Reinforcements in avian wing bones: Experiments, analysis, and modeling.
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M M Porter | E Novitskaya | C J Ruestes | V A Lubarda | M A Meyers | J McKittrick | M. Meyers | J. McKittrick | E. Novitskaya | V. Lubarda | M. Porter | C. Ruestes
[1] C. Pennycuick,et al. The strength of the pigeon's wing bones in relation to their function. , 1967, The Journal of experimental biology.
[2] Karl J. Niklas,et al. Plant Biomechanics: An Engineering Approach to Plant Form and Function , 1993 .
[3] J. H. Kiang. Avian Wing Bones , 2013 .
[4] W. Thorpe,et al. Studies on Plastron respiration IV. Plastron Respiration in the Coleoptera , 1949 .
[5] L. Brazier. ON THE FLEXURE OF THIN CYLINDRICAL SHELLS AND OTHER SECTION , 1927 .
[6] M. Meyers,et al. Reinforcing Structures in Avian Wing Bones , 2014 .
[7] R. McN. Alexander,et al. The thickness of the walls of tubular bones , 2009 .
[8] Andrew A. Biewener,et al. In vivo strain in the humerus of pigeons (Columba livia) during flight , 1995 .
[9] C. J. Pennycuick,et al. Modelling the Flying Bird , 2008 .
[10] A. Casinos,et al. Incidence and mechanical significance of pneumatization in the long bones of birds , 2000 .
[11] Peter Zioupos,et al. Mechanical properties of nacre and highly mineralized bone , 2001, Proceedings of the Royal Society of London. Series B: Biological Sciences.
[12] E. de Margerie,et al. Torsional resistance as a principal component of the structural design of long bones: comparative multivariate evidence in birds. , 2004, The anatomical record. Part A, Discoveries in molecular, cellular, and evolutionary biology.
[13] V. Lubarda. On the torsion constant of multicell profiles and its maximization with respect to spar position , 2009 .
[14] P. Davis. The bioerosion of bird bones , 1997 .
[15] David R. Carrier,et al. Wing bone stresses in free flying bats and the evolution of skeletal design for flight , 1992, Nature.
[16] C. Ruff,et al. Who's afraid of the big bad Wolff?: "Wolff's law" and bone functional adaptation. , 2006, American journal of physical anthropology.
[17] Leon P A M Claessens,et al. Basic avian pulmonary design and flow-through ventilation in non-avian theropod dinosaurs , 2005, Nature.
[18] Joanna McKittrick,et al. Anisotropy in the compressive mechanical properties of bovine cortical bone and the mineral and protein constituents. , 2011, Acta biomaterialia.
[19] A. Casinos,et al. Avian long bones, flight and bipedalism. , 2001, Comparative biochemistry and physiology. Part A, Molecular & integrative physiology.
[20] A. Wolfson. Recent studies in avian biology , 1955 .
[21] Walter D. Pilkey,et al. Analysis and Design of Elastic Beams: Computational Methods , 2003 .
[22] Bruno Bruderer,et al. Wing‐beat characteristics of birds recorded with tracking radar and cine camera , 2010 .
[23] Noble S. Proctor,et al. Manual of Ornithology: Avian Structure and Function , 1993 .
[24] Marc A. Meyers,et al. Torsional properties of helix-reinforced composites fabricated by magnetic freeze casting , 2015 .
[25] James H. Brown,et al. Differences in population density and energy use between birds and mammals: A macroecological perspective , 1997 .
[26] S. A. Etnier. Twisting and Bending of Biological Beams: Distribution of Biological Beams in a Stiffness Mechanospace , 2003, The Biological Bulletin.
[27] J. F. V. Vincent,et al. Young’s moduli and shear moduli in cortical bone , 1996, Proceedings of the Royal Society of London. Series B: Biological Sciences.
[28] Friedrich Pauwels,et al. Biomechanics of the Locomotor Apparatus , 1980 .
[29] E. Dumont. Bone density and the lightweight skeletons of birds , 2010, Proceedings of the Royal Society B: Biological Sciences.
[30] P Zioupos,et al. Exploring the Effects of Hypermineralisation in Bone Tissue by Using an Extreme Biological Example , 2000, Connective tissue research.
[31] A. Burstein,et al. The elastic and ultimate properties of compact bone tissue. , 1975, Journal of biomechanics.