OVX monkeys treated for 18 months with 1 or 5 g/kg/d teriparatide [PTH (1-34)] had significantly stronger proximal femora relative to ovariectomized controls. Teriparatide enhancement of cortical area, cortical width, and trabecular bone volume seemed to more than compensate for the dosedependent increase in cortical porosity. Beneficial effects of teriparatide treatment on the proximal femur persisted beyond the treatment period and may extend to the marrow. Introduction:We conducted a detailed quantitative analysis of the effects of teriparatide on the proximal femur of ovariectomized monkeys. Teriparatide increased bone mass, enhanced structural architecture, and strengthened the hip, despite increasing cortical porosity. Materials and Methods: Monkeys were treated with vehicle (sham or OVX controls), 1 g/kg/day teriparatide [parathyroid hormone (1-34); PTH1], or 5 g/kg/day teriparatide (PTH5) for 18 months or for 12 months followed by 6 months of treatment withdrawal (PTH1W and PTH5W, respectively). Excised proximal femora were analyzed by CT, conventional histomorphometry, and biomechanics. Results and Conclusions:The femoral neck showed significant reduction in trabecular bone volume (BV/TV) for OVX compared with sham, whereas PTH1 BV/TV was restored to sham levels and PTH5 BV/TV was greater than sham and OVX. The withdrawal groups had BV/TVs intermediate between sham and OVX. PTH1 had trabecular number (Tb.N) greater than OVX, and PTH5 Tb.N was greater than sham and OVX. The withdrawal groups had Tb.Ns intermediate between sham and OVX. No differences between groups were observed for trabecular orientation or trabecular thickness. Teriparatide dose-dependently increased bone formation rate and activation frequency in the femoral neck. Cellular composition analyses suggested a tendency of ovariectomy to increase adiposity of marrow by 100%, whereas PTH tended to reduce adipocyte number and increase osteoblast number compared with OVX. Analyses of the cortex showed dose-dependent elevation of cortical porosity, which was consistent with enhanced bone turnover with treatment. Cortical porosity was reduced after withdrawal of teriparatide, because PTH1W cortical porosity was lower than OVX, whereas PTH5W cortical porosity was intermediate between sham and OVX. Increased cortical porosity did not weaken the proximal femora. Biomechanics showed that ovariectomy weakened proximal femora compared with sham, but PTH1, PTH5, and PTH1W were stronger than OVX and not different from sham. PTH5W strength was intermediate between sham and OVX. Therefore, teriparatide had beneficial effects on the proximal femur, despite increasing cortical porosity. Cortical porosity did not adversely affect the mechanical integrity of the proximal femora, because enhanced cortical area and trabecular bone volume more than compensated for the porosity. Much of the beneficial effects of teriparatide were retained after 6 months withdrawal from treatment. PTH effects on the femoral neck were not limited to bone but may include i...
With the ready availability of several osteoporosis therapies, teriparatide [human PTH-(1-34)] is likely to be prescribed to postmenopausal women with prior exposure to agents that prevent bone loss, such as bisphosphonates, estrogen, or selective estrogen receptor modulators. Therefore, we evaluated the ability of once daily teriparatide to induce bone formation in ovariectomized (Ovx) rats with extended prior exposure to various antiresorptive agents, such as alendronate (ABP), 17 alpha-ethinyl estradiol (EE), or raloxifene (Ral). Sprague Dawley rats were Ovx and treated with ABP (28 microg/kg, twice weekly), EE (0.1 mg/kg per d), or Ral (1 mg/kg per d) for 10 months before switching to teriparatide 30 microg/kg per d for another 2 months. Analysis of the proximal tibial metaphysis showed that all three antiresorptive agents prevented ovariectomy-induced bone loss after 10 months, but were mechanistically distinct, as shown by histomorphometry. Before teriparatide treatment, ABP strongly suppressed activation frequency and bone formation rate to below levels in other treatment groups, whereas these parameters were not different from sham values for EE or Ral. Trabecular area for ABP, EE, and Ral were greater than that in Ovx controls. However, the trabecular bone effects of ABP were attributed not only to effects on the secondary spongiosa, but also to the preservation of primary spongiosa, which was prevented from remodeling. After 2 months of teriparatide treatment, lumbar vertebra showed relative bone mineral density increases of 18%, 7%, 11%, and 10% for vehicle/teriparatide, ABP/teriparatide, EE/teriparatide, and Ral/teriparatide, respectively, compared with 10 month levels. Histomorphometry showed that trabecular area was increased by 105%, 113%, 36%, and 48% for vehicle/teriparatide, ABP/teriparatide, EE/teriparatide, and Ral/teriparatide, respectively, compared with 10 month levels. Teriparatide enhanced mineralizing surface, mineral apposition rate, and bone formation rate in all groups. Compression testing of vertebra showed that teriparatide improved strength (peak load) and toughness in all groups to a proportionately similar extent compared with 10 month levels. These data showed a surprising ability of the rat skeleton to respond to teriparatide despite extensive pretreatment with ABP, EE, or Ral. Therefore, the mature skeleton of Ovx rats remains highly responsive to the appositional effects of teriparatide regardless of pretreatment status in terms of cancellous bone area or rate of bone turnover.
Skeletal effects are described for near-lifetime treatment of young, female rats with recombinant human PTH (1-34) (PTH). Rats (5-8 wk of age) were administered 0, 5, 30, or 75 microg/kg x d sc PTH for up to 2 yr, as part of an oncogenicity evaluation, which is required by regulatory agencies for potential chronic therapies. Proliferative lesions were observed in the skeleton as described in Vahle et al. (1 ); in this paper, we describe the quantitative bone data for this study. In the appendicular skeleton, PTH stimulated trabecular and endocortical mineral apposition to the near exclusion of marrow spaces at 5 microg/kg, with some periosteal apposition at 30 microg/kg, followed by considerable periosteal apposition and altered geometry at 75 microg/kg. Increased bone mass was observed for all treatment groups that substantially exceeded normal levels attained by vehicle controls and exceeded skeletal efficacy reported previously for similar doses in shorter-term studies. Dose-dependent increases in osteocalcin levels and a linear increase in wet weight of femora were observed for the entire treatment duration, suggesting nearly continuous PTH stimulation of osteoblasts and skeletal growth throughout life. Histology showed many osteocytes and prominent osteoblasts, but a conspicuous absence of osteoclasts. Morphometry showed a lack of distinction between trabecular and cortical bone. Biomechanics of vehicle controls showed that optimal mechanical integrity for the normal skeleton is observed at about 11 months of age. PTH greatly strengthened and stiffened vertebra and femora; however, the midshaft showed reduced toughness and increased brittleness with treatment, which was not the case for vertebra. Related studies of 6 and 9 months duration showed that the optimal duration for PTH skeletal efficacy was about 6 months in rats, based on toughness, strength, ultimate displacement, and architecture, especially for cortical bone. Therefore, treatment duration is an under appreciated aspect of PTH pharmacology; and PTH skeletal effects are a complex function of dose and duration. Comparative analyses showed that short-term treatment (6 months or less) is more advantageous than near-lifetime treatment, because PTH stimulates skeletal growth throughout life, resulting in abnormal architecture and untoward biomechanical properties in rats.
ABSTRACT:In rats, teriparatide ] causes marked increases in bone mass and osteosarcoma. In primates, teriparatide causes lesser increases in bone mass, and osteosarcomas have not been reported. Previous studies in primates were not designed to detect bone tumors and did not include a prolonged post-treatment observation period to determine whether tumors would arise after cessation of treatment. Ovariectomized (OVX), skeletally mature, cynomolgus monkeys (n ס 30 per group) were given teriparatide for 18 mo at either 0 or 5 g/kg/d subcutaneously. After 18 mo of treatment, subgroups of six monkeys from both groups were killed and evaluated, whereas all remaining monkeys entered a 3-yr observation period in which they did not receive teriparatide. Surveillance for bone tumors was accomplished with plain film radiographs, visual examination of the skeleton at necropsy, and histologic evaluation of multiple skeletal sites. Quantitative assessments of bone mass, architecture, and strength were also performed. After the 18-mo treatment period, vertebral BMD, BMC, and strength (ultimate load) were increased by 29%, 36%, and 52%, respectively, compared with OVX controls. Proximal femur BMD, BMC, and strength were also increased by 15%, 28% and 33%, respectively. After 3 yr without treatment, no differences in bone mass or strength at the vertebra were observed relative to OVX controls; however, the femoral neck showed significant persistence in stiffness (20%), BMC (14%), and trabecular BV/TV (53%), indicating a retention of teriparatide efficacy at the hip. Radiographs and histology did not identify any bone proliferative lesions or microscopic lesions of osteosarcoma at the end of the treatment or observation period. These data indicate that teriparatide did not induce bone proliferative lesions over a 4.5-yr interval of observation, including 18 mo of treatment and 3 yr of follow-up observation. Bone analyses confirmed that teriparatide caused increases in bone mass and strength, consistent with previous studies. During the withdrawal phase, beneficial effects of teriparatide treatment on the vertebra were lost; however, some of the beneficial effects on the proximal femur persisted for 3 yr after cessation of treatment. Although the lack of bone tumors in this study provides some additional reassurance regarding the safety of teriparatide for the primate skeleton, the small group size and other limitations of this, or any other animal study, limit the ability to draw definitive conclusions regarding the risk of bone tumor developments in patients.
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