for longer time periods (120 and 180 days), trabecular bone area, diffusely labeled trabecular bone area, labeled perimeter, mineral apposition, and bone formation rates were sustained at the elevated levels achieved earlier at 60-day treatment. The eroded perimeter continued to increase until 120 days, then plateau. The observation that continuous systemic PGE₂ administration to adult male rats elevated metaphyseal cancellous bone mass to 3.5-fold of the control level within 60 days and maintained it for another 120 days indicates that the powerful skeletal anabolic effects of PGE₂ can be sustained with continuous administration.     

Knee loading stimulates healing of mouse bone wounds in a femur neck

Healing of bone wounds is sensitive to various environmental stimuli. Using knee loading, which has been shown to stimulate bone formation in mouse femora and tibiae, we addressed a question: Does knee loading accelerate a closure of open wounds in a femur neck? A surgical wound (0.5 mm in diameter) was generated at the femur neck in the left and right femora of C57/BL/6 female mice, and knee loading was applied to the left knee for 3 min/day for 3 consecutive days. Surgical holes at the femoral midshaft were used as control. Animals were sacrificed 1, 2, and 3 weeks after surgery for analyses with μCT and pQCT as well as mechanical testing. The results showed load-driven acceleration of the closure of surgical holes. Compared to a sham-loaded contralateral control, knee loading reduced the size of surgical wounds in the femoral midshaft by 14% (p < 0.05), 21% (p < 0.01), and 32% (p < 0.001) in 1, 2, and 3 weeks, respectively. It also decreased the wound size in the femur neck by 16% (p < 0.001; 1 week), 18% (p < 0.001; 2 weeks), and 21% (p < 0.001; 3 weeks). Images with pQCT revealed that bone mineral density (BMD) was increased from 571 ± 19 mg/cm³ (control) to 686 ± 19 mg/cm³ (loaded) (p < 0.01), and bone mineral content (BMC) from 3.05 ± 0.12 mg/mm (control) to 3.42 ± 0.11 mg/mm (loaded) (p < 0.05). Furthermore, mechanical testing showed that stiffness of the femur was increased by knee loading (p < 0.05). This study demonstrates that knee loading is capable of accelerating healing of surgical wounds throughout the femur including the femoral midshaft and neck.     

The role of cell type in bone healing mediated by ex vivo gene therapy

Background The ideal cellular vehicle for use in cell-mediated gene therapy to enhance bone healing has not yet been identified. The purpose of this study was to compare the capacity of two types of cells transduced with retro-bone morphogenetic protein 4 (BMP4)—muscle-derived cells (MDCs) and unfractioned bone marrow stromal cells (BMSCs).Method Primary rat MDCs and unfractioned rat BMSCs were transduced with a retrovirus to express BMP4. A 7-mm, critical-sized femur defect was created in adult rats, and 5×10⁶ transduced cells were implanted into the femoral defect. Bone healing was monitored radiographically and histologically at 4, 8, and 12 weeks post-implantation.Results All specimens in the MDC-BMP4 group and BMSC-BMP4 group showed a bridging callus at 8 and 12 weeks. At 12 weeks post-implantation the calluses of the MDC-BMP4 femora displayed significantly higher bone photodensity than the BMSC-BMP4 femora (P<0.05). Histomorphometry revealed no difference between the two treatment groups. However, non-union between newly formed and original bone was observed in none of the MDC femora but in six femora from the BMSC-BMP4 group.Conclusion Both MDCs and unfractioned BMSCs can improve healing of a critical-sized bone defect following transduction of the cells with retroBMP4. However, MDCs appear to yield superior results when compared with BMSCs in terms of improved healing of segmental defects.     

含自体富集骨髓干细胞松质骨移植与自体松质骨镶嵌移植修复关节软骨缺损的对比研究

目的：评价含富集骨髓干细胞松质骨镶嵌移植与自体松质骨镶嵌移植两种方法修复兔膝关节骨软骨缺损的修复效果,为临床应用提供实验依据。方法：选健康3月龄新西兰兔16只,随机分成A、B两组,每组8只16膝。A组采用含富集自体骨髓干细胞的自体松质骨移植,B组采用自体松质骨移植。术后第12周处死动物取材,分别进行大体观察、光镜观察,并对观察指标采用Wakitani组织学评分法进行评分和秩和检验。结果：大体观察及光镜观察显示含富集骨髓干细胞松质骨镶嵌移植组大体观察关节面大多呈乳白色,表面比较平整,与周围软骨融合较好,未发现裂隙;光镜检查见关节软骨的厚度为正常软骨的2/3左右,表面较光滑,与周围组织接合较好,大多为透明软骨细胞;组织学评分为（4.44±1.41）分。自体松质骨镶嵌移植组大体观察见关节面呈灰白色,表面稍有凹陷,欠光整;光镜检查见关节软骨的厚度较薄,为正常软骨的1/3～1/2,移植物中央区域厚度更薄,见成纤维细胞和极少量透明软骨细胞;组织学评分为（8.93±1.18）分。两组组织学评分比较差异有统计学意义（P〈0.01）。结论：含富集骨髓干细胞松质骨镶嵌移植能以类透明软骨组织修复全层关节软骨缺损,可用于较大面积软骨缺损的修复。自体松质骨移植修复软骨缺损的能力较差。     

Trabecular bone volume and microdamage accumulation in the femoral heads of women with and without femoral neck fractures

Prostaglandin E₂ (PGE₂) possesses significant anabolic properties when administered systemically (i.e., it increases bone formation and, consequently, bone mass). We recently characterized the effects of a 3 week administration of 6 mg/kg PGE₂ into young rats and showed it increases cortical and cancellous bone mass and mechanical strength in long bones and bone density in the calvaria. We also found that a single dose of PGE₂ induces the expression of early-response genes (c-fos, c-jun, and egr-1) in bone marrow cells within these two types of bone. These observations, together with findings by others of new cancellous bone formation in PGE₂-treated animals, suggested that recruitment of osteoblasts from their precursors is a major mechanism of the anabolic effect of PGE₂. To test this hypothesis directly, we injected PGE₂ (6 mg/kg) or vehicle into 4-week-old rats for 2 weeks and then assessed the osteogenic potential of bone marrow in an ex vivo culture system. Primary and first-passage bone marrow cultures were established in the presence of β-glycerophosphate, ascorbate, and dexamethasone, and osteogenic differentiation was measured by bone nodule formation and alkaline phosphatase activity. This regimen increased bone mass expressed as femoral ash weight by 4.7% and tibial cancellous bone area by 38.3%. Nodule formation at 21 days was increased in both primary and first-passage cultures from PGE₂-treated rats despite seeding of the same number of marrow cells. Alkaline phosphatase activity was elevated in both primary and first-passage cultures from PGE₂-treated rats beginning 6–10 days after culture initiation. Cell proliferation was only slightly elevated in cultures from PGE₂-treated rats. These data strongly suggest that in vivo administration of PGE₂ induces the proliferation or differentiation of osteoprogenitor cells in bone marrow, and this effect takes a major part in its anabolic effect in vivo.     

Effect of recombinant human granulocyte colony-stimulating factor (rh G-CSF) on rat bone: Inhibition of bone formation at the endosteal surface of vertebra and tibia

The effect of recombinant human granulocyte colony-stimulating factor (rh G-CSF) on bone was evaluated by histomorphometry using Sprague-Dawley rats. rh G-CSF was injected at doses of 0, 50, 150, and 450 μg/kg for 6 weeks.In vivo double fluorochrome labeling was performed before sacrifice. No significant change in body weight was observed. Bone mineral density (BMD) of lumbar vertebrae and femora was significantly decreased in G-CSF-treated groups. In the lumbar vertebra, osteoid surface, osteoid thickness, trabecular thickness, and labeled surface in G-CSF-treated groups were also significantly lower. In addition, osteoclast number and osteoclast surface were significantly higher in the G-CSF-treated groups. The endocortical surface at the mid-tibia showed lower labeled surface and mineral apposition rate in G-CSF-treated groups, without significant changes at the periosteal surface. Furthermore, numerous granulocytes fully occupied the bone marrow area. We conclude that proliferating granulocytes in the bone marrow may inhibit bone-forming cells from contacting the bone surface, resulting in reduction of bone formation;and increased osteoclastic bone resorption induced by G-CSF treatment contributed to the reduction of BMD.     

Immobilization-related bone loss in the rat is increased by calcium deficiency

Summary The object of this study was to investigate whether a calcium-deficient diet increases the bone loss produced by mechanical hypofunction (disuse) in the rat. Male Sprague-Dawley rats of approximately 150 g were placed on either a normal diet or a calcium-deficient diet. After 7 days, all rats underwent unilateral hind-limb immobilization by sciatic neurectomy and were sacrificed 30 hours, 72 hours, or 10 days postsurgery. Femora were ashed and the total mineral content (ash weight) was determined. Tibiae were embedded, sectioned, and stained. The metaphyseal secondary spongiosa and the diaphyseal cortical bone were subjected to histomorphometric analysis. Femoral length and serum calcium were not affected by calcium intake or immobilization. Serum parathyroid hormone levels were elevated in rats on the calcium-deficient diet compared to those on the normal diet. Calcium deficiency caused a significant reduction in femoral ash weight (20–35%), tibial cortical thickness (16–20%), and trabecular bone volume (TBV) (33–39%) at 72 hours and 10 days postsurgery. Additional loss of bone mass occurred in the immobilized limb compared to the contralateral intact limb of both dietary groups. This loss occurred earlier (30 hours postsurgery versus 72 hours) in the animals on a calcium-deficient diet and was larger compared to animals on a normal diet (10.6% versus 4.8% at 72 hours and 17.9% versus 12.45% at 10 days). The total bone loss induced by the combination of a calcium-deficient diet and immobilization in this experiment was estimated to equal 46% of femoral ash weight and 79% of tibial TBV. Calcium deficiency increased the number of osteoclasts/mm bone surface in the secondary spongiosa by 25–45%. Immobilization caused a further increase of 50–60% by 72 hours postsurgery. Endosteal mineral apposition rate was significantly decreased (27–44%) by immobilization but was not altered by the low-calcium diet. These data suggest that dietary calcium deficiency augments immobilization-related osteopenia by increasing bone resorption.