Regional maps of rib cortical bone thickness and cross‐sectional geometry

Holcombe, Sven A.; Kang, Yun‐Seok; Derstine, Brian A.; Wang, Stewart C.; Agnew, Amanda M.

Affiliations

¹Morphomics Analysis Group, University of Michigan, Ann Arbor, MI, USA

²Injury Biomechanics Research Center, The Ohio State University, Columbus, OH, USA

³Department of Surgery, University of Michigan, Ann Arbor, MI, USA

Abstract and keywords

Here we present detailed regional bone thickness and cross‐sectional measurements from full adult ribs using high resolution CT scans processed with a cortical bone mapping technique. Sixth ribs from 33 subjects ranging from 24 to 99 years of age were used to produce average cortical bone thickness maps and to provide average ± 1SD corridors for expected cross‐section properties (cross‐sectional areas and inertial moments) as a function of rib length. Results obtained from CT data were validated at specific rib locations using direct measurements from cut sections. Individual thickness measurements from CT had an accuracy (mean error) and precision (SD error) of −0.013 ± 0.167 mm (R2 coefficient of determination of 0.84). CT‐based measurement errors for rib cross‐sectional geometry were −0.1 ± 13.1% (cortical bone cross‐sectional area) and 4.7 ± 1.8% (total cross‐sectional area). Rib cortical bone thickness maps show the expected regional variation across a typical rib's surface. The local mid‐rib maxima in cortical thickness along the pleural rib aspect ranged from range 0.9 to 2.6 mm across the study population with an average map maximum of 1.4 mm. Along the cutaneous aspect, rib cortical bone thickness ranged from 0.7 to 1.9 mm with an average map thickness of 0.9 mm. Average cross‐sectional properties show a steady reduction in total cortical bone area from 10% along the rib's length through to the sternal end, whereas overall cross‐sectional area remains relatively constant along the majority of the rib's length before rising steeply towards the sternal end. On average, male ribs contained more cortical bone within a given cross‐section than was seen for female ribs. Importantly, however, this difference was driven by male ribs having larger overall cross‐sectional areas, rather than by sex differences in the bone thickness observed at specific local cortex sites. The cortical bone thickness results here can be used directly to improve the accuracy of current human body and rib models. Furthermore, the measurement corridors obtained from adult subjects across a wide age range can be used to validate future measurements from more widely available image sources such as clinical CT where gold standard reference measures (e.g. such as direct measurements obtained from cut sections) are otherwise unobtainable.

Keywords: computational models; computed tomography; cortical bone; cortical thickness; cross-sectional geometry; rib

Links

DOI: 10.1111/joa.13045

PubMed: 31225915

WoS: 000490116100003

History

Accepted: 2019-05-27

Online: 2019-06-21

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Cited By (5)

Year	Entry
2020	Fleischmann KM, Hsu F-C, Aira JR, Gayzik FS. The effect of varying enclosed area and age-adjusted cortical bone properties on the structural response of the rib: a simulation study. In: Proceedings of the 2020 International IRCOBI Conference on the Biomechanics of Injury. 2020; Munich, Germany.123-136.
2022	Larsson K-J, Iraeus J, Pipkorn B, Holcombe S. Influence of individual ribcage shape variability on occupant rib fracture risk. In: Proceedings of the 2022 International IRCOBI Conference on the Biomechanics of Injury. September 14-16, 2022; Porto, Portugal.667-684.
2020	Holcombe SA, Brown E, Agnew AM, Wang SC. Average male and female rib cross‐sectional shapes via PCA. In: Proceedings of the 2020 International IRCOBI Asia Conference on the Biomechanics of Injury. 2020; Beijing, China.56-59.
2023	Bernier E, Driscoll M. Numerical investigation of intra-abdominal pressure and spinal load-sharing upon the application of an abdominal belt. J Biomech. December 1, 2023;161:111863.
2019	Iraeus J, Lundin L, Storm S, Agnew A, Kang Y-S, Kemper A, Albert D, Holcombe S, Pipkorn B. Detailed subject-specific FE rib modeling for fracture prediction. Traffic Inj Prev. 2019;20(suppl 2):S88-S95.