Karen R. Swan, Zewdi J. Tsegai, Rachel Ives, Louise T. Humphrey
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Diaphyseal cross-sections were extracted from micro-CT scans of the femur at 35%, 50%, and 65% of total intermetaphyseal length and variation in cortical bone structure was assessed based on bending rigidity (Imax/Imin, Ix/Iy), relative medullary area, and cortical bone porosity.</p>\n </section>\n \n <section>\n \n <h3> Results</h3>\n \n <p>Diaphyseal shape is relatively circular with a high amount of cortical bone porosity and a large relative medullary area during early infancy. Distinct shifts in cortical bone structure occurred for each studied parameter with the biggest changes occurring within the first 5 years. Values appear to stabilize as quadrupedal walking increases in frequency and is established as the main form of locomotion.</p>\n </section>\n \n <section>\n \n <h3> Discussion</h3>\n \n <p>Collectively, the results suggest a degree of integration in which cortical bone restructures in response to rapid changes in locomotion in addition to nonmechanical influences such as hormonal, and growth factors, without compromising function and structural integrity. The extent of influence of each factor varies throughout growth and highlights the need for caution in functional interpretations of cortical bone geometry.</p>\n </section>\n </div>","PeriodicalId":29759,"journal":{"name":"American Journal of Biological Anthropology","volume":"186 1","pages":""},"PeriodicalIF":1.7000,"publicationDate":"2024-11-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11663440/pdf/","citationCount":"0","resultStr":"{\"title\":\"Restructuring of Femoral Cortical Bone During Growth and Locomotor Development of Wild Chimpanzees (Pan troglodytes verus)\",\"authors\":\"Karen R. Swan, Zewdi J. Tsegai, Rachel Ives, Louise T. 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Diaphyseal cross-sections were extracted from micro-CT scans of the femur at 35%, 50%, and 65% of total intermetaphyseal length and variation in cortical bone structure was assessed based on bending rigidity (Imax/Imin, Ix/Iy), relative medullary area, and cortical bone porosity.</p>\\n </section>\\n \\n <section>\\n \\n <h3> Results</h3>\\n \\n <p>Diaphyseal shape is relatively circular with a high amount of cortical bone porosity and a large relative medullary area during early infancy. Distinct shifts in cortical bone structure occurred for each studied parameter with the biggest changes occurring within the first 5 years. 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引用次数: 0
摘要
目的:黑猩猩的运动发育和从被搬运到从事悬吊和树上运动行为到最终依靠陆地四足行走作为主要运动方式的转变是一个滞后的过程。在这里,我们考虑在野生黑猩猩生长和运动发育期间股骨皮质骨重构的机械意义。材料和方法:研究了年龄在2周至12.6岁之间的野生黑猩猩单一亚种(P. t. verus)的个体发生样本的皮质骨结构。从股骨显微ct扫描中提取干骺端总长度的35%、50%和65%的横截面,并根据弯曲刚度(Imax/Imin, Ix/Iy)、相对髓质面积和皮质骨孔隙度评估皮质骨结构的变化。结果:婴幼儿早期干骺端形状相对圆形,皮质骨孔隙率高,相对髓质面积大。每个研究参数的皮质骨结构都发生了明显的变化,最大的变化发生在前5年。随着四足行走频率的增加和作为主要运动形式的确立,这些数值趋于稳定。讨论:总的来说,结果表明皮质骨在响应快速运动变化以及非机械性影响(如激素和生长因子)的情况下重构了一定程度的整合,而不影响功能和结构完整性。每个因素的影响程度在整个生长过程中都是不同的,这强调了对皮质骨几何结构的功能解释需要谨慎。
Restructuring of Femoral Cortical Bone During Growth and Locomotor Development of Wild Chimpanzees (Pan troglodytes verus)
Objective
Chimpanzees are altricial in terms of their locomotor development and transition from being carried to engaging in suspensory and arboreal locomotor behaviors to eventually relying on terrestrial quadrupedalism as their main form of locomotion. Here, we consider the mechanical implications of femoral cortical bone restructuring during growth and locomotor development in wild chimpanzees.
Materials and Methods
Cortical bone structure was examined in an ontogenetic sample of wild chimpanzees from a single subspecies (P. t. verus) spanning in age from 2 weeks to 12.6 years. Diaphyseal cross-sections were extracted from micro-CT scans of the femur at 35%, 50%, and 65% of total intermetaphyseal length and variation in cortical bone structure was assessed based on bending rigidity (Imax/Imin, Ix/Iy), relative medullary area, and cortical bone porosity.
Results
Diaphyseal shape is relatively circular with a high amount of cortical bone porosity and a large relative medullary area during early infancy. Distinct shifts in cortical bone structure occurred for each studied parameter with the biggest changes occurring within the first 5 years. Values appear to stabilize as quadrupedal walking increases in frequency and is established as the main form of locomotion.
Discussion
Collectively, the results suggest a degree of integration in which cortical bone restructures in response to rapid changes in locomotion in addition to nonmechanical influences such as hormonal, and growth factors, without compromising function and structural integrity. The extent of influence of each factor varies throughout growth and highlights the need for caution in functional interpretations of cortical bone geometry.
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