Results 231 to 240 of about 3,036,943 (405)

Assessment of the risk of low bone mineral density in premenopausal Japanese female patients with systemic lupus erythematosus

, 2018
Yu Mori, Kazuyoshi Baba, Atsushi Kogure, Takuya Izumiyama, M Matsuda, Naoko Mori, Tomonori Ishii, Eiji Itoi   +7 more
openalex   +2 more sources

Vitamin K Supplement Along with Vitamin D and Calcium Reduced Serum Concentration of Undercarboxylated Osteocalcin While Increasing Bone Mineral Density in Korean Postmenopausal Women over Sixty-Years-Old [PDF]

, 2011
Sang H. Je, Nam‐Seok Joo, Beom Hee Choi, Kwang‐Min Kim, Bom-Taeck Kim, Sat-Byul Park, Doo‐Yeoun Cho, Kyu-Nam Kim, Duck‐Joo Lee   +8 more
openalex   +1 more source

Denosumab in postmenopausal women with low bone mineral density.

New England Journal of Medicine, 2006
William D Rifkin
semanticscholar   +1 more source

CircTspan3 Promotes Cartilage Development Through ANNEXIN A2‐Mediated Ferroptosis and Apoptosis Inhibition and Exosome‐Mediated Paracrine Signaling

Advanced Science, EarlyView.
This study reveals that XBP1s drives production of circTspan3, a circular RNA that strengthens cartilage by boosting anabolic activity and limiting cell death. Phosphorylated ANXA2 directs circTspan3 into exosomes, enabling paracrine repair. Exosomal circTspan3 expands growth‐plate cartilage and promotes in vivo regeneration, highlighting its promise ...
Yiming Pan, Fengmei Zhang, Jiayan Zhong, Qian Gong, Nana Geng, Biao Kuang, Qiumei Lan, Miao Yi, Qiqi Zeng, Cheng Chen, Mengtian Fan, Chunliang Zhao, Deping Zeng, Yu Du, Mao Nie, Zhibiao Wang, Fengjin Guo   +16 more
wiley   +1 more source

Glyphosate exposure, bone mineral density, osteoporosis, and fractures in the United States population. [PDF]

J Environ Health Sci Eng
Khalil N, Hamdaoui L, Ducatman A, Koskela A, Rebai T, Lee M, Nahhas RW.   +6 more
europepmc   +1 more source

Relationship between the fat and lean body mass with lumbar spine bone mineral density in postmenopausal women [PDF]

, 2011
Maryam Shabani, M Ramazanpoor, Samira Moghimi   +2 more
openalex   +1 more source

Ionic–Bionic Interfaces: Advancing Iontronic Strategies for Bioelectronic Sensing and Therapy

Advanced Science, EarlyView.
Ionic–bionic interfaces for bioelectronics leverage ions as multifunctional mediators that combine mechanical compliance, ionic and electronic functionalities, and therapeutic effects. These systems offer real‐time biosignal transduction, effective wound dressing, responsive drug delivery, and seamless interaction between soft tissues and electronic ...
Yun Goo Ro, Yoojin Chang, Jeeyoon Kim, Seungjae Lee, Sangyun Na, Cheolhong Park, Hyunhyub Ko   +6 more
wiley   +1 more source

Correction: The effect of tennis on male bone mineral density: A meta-analysis. [PDF]

PLoS One
Huiwen H, Jun H, Dong F, Yan F, Tao W.
europepmc   +1 more source

Atypical subtrochanteric and diaphyseal femoral fractures: Report of a task force of the american society for bone and mineral Research

Journal of Bone and Mineral Research, 2010
E. Shane, D. Burr, P. Ebeling, B. Abrahamsen, R. Adler, T. Brown, A. Cheung, F. Cosman, J. Curtis, R. Dell, D. Dempster, T. Einhorn, H. Genant, P. Geusens, K. Klaushofer, K. Koval, J. Lane, F. McKiernan, Ross E. McKinney, A. Ng, J. Nieves, R. O’Keefe, S. Papapoulos, H. T. Sen, Marjolein CH van der Meulen, R. Weinstein, M. Whyte   +26 more
semanticscholar   +1 more source

Synovial Fluid‐derived Micrococcus Luteus G18 Exacerbates Osteoarthritis Progression by Promoting Chondrocyte Degradation via TLR2/JNK/AP‐1 Signaling Pathway

Advanced Science, EarlyView.
Traditionally considered sterile, the articular cavity is now recognized to harbor microbial communities influencing osteoarthritis (OA). Integrating 16S rRNA sequencing and culturomics, Micrococcus luteus is enriched in advanced OA. Notably, M. luteus G18 exacerbates cartilage degeneration via TLR2/JNK/AP‐1‐mediated ECM disruption, revealing intra ...
Tingtao Chen, Qingwei Zeng, Tangchang Xu, Xinyue Qi, Kaiyi Li, Jing Wei, Liang Hao   +6 more
wiley   +1 more source