Abstract
This study describes and demonstrates the functionalities and application of a new R package, morphomap, designed to extract shape information as semilandmarks in multiple sections, build cortical thickness maps, and calculate biomechanical parameters on long bones. morphomap creates, from a single input (an oriented 3D mesh representing the long bone surface), multiple evenly spaced virtual sections. morphomap then directly and rapidly computes morphometric and biomechanical parameters on each of these sections. The R package comprises three modules: (a) to place semilandmarks on the inner and outer outlines of each section, (b) to extract cortical thicknesses for 2D and 3D morphometric mapping, and (c) to compute cross-sectional geometry. In this article, we apply morphomap to femora from Homo sapiens and Pan troglodytes to demonstrate its utility and show its typical outputs. morphomap greatly facilitates rapid analysis and functional interpretation of long bone form and should prove a valuable addition to the osteoarcheological analysis software toolkit. Long bone loading history is commonly retrodicted by calculating biomechanical parameters such as area moments of inertia, analyzing external shape and measuring cortical thickness. morphomap is a software written in the open source R environment, it integrates the main methodological approaches (geometric morphometrics, cortical morphometric maps, and cross-sectional geometry) used to parametrize long bones.
Highlights
The study of diaphyseal bone form based on landmarks or measurements between them, cortical thickness variations and cross-sectional geometry (CSG) are commonly carried to retrodict long bone behavior and adaptation in response to loading
While parameters describing bone form, cortical thickness variations and CSG have proven to be very useful for reconstructing bone loading patterns (Endo & Takahashi, 1982; Huiskes, 1982; Piziali, Hight, & Nagel, 1976; Uhthoff & Jaworski, 1978), the effort in calculation has tended to limit studies to a few cross-sections, some previous studies have shown the value of finer detailed analysis of whole long bone shafts and multiple sections (Lacoste Jeanson, Santos, Dupej, 2018; Lacoste Jeanson, Santos, Villa, et al, 2018; Puymerail et al, 2012)
2.1 | The morphomap R package morphomap is designed to produce by default 61 cross-sections along the diaphysis of the long bone defined at increments of 1% between 20 and 80% of its biomechanical length as it is commonly defined in studies of diaphyseal CSG (Ruff, 2002; Marchi, 2005, 2007; Figure 1a)
Summary
The study of diaphyseal bone form based on landmarks or measurements between them, cortical thickness variations and cross-sectional geometry (CSG) are commonly carried to retrodict long bone behavior and adaptation in response to loading. Computerized tomography (CT) scanning and advances in three dimensional (3D) reconstruction, visualization, parameterization, and analysis of skeletal form have facilitated the collection, sharing (i.e., morphosource, MorphoMuseum, Digital Morphology museum available at http://dmm.pri.kyoto-u.ac.jp, Kupri and NESPOS) (Boyer, Gunnell, Kaufman, & McGeary, 2016; Bradtmöller, Pastoors, Slizewski, & Weniger, 2010; Lebrun & Orliac, 2016) interpretation of large datasets (Davies et al, 2017) These advances underpin a specific subdiscipline within our field of biological anthropology, virtual anthropology (VA; Weber, Recheis, Scholze, & Seidler, 1998; Weber, 2001; Cunningham, Rahman, Lautenschlager, Rayfield, & Donoghue, 2014). The methods of VA are applicable to skeletal studies in all species
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