Structural changes in rat bone subjected to long-term, in vivo mechanical loading.

Woven bone formation is commonly observed when grossly altered loading conditions are imposed upon living bone tissue. The fate of this woven bone with time has not been fully characterized. In this study, rats underwent daily bending of the right tibia for a period of 3 to 14 weeks. New bone was formed in the region of maximum bending stresses on the right tibiae of all rats that underwent daily loading. The new bone was at first poorly mineralized with disorganized collagen structure. With time, the new bone consolidated into a well mineralized primary bone structure similar in appearance to pre-existing nonlamellar bone within the tibial cortex. Using the data from this study and previous studies, we were able to outline the sequence of events that occur during bone adaptation in the rat tibia loading model. Explosive new woven bone formation began to occur five days after the initial four-point bending session, and the amount of woven bone reached a peak after about 15 days. After the third week the new bone began to consolidate. Rapid mineralization occurred during the third and fourth weeks, with less rapid mineralization occurring for several weeks thereafter. After the 14 weeks, the new bone was fully mineralized, and new bone formation had stopped.     

Noninvasive loading of the rat ulna in vivo induces a strain-related modeling response uncomplicated by trauma or periostal pressure

Adaptive changes in bone modeling in response to noninvasive, cyclic axial loading of the rat ulna were compared with those using 4-point bending of the tibia. Twenty cycles daily of 4-point bending for 10 days were applied to rat tibiae through loading points 23 and 11 mm apart. Control bones received nonbending loads through loading points 11 mm apart. As woven bone was produced in both situations, any strain-related response was confounded by the response to direct periosteal pressure. Four-point bending is not, therefore, an ideal mode of loading for the investigation of strain-related adaptive modeling. The ulna's adaptive response to daily axial loading over 9 days was investigated in 30 rats. Groups 1–3 were loaded for 1200 cycles: Group 1 at 10 Hz and 20 N, Group 2 at 10 Hz and 15 N, and Group 3 at 20 Hz and 15 N. Groups 4 and 5 received 12,000 cycles of 20 N and 15 N at 10 Hz. Groups 1 and 4 showed a similar amount of new bone formation. Group 4 showed the same pattern of response but in reduced amount. The responses in Groups 2 and 3 were either small or absent. Strains were measured with single-element, miniature strain gauges bonded around the circumference of dissected bones. The 20 N loading induced peak strains of 3500–4500 strain. The width of the periosteal new bone response was proportional to the longitudinal strain at each point around the bone's circumference. It appears that when a bone is loaded in a normal strain distribution, an osteogenic response occurs when peak physiological strains are exceeded. In this situation the amount of new bone formed at each location is proportional to the local surface strain. Cycle numbers between 1200 and 12,000, and cycle frequencies between 10 and 20 Hz have no effect on the bone's adaptive response.     

Cyclooxygenase-2 Inhibition Delays the Attainment of Peak Woven Bone Formation following Four-Point Bending in the Rat

Fracture healing is retarded in the presence of cyclooxygenase-2 (COX-2) inhibitors, demonstrating an important role of COX-2 in trauma-induced woven bone adaptation. The aim of this experiment was to determine the influence of COX-2 inhibition on the remodeling and consolidation of nontraumatic woven bone produced by mechanical loading. A periosteal woven bone callus was initiated in the right tibia of female Wistar rats following a single bout of four-point bending, applied as a haversine wave for 300 cycles at a frequency of 2 Hz and a magnitude of 65 N. Daily injections of vehicle (VEH, polyethylene glycol) or the COX-2 inhibitor 5,5-dimethyl-3-3(3 fluorophenyl)-4-(4-methylsulfonal)phenyl-2(5H)-furanone (DFU, 2.0 mg · kg⁻¹ and 0.02 mg · kg⁻¹ i.p.), commenced 7 days postloading, and tibiae were examined 2, 3, 4, and 5 weeks postloading. Tibiae were dissected, embedded in polymethylmethacrylate, and sectioned for histomorphometric analysis of periosteal woven bone. No significant difference in peak woven bone area was observed between DFU-treated and VEH rats. However, treatment with DFU resulted in a temporal defect in woven bone formation, where the achievement of peak woven bone area was delayed by 1 week. Woven bone remodeling was observed in DFU-treated rats at 21 days postloading, demonstrating that remodeling of the periosteal callus is not prevented in the presence of a COX-2 inhibitor in the rat. We conclude that COX-2 inhibition does not significantly disrupt the mechanism of woven bone remodeling but alters its timing.     

Bones' adaptive response to mechanical loading is essentially linear between the low strains associated with disuse and the high strains associated with the lamellar/woven bone transition

There is a widely held view that the relationship between mechanical loading history and adult bone mass/strength includes an adapted state or “lazy zone” where the bone mass/strength remains constant over a wide range of strain magnitudes. Evidence to support this theory is circumstantial. We investigated the possibility that the “lazy zone” is an artifact and that, across the range of normal strain experience, features of bone architecture associated with strength are linearly related in size to their strain experience. Skeletally mature female C57BL/6 mice were right sciatic neurectomized to minimize natural loading in their right tibiae. From the fifth day, these tibiae were subjected to a single period of external axial loading (40, 10‐second rest interrupted cycles) on alternate days for 2 weeks, with a peak dynamic load magnitude ranging from 0 to 14 N (peak strain magnitude: 0–5000 µε) and a constant loading rate of 500 N/s (maximum strain rate: 75,000 µε/s). The left tibiae were used as internal controls. Multilevel regression analyses suggest no evidence of any discontinuity in the progression of the relationships between peak dynamic load and three‐dimensional measures of bone mass/strength in both cortical and cancellous regions. These are essentially linear between the low‐peak locomotor strains associated with disuse (～300 µε) and the high‐peak strains derived from artificial loading and associated with the lamellar/woven bone transition (～5000 µε). The strain:response relationship and minimum effective strain are site‐specific, probably related to differences in the mismatch in strain distribution between normal and artificial loading at the locations investigated. © 2012 American Society for Bone and Mineral Research.     

Bone Response to In Vivo Mechanical Loading in Two Breeds of Mice

We investigated the bone response to external loading in C57BL/6J and C3H/HeJ mice, both breeds with low and high bone density, respectively. An in vivo tibial four-point bending device previously used for application of measured external loads in rats was adapted for mice. It delivered a uniform medio-lateral bending moment to the region of the tibia located 1–5.5 mm proximal to the tibio-fibula junction. The right legs of six C57BL/6J [low bone density (LBD)] and C3H/HeJ [high bone density (HBD)] mice were externally loaded in the device for 36 cycles/day at 2 Hz, 6 days/week for 2 weeks at 9.3 ± 0.9 N force, inducing estimated lateral periosteal surface compressive strains of 5121 ± 1128 με in C3H/HeJ (HBD) mice (n = 6), significantly higher than the estimated 3988 ± 820 με in C57BL/6J mice (n = 6) (mean ± SD). In addition, C3H/HeJ HBD mice (n = 11) were externally sham (pad pressure or no bending) loaded in the device for 36 cycles/day at 2 Hz, 3 days/week for 3 weeks at 9.3 ± 0.9 N force. Calcein injections for bone labeling were given at the 10th and 3rd days before sacrifice. At the end of the experiment, all mice were killed and both tibiae were removed, fixed, embedded, and cross-sectioned through the loaded region. Both tibiae were measured for marrow area (Ma.Ar), cortical area (Ct.Ar), total area (Tt.Ar), cross-sectional moment of inertia (CSMI), and periosteal and endocortical woven bone surface (Wo.B/BS), single-labeled surface (sLS), double-labeled surface (dLS), and total formation surface (FS/BS). Differences in all variables due to breed and loading (both bending and sham-bending) were tested by two-way analysis of variance (ANOVA) (P < 0.05). Ma.Ar, Tt.Ar, and CSMI were greater in C57BL/6J (LBD) than in C3H/HeJ (HBD) mice. Periosteal and endocortical woven bone and formation surface were increased significantly more by loading (bending) in C57BL/6J than in C3H/HeJ mice. Periosteal woven bone response due to sham-bending or sham-loading was significantly lower than due to bending loads in the C3H/HeJ mice. We conclude that the bone response to external loading is greater in LBD mice than in HBD mice. The high bone density of C3H/HeJ (HBD) mice is related to breed-specific factors other than the response to loading. Received: 5 March 1997 / Accepted: 8 April 1998     

Viscoelastic response of the rat loading model: implications for studies of strain-adaptive bone formation.

Studies of the adaptive skeletal response to mechanical loading require appropriate animal models. Two new approaches involve the nonsurgical application of loads to either the ulna or tibia of rats. Both of these approaches require the loading of bone through adjacent soft tissues, and thus the tissue viscoelasticity might affect the way load is transferred to the bone. The objective of this study was to characterize the mechanical strain in the rat tibia or ulna during applied loading at different frequencies. For the rat ulna model, loading was applied to the ulnae of four adult, female rats as a haversine waveform at frequencies of 1, 2, 5, 10, and 20 Hz and peak loads of 5, 10, 15, and 20 N. Mechanical strain was measured on the medial and lateral ulnar surfaces using single element strain gauges. For the rat tibia model, four-point bending loads were applied to the right tibiae of seven rats at frequencies of 0.5, 1, 2, 5, 10, and 20 Hz and peak loads of 30, 40, 50, and 60 N. Mechanical strain was measured on the lateral tibial surface at 5 mm proximal to the tibiofibular junction. We found that peak strains were linearly proportional to applied load, but decreased logarithmically as loading frequency was increased, indicating a significant viscoelastic effect in the soft tissues surrounding the ulnocarpal joint and in the soft tissues surrounding the tibia shaft. The viscoelastic response of the ulna and tibia tends to "filter out" high-frequency loading components and, as a result, the rat loading systems act as a low-pass filter. Consequently, any experiment designed to test the effect of loading frequency on bone formation in the rat ulna and tibia should employ progressively larger loads at higher loading frequencies to guarantee a consistent peak strain magnitude in the bone. The filtering effect of the ulna loading system is illustrated by an analysis of the strain waveforms from the recent study by Mosley and Lanyon (Bone 23:313-318; 1998) that was designed to evaluate the effect of strain rate on bone formation.     

The angiogenic peptide pleiotrophin (PTN/HB-GAM) is expressed in fracture healing: an immunohistochemical study in rats

Introduction Formation of new blood vessels is essential for the process of fracture healing.Materials and methods We investigated the expression of the angiogenic factor pleiotrophin/HB-GAM in a closed fracture model in rats by immunohistochemical methods.Results Histologically, 5 days after fracture the callus was predominantly composed of fibrous tissue. On day 10 a prominent chondral callus connected both ends of the fractured tibia. There was a continuous transition from the chondral callus to the newly formed bone adjacent to the corticalis of the tibia. On day 15 the amount of woven bone had increased, and in 3 of 5 animals the proximal and distal tibiae were connected by a bridge of woven bone. Pleiotrophin could be immunostained in fibroblasts and endothelial cells of the fibrous tissue between the fractured tibia ends. The chondral callus remained largely pleiotrophin-negative. Only single chondrocytes adjacent to the newly formed bone were pleiotrophin-positive. On days 10 and 15 strong immunoreactivity for pleiotrophin in the well vascularized, newly formed, woven bone was detectable. Osteoblasts, endothelial cells and fibroblasts were strongly pleiotrophin-positive.Conclusions These results show the presence of the angiogenic peptide pleiotrophin during fracture healing.     

Effect of parathyroid hormone on cortical bone response to in vivo external loading of the rat tibia

Cortical bone responses following administration of parathyroid hormone (PTH) were evaluated using a four-point bending device to clarify the relationship between the effect of PTH and mechanical loading. Female Wistar rats, 36-months-old, were used. Rats were randomized into three groups (n = 10/group), namely PTH-5 (5 μg PTH/kg body weight), PTH-30 (30 μg PTH/kg body weight), and PTH-v (vehicle). PTH (human PTH (1–34)) was injected subcutaneously three times/week for 3 weeks. Loads on the right tibia were applied in vivo at 29.1 ± 0.3 N for 36 cycles at 2 Hz 3 days/week for 3 weeks using four-point bending. The administration of PTH and tibial mechanical loading were performed on the same day. After calcein double labeling, rats were killed and tibial cross-sections were prepared from the region with maximal bending at the central diaphysis. Histomorphometry was performed over the entire periosteal and endocortical surfaces of the tibiae, dividing the periosteum into lateral and medial surfaces. The in vivo average peak tibial strains (predicted) on the lateral periosteal surface were 1392.4, 1421.8 and 1384.7 μstrain in PTH-v, PTH-5 and PTH-30 groups, respectively, showing no significant difference among the three groups. Significant loading-related increases in the bone formation surface, mineral apposition rate, and bone formation rate were observed at the periosteal and endocortical surfaces. Significant differences between PTH groups were also seen. Interaction between mechanical loading and PTH was significant at both periosteal and endocortical surfaces. It is concluded that PTH has a synergistic effect on the cortical bone response to mechanical loading. Received: October 4, 2000 / Accepted: January 12, 2001     

The response of rat tibiae to incremental bouts of mechanical loading: A quantum concept for bone formation

To investigate the minimum number of loading bouts necessary to produce new lamellar or woven bone formation, and the time required for its initiation, bone formation was measured in 32 retired breeder female Sprague-Dawley rats following one, two, three, or five bouts of applied loading. Bending forces of 54 N were applied to right tibiae using a four-point loading apparatus, and left tibiae served as contralateral controls. Loading was applied as a sine wave with a frequency of 2 Hz for 18 s (36 cycles) per loading bout. Rats were injected with alizarin on day 1 and calcein on days 5 and 12, and were killed on day 19. One bout of loading was sufficient to increase the periosteal woven bone surface (Wb.Pm/B.Pm) from 0% to 40% (p < 0.01), and to 80% after five bouts of loading (p < 0.01), with a dose-response relationship for increases in Wb.Pm/B.Pm (p < 0.0001), mineral apposition rate (Wb.AR; p = 0.002), and bone formation rate (Wb.BFR/BS; p = 0.0001). In the first labeling period (days 1–5), the endocortical lamellar bone forming surface (BS_f/BS) was increased slightly (p < 0.05), but no significant differences were shown for BFR/BS or MAR. From days 5 to 19, right tibiae showed a dose-response increase in BFR/BS (p = 0.002) and BS_f/BS (p = 0.008), but not MAR. These results are consistent with a “quantum” model of bone formation such that a “quantum” of bone cells is activated in response to the loading bout and the strain magnitude dictate the size or microstructural organization of a given packet of new bone. Conversely, the distributed nature of loading may define the recruitment, rather than size, of new packets of bone.     

Partitioning a daily mechanical stimulus into discrete loading bouts improves the osteogenic response to loading.

A single 3-minute bout of mechanical loading increases bone formation in the rat tibia. We hypothesized that more frequent, shorter loading bouts would elicit a greater osteogenic response than a single 3-minute bout. The right tibias of 36 adult female Sprague-Dawley rats were subjected to 360 bending cycles per day of a 54 N force delivered in 1, 2, 4, or 6 bouts on each of the 3 loading days. Rats in the 6-bouts/day group received 60 bending cycles per bout (60 x 6); rats in the 4-bouts/day group received 90 bending cycles per bout (90 x 4); the 2- and 1-bouts/day groups received 180 and 360 bending cycles per bout, respectively (180 x 2 and 360 x 1). A nonloaded, age-matched control group (0 x 0) and two sham-bending groups (60 x 6 and 360 x 1) also were included. Fluorochrome labeling revealed a 10-fold increase in endocortical lamellar bone formation rate (BFR/bone surface [BS]) in the right tibia versus the left (nonloaded) side in the 60 x 6 bending group. Endocortical BFR/BS in the right tibia of the 4-, 2-, and 1-bout bending groups exhibited 8-, 4-, and 4-fold increases, respectively, over the control side. Relative (right minus left) values for endocortical BFR/BS, mineralizing surface (MS/BS), and mineral apposition rate (MAR) were 65-94% greater in the 90 x 4 and 60 x 6 bending groups compared to the 360 x 1 bending group. Sham-bending tibias exhibited relative endocortical bone formation values similar to those collected from the control (0 x 0) group. The data show that 360 daily loading cycles applied at intervals of 60 x 6 or 90 x 4 represent a more osteogenic stimulus than 360 cycles applied all at once, and that mechanical loading is more osteogenic when divided into discrete loading bouts. Presumably, bone cells become increasingly "deaf" to the mechanical stimulus as loading cycles persist uninterrupted, and by allowing a rest period between loading bouts, the osteogenic effectiveness of subsequent cycles can be increased.     

Bone response to mechanical loading in adult rats with collagen-induced arthritis

To elucidate the effects of inflammation on the response of bone to mechanical stress, we performed experiments using a rat with collagen-induced arthritis (CIA) model. Six-month-old female Wistar rats were used in the experiment. Bovine type II collagen sensitization and additional sensitization after 1 week were preformed in all CIA groups. Loads were applied using a four-point bending device. The right tibia was loaded in both CIA and control (CONT) groups at 35 N (low groups), 40 N (medium groups), or 47 N (high groups) for 36 cycles at 2 Hz three times per week for 3 weeks. Histomorphometrical data were collected from the periosteal and endosteal surfaces of the tibia in all rats. The tibia periosteal surface was subdivided into lateral and medial surfaces. Formation surface (FS), mineral apposition rate (MAR) and bone formation rate (BFR) were calculated. At lateral surface of periosteal surface, all three parameters showed significant differences between the loaded and nonloaded tibiae. All these parameters were significantly lower in CIA groups than in CONT groups, and interaction was seen between applied loading and CIA. There was a significant correlation between peak strain and the right-left difference of FS in the CONT groups. At medial surface of periosteal surface, there were force-related increase in FS, MAR, and BFR on the loaded side in both CIA and CONT groups, except MAR in the CONT group. All three parameters showed significant differences between the loaded and nonloaded tibiae. At endocortical surface, force-related increase was observed only in FS on the loaded side in CONT groups, and FS was significantly higher on the loaded side than the nonloaded side. CIA lowered all three parameters significantly. We examined the response to mechanical loading on the tibia in untreated CONT rats and rats with CIA by bone histomorphometry, and found that arthritis suppressed bone formation induced by mechanical loading.     

Mechanical loading enhances the anabolic effects of intermittent parathyroid hormone (1-34) on trabecular and cortical bone in mice

The separate and combined effects of intermittent parathyroid hormone (iPTH) (1-34) and mechanical loading were assessed at trabecular and cortical sites of mouse long bones. Female C57BL/6 mice from 13 to 19 weeks of age were given daily injections of vehicle or PTH (1-34) at low (20 microg/kg/day), medium (40 microg/kg/day) or high (80 microg/kg/day) dose. For three alternate days per week during the last two weeks of this treatment, the tibiae and ulnae on one side were subjected to a single period of non-invasive, dynamic axial loading (40 cycles at 10 Hz with 10-second intervals between each cycle). Two levels of peak load were used; one sufficient to engender an osteogenic response, and the other insufficient to do so. The whole tibiae and ulnae were analyzed post-mortem by micro-computed tomography with a resolution of 5 microm. Treatment with iPTH (1-34) modified bone structure in a dose- and time-dependent manner, which was particularly evident in the trabecular region of the proximal tibia. In the tibia, loading at a level sufficient by itself to stimulate osteogenesis produced an osteogenic response in the low-dose iPTH (1-34)-treated trabecular bone and in the proximal and middle cortical bone treated with all doses of iPTH (1-34). In the ulna, loading at a level that did not by itself stimulate osteogenesis was osteogenic at the distal site when combined with high-dose iPTH (1-34). At both levels of loading, there were synergistic effects in cortical bone volume of the proximal tibia and distal ulna between loading and high-dose iPTH (1-34). Images of fluorescently labelled bones confirmed that such synergism resulted from increases in both endosteal and periosteal bone formation. No woven bone was induced by iPTH (1-34) or either level of loading alone, whereas the combination of iPTH (1-34) and the "sufficient" level of loading stimulated woven bone formation on endosteal and periosteal surfaces of the proximal cortex in the tibiae. Together, these data suggest that in female C57BL/6 mice, under some but not all circumstances, mechanical loading exerts an osteogenic response with iPTH (1-34) in trabecular and cortical bone.     

Validation of a technique for studying functional adaptation of the mouse ulna in response to mechanical loading

Functional adaptation of the mouse ulna in response to artificial loading in vivo was assessed using a technique previously developed in the rat. Strain gauge recordings from the mouse ulnar midshaft during locomotion showed peak strains of 1680 muepsilon and maximum strain rates of 0.03 sec(-1). During falls from 20 cm these reached 2620 muepsilon and 0.10 sec(-1). Axial loads of 3.0 N and 4.3 N, applied through the olecranon and flexed carpus, engendered peak strains at the lateral ulnar midshaft of 2000 muepsilon and 3000 muepsilon, respectively. The left ulnae of 17, 17-week-old female CD1 mice were loaded for 10 min with a 4 Hz trapezoidal wave engendering a strain rate of 0.1 sec(-1) for 5 days/week for 2 weeks. The mice were killed 3 days later. The response of the cortical bone of the diaphysis was assessed histomorphometrically using double calcein labels administered on days 3 and 12 of the loading period. Loading to peak strains of 2000 muepsilon stimulated lamellar periosteal bone formation, but no response endosteally. The greatest increase in cortical bone area was 4 mm distal to the midshaft (5 +/- 0.4% compared with 0.1 +/- 0.1% in controls [p < 0.01]). Periosteal bone formation rate (BFR) at this site was 0.73 +/- 0.06 microm(2)/microm per day, compared with 0.03 +/- 0.02 microm(2)/microm per day in controls (p < 0.01). Loading to peak strains of 3000 muepsilon induced a mixed woven/lamellar periosteal response and lamellar endosteal bone formation. Both of these were greatest 3-4 mm distal to the ulnar midshaft. At this level, the loading-induced periosteal response increased cortical bone area by 21 +/- 4% compared with 0.03 +/- 0.02% in controls, and resulted in a BFR of 2.84 +/- 0.42 microm(2)/microm per day, compared with 0.01 +/- 0.01 microm(2)/microm per day in controls (p < 0.05). Endosteal new bone formation resulted in a 2 +/- 0.4% increase in cortical bone area, compared with 0.4 +/- 0.3% in controls, and a BFR of 1.05 +/- 0.23 microm(2)/microm per day, compared with 0.22 +/- 0.15 microm(2)/microm per day in controls (p < 0.05). These data show that the axial ulna loading technique developed in the rat can be used successfully in the mouse. As in the rat, a short daily period of loading results in an osteogenic response related to peak strain magnitude. One important advantage in using mice over rats involves the potential for assessing the effects of loading in transgenics.     

Bone morphogenetic protein-7 selectively enhances mechanically induced bone formation

The responses of bone cells to skeletal loading are clearly an important factor in bone biology, but much remains to be learned about the role of these responses in skeletal development, maintenance, and tissue repair. Bone morphogenetic proteins (BMPs) are key regulators of bone formation. We examined the effect of BMP-7 on periosteal and endosteal bone formation in response to increased mechanical loading using the rat tibial bending model. Female Sprague-Dawley rats were divided into four groups of six rats each. Three groups received four point bending loading at 60 N force; the fourth group received sham loading at the same force. The right tibia received 36 cycles of loading on Monday, Wednesday, and Friday for 2 weeks; the left tibia served as a nonloaded control. Just prior to loading, the three loaded groups were injected intraperitoneally with vehicle only or 10 microg/kg or 100 microg/kg of recombinant human BMP-7. Half the sham group received vehicle, and half were given 100 microg/kg of BMP-7. Bone forming surfaces were labeled twice in vivo with calcein, and histomorphometry was performed to quantify periosteal and endosteal bone formation in the loaded and control tibiae. BMP-7 had no effect on periosteal or endosteal bone formation in control or sham-loaded tibiae. Loading produced significantly more woven bone on the periosteal surface than sham loading, but BMP-7 treatment had no effect on this response. Endosteal bone formation was entirely lamellar, and loading (but not sham loading) increased the endosteal mineral apposition and bone formation rates. The higher BMP-7 dose more than doubled the load-induced increase in endosteal lamellar bone formation rate, primarily by increasing the amount of bone forming surface.     

A systemic acceleratory phenomenon (SAP) accompanies the regional acceleratory phenomenon (RAP) during healing of a bone defect in the rat

The rate of remodeling in the region of a bone defect exceeds normal tissue activity. It was Frost who described this reaction as a regional acceleratory phenomenon (RAP). We investigated the local healing process with rats with a burr hole defect (1.2 mm in diameter) in the left tibia. We differentiated an initial phase of bone formation followed by a phase of predominant resorption. To determine whether this regional enhancement of bone formation would result in a systemic impact on bone metabolism, we analyzed both tibiae and femora and the fourth lumbar vertebra. On day 7 both femora of rats with the tibial defect showed a significant increase in computerized x-ray density, dry weight, ash weight, and Ca2+ content. Both tibiae and the fourth lumbar vertebra showed a significant increase in mineralizing surface, mineral apposition rate, and bone formation rate. Because of these results we conclude that a systemic acceleratory phenomenon (SAP) accompanies the RAP. SAP affects only the cancellous, but not the cortical bone compartment. SAP is associated closely with the occurrence of woven bone during the formation phase of the healing process. Thus we assume that woven bone formation plays a pivotal role in the mediation of SAP.     

Effect of weight-bearing on healing of cortical defects in the canine tibia

It has been generally accepted that mechanical stimulation is an important factor in the promotion of formation of bone. Fracture-healing consists of periosteal bridging of the fracture, which achieves stability, and proliferation of endosteal bone to fill the defects between the ends of the bone. To evaluate the effect of weight-bearing on bone-healing, an operatively created defect in the tibial cortex was chosen as an experimental model. In one set of dogs (Group 1), a bilateral defect in the tibial cortex was created and weight-bearing was permitted on one tibia but not on the opposite one. In Group 2, a bilateral defect in the tibial cortex was made and weight-bearing was allowed on both tibiae. A third group of dogs of similar age (Group 3) had no tibial defects. Quantitative histomorphometry was used to measure formation and porosity of bone. Weight-bearing was measured with both static and dynamic techniques. Significantly less woven bone formed in the defects in the non-weight-bearing tibiae than in the weight-bearing tibiae. This appeared to be due to a disuse response in the underloaded tibiae, in which less bone formed, rather than to the formation of more bone in the weight-bearing tibiae. The data suggest that weight-bearing is a permissive factor, not a stimulus, for formation of woven bone in a tibial defect. Clinical Relevance: This animal model supports the concept that lack of weight-bearing decreases the amount of woven bone that is formed in a healing tibial defect. The results of this study indicate that weight-bearing increases the formation of bone in fracture-healing.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intraosseous infusion of prostaglandin E2 prevents disuse-induced bone loss in the tibia

We investigated whether intraosseous injection of prostaglandin E₂ would preserve tibial bone mass in the skeletally unloaded limb of a large animal model. Skeletal unloading of one rear limb was produced by unilateral Achilles tenectomy in the goat. Prostaglandin E₂ was injected at 0.5 or 1.0 mg (1 ml of volume) twice daily, beginning on day 7 and continuing for 10 days, through an implant that had been surgically placed in the proximal tibial metaphysis. Thirty-five days after surgery, the tibiae were harvested for measurement of static and dynamic bone parameters and mechanical characteristics using transmission ultrasound. Prostaglandin E₂ produced a dose-dependent increase in the formation of woven new bone at all bone envelopes. The 1.0 mg dosage prevented and partially reversed the effects of skeletal unloading and added new bone (p < 0.05) compared with the unloaded tibiae. Because prostaglandin E₂ increased both bone formation and resorption and the new bone produced was primarily woven bone, the material properties of the tibiae infused with prostaglandin E₂ did not increase significantly during the study compared with the unloaded and weight-bearing tibiae.     

Effect of exercise on tibial and lumbar vertebral bone mass in mature osteopenic rats: Bone histomorphometry study

The effect of moderate running exercise on tibial and lumbar vertebral bone mass was examined in mature osteopenic rats by bone histomorphometry. Ten 37-week-old female Wistar rats, with bone loss resulting from being fed a relatively low-calcium diet for 14 weeks after ovariectomy at the age of 23 weeks, were randomly divided into two groups of five animals each; control and exercise groups. The exercise consisted of treadmill running at 12 m/min for 1 h per day on 5 days per week for 12 weeks. During the exercise period, all animals were fed a standard calcium diet. After 12 weeks of exercise, bone histomorphometry was evaluated for cancellous bone (secondary spongiosa) of the proximal tibia and the fourth lumbar vertebra and for cortical bone of the tibial shaft. The findings suggested that in the mature osteopenic rat, there was a beneficial effect of moderate running exercise with adequate calcium intake on bone mass only in a weight-bearing long bone, the tibia. The mechanism for increased bone mass appeared to be both decreased bone resorption and increased bone formation in cancellous bone and increased bone formation in cortical bone. Received for publication on Dec. 18, 1997; accepted on April 2, 1998     

In vivo fatigue loading of the rat ulna induces both bone formation and resorption and leads to time-related changes in bone mechanical properties and density.

Fatigue loading triggers bone resorption and is associated with stress fractures. Neither the osteogenic response nor the changes in bone mechanical properties following in vivo fatigue loading have been quantified. To further characterize the skeletal response to fatigue loading, we assessed bone formation, mechanical properties, density and resorption in the ulnae of 72 adult rats subjected to a single bout of in vivo loading followed by 0, 6, 12 or 18 days of recovery. Axial, compressive loading (peak force 13.3 N, 2 Hz) was applied to the right forelimb until the ulna was fatigued to a pre-determined level. The left forelimb served as a contralateral control. The primary osteogenic response to fatigue loading was woven bone formation that occurred on the periosteal surface of the ulnar diaphysis and was significantly greater in loaded limbs versus controls at 6, 12 and 18 days (p <.0.05). Ultimate force of the ulna in three-point bending decreased by 50% and stiffness decreased by 70% on day 0 (p < 0.01 vs. control), indicative of acute fatigue damage. By day 12, ultimate force and stiffness had returned to control levels (p > 0.05) and by day 18 had increased 20% beyond controls (p < 0.01). Bone cross-sectional area, moment of inertia, and mineral content increased with recovery time (p < 0.01), consistent with the increases in woven bone formation and mechanical properties. Intracortical resorption space density and osteoclast density also increased with recovery time (p < 0.05), indicating activation of intracortical remodeling. In summary, our findings demonstrate the remarkable ability of the adult skeleton to rapidly form periosteal woven bone and thereby offset the negative structural effects of acute fatigue damage and subsequent intracortical resorption.     

Pressure-induced periprosthetic osteolysis: a rat model.

Recent animal experiments have indicated that oscillating fluid pressure at the interface of bone and implant can lead to osteolysis. However, external nonphysiologic saline solutions were used to generate the pressure in these studies. In the present study on 15 Sprague-Dawley rats, hydrostatic pressure fluctuations were applied to bone through body fluids, by compressing a soft-tissue membrane adjacent to the proximal tibia. A titanium plate was fixed to the bone surface. After 28 days of osseointegration of the plate, a 1-mm-wide gap was created between it and the cortical bone and 5 days were given for fibrous tissue to form. Load was transmitted to this soft tissue by applying force on a piston mounted in the plate. In six rats, a cyclic pressure of 0.6 MPa was then applied to this tissue by 20 cycles twice a day with a frequency of 0.17 Hz for 5 days. The remaining rats served as controls, with the piston left untouched in its upper position. All of the rats were killed 10 days after creation of the gap. Histological sections were produced at a right angle to the loaded surface. In the pressurized specimens, osteoclastic bone resorption was dramatic. In all specimens, the original cortex was almost entirely resorbed but new woven bone had formed deeper in the marrow and walled off a cystic lesion. When necrotic remnants of the cortex were still in place, new woven bone was seen on the side away from the piston. This "lee effect" may indicate that bone formation was inhibited by fluid flow away from the pressurized tissue. The specimens with a nonloaded piston showed no signs of resorption. This new experimental model shows again that a moderate rise of hydrostatic pressure at the interface of bone and implant leads to considerable bone resorption. This could be a mechanism of prosthetic loosening.