Literature DB >> 27818743

The clinical contribution of cortical porosity to fragility fractures.

Åshild Bjørnerem1.   

Abstract

Cortical bone is not compact; rather it is penetrated by many Haversian and Volkmann canals for blood supply. The lining of these canals are the intracortical bone surfaces available for bone remodeling. Increasing intracortical bone remodeling increases cortical porosity. However, cortical bone loss occurs more slowly than trabecular loss due to the fact that less surface per unit of bone matrix volume is available for bone remodeling. Nevertheless, most of the bone loss over time is cortical because cortical bone constitutes 80% of the skeleton, and the relative proportion of trabecular bone diminishes with advancing age. Higher serum levels of bone turnover markers are associated with higher cortical porosity of the distal tibia and the proximal femur. Greater porosity of the distal radius is associated with higher odds for forearm fracture, and greater porosity of the proximal femur is associated with higher odds for non-vertebral fracture in postmenopausal women. Measurement of cortical porosity contributes to fracture risk independent of areal bone mineral density and Fracture Risk Assessment Tool. On the other hand, antiresorptive treatment reduces porosity at the distal radius and at the proximal femoral shaft. Thus, porosity is a substantial determinant of the bone fragility that underlies the risk of fractures and may be a target for fracture prevention.

Entities:  

Year:  2016        PMID: 27818743      PMCID: PMC5081000          DOI: 10.1038/bonekey.2016.77

Source DB:  PubMed          Journal:  Bonekey Rep        ISSN: 2047-6396


  49 in total

1.  The burden of osteoporotic fractures: a method for setting intervention thresholds.

Authors:  J A Kanis; A Oden; O Johnell; B Jonsson; C de Laet; A Dawson
Journal:  Osteoporos Int       Date:  2001       Impact factor: 4.507

2.  Stiffness of compact bone: effects of porosity and density.

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Journal:  J Biomech       Date:  1988       Impact factor: 2.712

3.  Risedronate slows or partly reverses cortical and trabecular microarchitectural deterioration in postmenopausal women.

Authors:  Yohann Bala; Roland Chapurlat; Angela M Cheung; Dieter Felsenberg; Michel LaRoche; Edward Morris; Jonathan Reeve; Thierry Thomas; Jose Zanchetta; Oliver Bock; Ali Ghasem-Zadeh; Roger Martin Zebaze Djoumessi; Ego Seeman; René Rizzoli
Journal:  J Bone Miner Res       Date:  2014-02       Impact factor: 6.741

4.  Bone turnover markers are associated with higher cortical porosity, thinner cortices, and larger size of the proximal femur and non-vertebral fractures.

Authors:  Rajesh Shigdel; Marit Osima; Luai A Ahmed; Ragnar M Joakimsen; Erik F Eriksen; Roger Zebaze; Åshild Bjørnerem
Journal:  Bone       Date:  2015-06-22       Impact factor: 4.398

5.  Cortical porosity identifies women with osteopenia at increased risk for forearm fractures.

Authors:  Yohann Bala; Roger Zebaze; Ali Ghasem-Zadeh; Elizabeth J Atkinson; Sandra Iuliano; James M Peterson; Shreyasee Amin; Åshild Bjørnerem; L Joseph Melton; Helena Johansson; John A Kanis; Sundeep Khosla; Ego Seeman
Journal:  J Bone Miner Res       Date:  2014-06       Impact factor: 6.741

6.  Direct comparison of eight national FRAX® tools for fracture prediction and treatment qualification in Canadian women.

Authors:  W D Leslie; S L Brennan; L M Lix; H Johansson; A Oden; E McCloskey; J A Kanis
Journal:  Arch Osteoporos       Date:  2013-08-09       Impact factor: 2.617

7.  Hip fractures and the contribution of cortical versus trabecular bone to femoral neck strength.

Authors:  Gerold Holzer; Gobert von Skrbensky; Lukas A Holzer; Wolfgang Pichl
Journal:  J Bone Miner Res       Date:  2009-03       Impact factor: 6.741

8.  Bone mineral density thresholds for pharmacological intervention to prevent fractures.

Authors:  Ethel S Siris; Ya-Ting Chen; Thomas A Abbott; Elizabeth Barrett-Connor; Paul D Miller; Lois E Wehren; Marc L Berger
Journal:  Arch Intern Med       Date:  2004-05-24

9.  Determinants of Transitional Zone Area and Porosity of the Proximal Femur Quantified In Vivo in Postmenopausal Women.

Authors:  Rajesh Shigdel; Marit Osima; Marko Lukic; Luai A Ahmed; Ragnar M Joakimsen; Erik F Eriksen; Åshild Bjørnerem
Journal:  J Bone Miner Res       Date:  2015-12-23       Impact factor: 6.741

10.  Age- and gender-related differences in the geometric properties and biomechanical significance of intracortical porosity in the distal radius and tibia.

Authors:  Andrew J Burghardt; Galateia J Kazakia; Sweta Ramachandran; Thomas M Link; Sharmila Majumdar
Journal:  J Bone Miner Res       Date:  2010-05       Impact factor: 6.741
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  12 in total

1.  Serum parathyroid hormone is associated with increased cortical porosity of the inner transitional zone at the proximal femur in postmenopausal women: the Tromsø Study.

Authors:  M Osima; T T Borgen; M Lukic; G Grimnes; R M Joakimsen; E F Eriksen; Å Bjørnerem
Journal:  Osteoporos Int       Date:  2017-11-14       Impact factor: 4.507

2.  Cortical Bone Loss Following Gastric Bypass Surgery Is Not Primarily Endocortical.

Authors:  Saghi Sadoughi; Courtney Pasco; Gabby B Joseph; Po-Hung Wu; Anne L Schafer; Galateia J Kazakia
Journal:  J Bone Miner Res       Date:  2022-02-08       Impact factor: 6.390

3.  Increased cortical porosity and reduced cortical thickness of the proximal femur are associated with nonvertebral fracture independent of Fracture Risk Assessment Tool and Garvan estimates in postmenopausal women.

Authors:  Rita Kral; Marit Osima; Tove T Borgen; Roald Vestgaard; Elin Richardsen; Åshild Bjørnerem
Journal:  PLoS One       Date:  2017-09-25       Impact factor: 3.240

4.  Diabetes Mellitus-induced Bone Fragility.

Authors:  Ippei Kanazawa; Toshitsugu Sugimoto
Journal:  Intern Med       Date:  2018-05-18       Impact factor: 1.271

5.  Computed tomography porosity and spherical indentation for determining cortical bone millimetre-scale mechanical properties.

Authors:  Oliver R Boughton; Shaocheng Ma; Xiran Cai; Liye Yan; Laura Peralta; Pascal Laugier; James Marrow; Finn Giuliani; Ulrich Hansen; Richard L Abel; Quentin Grimal; Justin P Cobb
Journal:  Sci Rep       Date:  2019-05-15       Impact factor: 4.379

6.  Bone loss markers in the earliest Pacific Islanders.

Authors:  Justyna J Miszkiewicz; Frédérique Valentin; Christina Vrahnas; Natalie A Sims; Jitraporn Vongsvivut; Mark J Tobin; Geoffrey Clark
Journal:  Sci Rep       Date:  2021-02-17       Impact factor: 4.379

7.  Contemporary kidney transplantation has a limited impact on bone microarchitecture.

Authors:  Catarina Meng; Hanne Skou Jørgensen; Lieve Verlinden; Nathalie Bravenboer; Henriette de Loor; Patrick C D'Haese; Geert Carmeliet; Pieter Evenepoel
Journal:  Bone Rep       Date:  2022-02-07

Review 8.  The challenges of diagnosing osteoporosis and the limitations of currently available tools.

Authors:  Palak Choksi; Karl J Jepsen; Gregory A Clines
Journal:  Clin Diabetes Endocrinol       Date:  2018-05-29

9.  MRI-derived bone porosity index correlates to bone composition and mechanical stiffness.

Authors:  Abigail L Hong; Mikayel Ispiryan; Mugdha V Padalkar; Brandon C Jones; Alexandra S Batzdorf; Snehal S Shetye; Nancy Pleshko; Chamith S Rajapakse
Journal:  Bone Rep       Date:  2019-06-26

10.  Best Performance Parameters of HR-pQCT to Predict Fragility Fracture: Systematic Review and Meta-Analysis.

Authors:  Wing-Hoi Cheung; Vivian Wing-Yin Hung; Ka-Yee Cheuk; Wai-Wang Chau; Kelvin Kam-Fai Tsoi; Ronald Man-Yeung Wong; Simon Kwoon-Ho Chow; Tsz-Ping Lam; Patrick Shu-Hang Yung; Sheung-Wai Law; Ling Qin
Journal:  J Bone Miner Res       Date:  2021-10-18       Impact factor: 6.390
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