Effects of teriparatide on cortical histomorphometric variables in postmenopausal women with or without prior alendronate treatment.

Cortical bone, the dominant component of the human skeleton by volume, plays a key role in protecting bones from fracture. We analyzed the cortical bone effects of teriparatide treatment in postmenopausal women with osteoporosis who had previously received long-term alendronate (ALN) therapy or were treatment naïve (TN). Tetracycline-labeled paired iliac crest biopsies obtained from 29 ALN-pretreated and 16 TN women were evaluated for dynamic histomorphometric parameters of bone formation at the periosteal, endocortical and intracortical bone compartments, before and after 24months of teriparatide treatment. At baseline, the frequency of specimens without any endocortical and periosteal tetracycline labeling, and the percentage of quiescent osteons, was higher in the ALN than the TN group. Endocortical and periosteal mineralizing surface (MS/BS%), periosteal bone formation rate (BFR/BS), mineral apposition rate (MAR) and the number of intracortical forming osteons were significantly lower in the ALN-pretreated patients than in the TN group. Following teriparatide treatment, the frequency of endocortical and periosteal unlabeled biopsies decreased; in the ALN-pretreated group the percentage of quiescent osteons decreased and, in contrast, forming and resorbing osteons were increased. Teriparatide treatment resulted in significant increases of MAR in the endocortical, and MS/BS% in the periosteal compartment in the ALN-pretreated group. Most indices of bone formation remained lower in the ALN-pretreated group compared with the TN group at study end. Endocortical wall width was increased in both ALN-pretreated and TN groups. Cortical porosity and cortical thickness were significantly increased in the ALN-pretreated group after teriparatide treatment. Our results suggest that 24months of teriparatide treatment increases cortical bone formation and cortical turnover in patients who were either TN or had previous ALN therapy.

The effect of timing of teriparatide treatment on the circadian rhythm of bone turnover in postmenopausal osteoporosis.

BACKGROUND: We hypothesized that with the administration of teriparatide (TPTD) treatment at different times, we would be able to modify the physiological circadian rhythm of bone turnover. METHODS: The concentration of serum C-terminal telopeptide of collagen type I (ßCTX), serum N-terminal propeptide of procollagen type I (P1NP), serum ionized calcium (iCa), and plasma PTH were measured every 3 h over a 24 h period in 14 postmenopausal osteoporotic women (aged 72.4±9.3 years) treated with 20 µg TPTD for long term, given at different times of the day. General linear model-repeated measurements (GLM RM) were performed to analyze the circadian rhythms as well as intergroup comparisons. RESULTS: GLM-RM for both related groups showed a significant influence of time of day on all measured variables except P1NP. The analysis for each group separately provided a powerful model for ßCTX (P<0.001, η(2)=0.496), serum iCa (P<0.001, η(2)=0.423), plasma PTH (P<0.001, η(2)=0.283), and serum PINP (P<0.001, η(2)=0.248). While the evening TPTD treatment showed a marked circadian rhythm for serum ßCTX, the morning TPTD treatment rather suggested circasemidian rhythm. The P1NP rhythm followed a much smaller amplitude of the rhythm than ßCTX. Changes in serum iCa were positively related to changes in serum ßCTX (P<0.001) and negatively related to changes in PTH (P<0.001). CONCLUSION: Timing of TPTD administration may significantly change the 24 h variation in bone turnover markers as well as calcium-parathyroid axis in postmenopausal osteoporotic women.

Teriparatide reduces bone microdamage accumulation in postmenopausal women previously treated with alendronate.

Suppression of bone turnover by bisphosphonates is associated with increased bone microdamage accumulation in animal models. Our objective was to study the effects of teriparatide treatment on changes in microdamage accumulation at the iliac crest in previously treatment-naïve patients or in those switched from alendronate to teriparatide. Sixty-six postmenopausal women with osteoporosis (mean age, 68.0 yr; and mean BMD T-score of -2.8 at lumbar spine and -1.7 at total hip; 62% with prevalent fractures) entered this prospective, nonrandomized study and started with 24-mo 20 microg/d subcutaneous teriparatide treatment in monotherapy: 38 patients stopped previous alendronate treatment (10 mg/d or 70 mg/wk for a mean duration of 63.6 mo) and switched to teriparatide, whereas 28 were previously treatment naïve. Thirty-one paired biopsies with two intact cortices were collected and analyzed for microstructure and microdamage accumulation at baseline and after 24 mo of teriparatide administration. After 24 mo of teriparatide treatment, crack density (Cr.Dn), crack surface density (Cr.S.Dn), and crack length (Cr.Le) were decreased in previously alendronate-treated patients, whereas only Cr.Le was reduced in former treatment-naïve patients. Patients with lower initial femoral neck BMD also showed a higher reduction of microdamage accumulation. Better bone microarchitecture correlated positively, whereas bone turnover markers and age did not correlate with reduced microdamage accumulation on teriparatide. In conclusion, teriparatide reduces microdamage accumulation in the iliac crest of patients previously treated with alendronate. There is insufficient evidence to suggest that age or bone turnover would be associated with this change.

Low bone mineral density is associated with bone microdamage accumulation in postmenopausal women with osteoporosis.

Marked suppression of bone turnover by bisphosphonates is associated with increased bone microdamage accumulation in animal models. The purpose of this study was to test the hypothesis that long-term treatment with alendronate (ALN) results in accumulation of microdamage in bone in women after menopause. Sixty-six postmenopausal women with osteoporosis (mean age of 68.0 years and mean BMD T-score of -1.7 at total hip and -2.8 at lumbar spine; 62% with prevalent fractures) were evaluated in this cross-sectional analysis. Thirty-eight had been treated previously with ALN (10 mg/day or 70 mg/week for a mean duration of 63.6 months) while twenty-eight were treatment naive (TN). Without adjustments, crack surface density (Cr.S.Dn) and crack density (Cr.Dn) were not different between ALN and TN patients. After adjustment for potential confounders (age, prevalent fractures, femoral neck BMD, activation frequency and center), Cr.Dn was elevated in ALN patients (P=0.028 and P=0.069 for Cr.S.Dn). In ALN patients only, lower femoral neck BMD (Cr.S.Dn, r=-0.58, P=0.003; Cr.Dn, r=-0.54, P=0.005) and increased age (Cr.S.Dn, r=0.43, P=0.03; Cr.Dn, r=0.43, P=0.03) were associated with microdamage accumulation. Among potential confounders, femoral neck BMD was the only independent predictor for these correlations (P=0.04 for Cr.Dn and P=0.03 for Cr.S.Dn). We conclude that increased microdamage accumulation may occur in low BMD patients treated with alendronate.

The effect of raloxifene after discontinuation of long-term alendronate treatment of postmenopausal osteoporosis.

OBJECTIVE: The aim of this study was to compare bone mineral density (BMD) and biochemical markers of bone turnover in patients receiving long-term alendronate therapy who continued alendronate, were switched to raloxifene, or discontinued antiresorptive therapy. DESIGN, PATIENTS, AND INTERVENTIONS: Ninety-nine ambulatory women who were diagnosed with postmenopausal osteoporosis and treated with alendronate (10 mg/d) for a mean period of 43 months were randomized to double-blind raloxifene (60 mg/d; n = 33), placebo (n = 33), or continuation of open-label alendronate (n = 33) for 12 months. Patients continued their assigned treatment in a subsequent 12-month, open-label extension phase. All patients received supplemental calcium (500 mg/d) and vitamin D (800 IU/d). MAIN OUTCOME MEASURES: BMD (lumbar spine, total femur, femoral neck, distal forearm, and total body) and biochemical markers (serum intact amino-terminal propeptide of type I procollagen, type 1 collagen cross-linked C-telopeptide, and osteocalcin) were measured at baseline and follow-up visits. RESULTS: Discontinuation of alendronate therapy resulted in a decrease in lumbar spine BMD at 12 months (-2.66%; P < 0.05), but did not change total femur BMD (+0.35%; nonsignificant). Raloxifene and alendronate, compared with discontinuation, prevented lumbar spine BMD loss (-0.75% and -0.54% at 12 months, respectively; P < 0.05). Raloxifene and alendronate caused a similar increase in total femur BMD at 12 months (1.45% and 1.56%; both P < 0.05 vs. baseline; nonsignificant vs. discontinuation). Patients, who discontinued alendronate therapy experienced an increase in bone turnover. Bone turnover increases were less pronounced in patients taking raloxifene and were absent in those who continued alendronate. Of the three groups, mean bone turnover in raloxifene patients was the closest to premenopausal mean values. CONCLUSIONS: BMD preservation and increase were most pronounced in patients continuing alendronate. Raloxifene treatment, compared with placebo, demonstrated beneficial effects on BMD and bone turnover after discontinuation of long-term alendronate therapy.