Effect of denosumab on bone mineral density and biochemical markers of bone turnover: 8-year results of a phase 2 clinical trial.

UNLABELLED: In a phase 2 study, continued denosumab treatment for up to 8 years was associated with continued gains in bone mineral density and persistent reductions in bone turnover markers. Denosumab treatment was well tolerated throughout the 8-year study. INTRODUCTION: The purpose of this study is to present the effects of 8 years of continued denosumab treatment on bone mineral density (BMD) and bone turnover markers (BTM) from a phase 2 study. METHODS: In the 4-year parent study, postmenopausal women with low BMD were randomized to receive placebo, alendronate, or denosumab. After 2 years, subjects were reallocated to continue, discontinue, or discontinue and reinitiate denosumab; discontinue alendronate; or maintain placebo for two more years. The parent study was then extended for 4 years where all subjects received denosumab. RESULTS: Of the 262 subjects who completed the parent study, 200 enrolled in the extension, and of these, 138 completed the extension. For the subjects who received 8 years of continued denosumab treatment, BMD at the lumbar spine (N = 88) and total hip (N = 87) increased by 16.5 and 6.8 %, respectively, compared with their parent study baseline, and by 5.7 and 1.8 %, respectively, compared with their extension study baseline. For the 12 subjects in the original placebo group, 4 years of denosumab resulted in BMD gains comparable with those observed during the 4 years of denosumab in the parent study. Reductions in BTM were sustained over the course of continued denosumab treatment. Reductions also were observed when the placebo group transitioned to denosumab. Adverse event profile was consistent with previous reports and an aging cohort. CONCLUSION: Continued denosumab treatment for 8 years was associated with progressive gains in BMD, persistent reductions in BTM, and was well tolerated.

Oxidative stress and brain aging: is zinc the link?

Zn(2+) dyshomeostasis has been strongly linked to neuronal injury in many neurological conditions. Toxic accumulation of intracellular free Zn(2+) ([Zn(2+)](i)) may result from either flux of the cation through glutamate receptor-associated channels, voltage-sensitive calcium channels, or Zn(2+)-sensitive membrane transporters. Injurious [Zn(2+)](i) rises can also result from release of the cation from intracellular sites such as metallothioneins (MTs) and mitochondria. Chronic inflammation and oxidative stress are hallmarks of aging. Zn(2+) homeostasis is affected by oxidative stress, which is a potent trigger for detrimental Zn(2+) release from MTs. Interestingly, Zn(2+) itself is a strong inducer of oxidative stress by promoting mitochondrial and extra-mitochondrial production of reactive oxygen species. In this review, we examine how Zn(2+) dyshomeostasis and oxidative stress might act synergistically to promote aging-related neurodegeneration.