# Publications Search Within Results Search Within Results search ## 170 results Show filters filter\_alt Sort by Year of PublicationAlphabetical A-Z sort ## 170 results Download 170 citations download- [BibTeX](/node/1616711/export?format=bibtex) - [EndNote X3 XML](/node/1616711/export?format=endnote8) - [EndNote 7 XML](/node/1616711/export?format=endnote7) - [Endnote tagged](/node/1616711/export?format=tagged) - [Marc](/node/1616711/export?format=marc) - [PubMedId](/node/1616711/export?format=pubmed_id) - [RIS](/node/1616711/export?format=ris) ### 2025 Biewener AA, Lauder GV, Pierce SE. [The Concord Field Station at Harvard: foundational contributions to organismal physiology and biomechanics](/publication/concord-field-station-harvard-foundational-contributions-organismal-physiology-and). Journal of Experimental Biology. 2025;228(20). doi:10.1242/jeb.251226 Biewener AA, Lauder GV, Pierce SE. [The Concord Field Station at Harvard: foundational contributions to organismal physiology and biomechanics](/publication/concord-field-station-harvard-foundational-contributions-organismal-physiology-and). Journal of Experimental Biology. 2025;228(20). doi:10.1242/jeb.251226 - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/20/jeb251226/369567/The-Concord-Field-Station-at-Harvard-University) Progress in understanding animal function has been tremendously facilitated by research conducted at field stations that provide access to locations, organisms and equipment not otherwise available in more traditional urban universities or research... - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/20/jeb251226/369567/The-Concord-Field-Station-at-Harvard-University) Brocklehurst RJ, Fahn-Lai L, Biewener AA, Pierce SE. [Relationship between joint shape and function as revealed through ex vivo XROMM ](/publication/relationship-between-joint-shape-and-function-revealed-through-ex-vivo-xromm). Journal of Experimental Biology. 2025;228(10). doi:10.1242/jeb.249261 Brocklehurst RJ, Fahn-Lai L, Biewener AA, Pierce SE. [Relationship between joint shape and function as revealed through ex vivo XROMM ](/publication/relationship-between-joint-shape-and-function-revealed-through-ex-vivo-xromm). Journal of Experimental Biology. 2025;228(10). doi:10.1242/jeb.249261 - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/10/jeb249261/368018/Relationship-between-joint-shape-and-function-as) Skeletal joint morphology and mobility underlie movement, behavior and ecology in vertebrates. Joints can be categorized by their shape and articulation type, but such schemes might be unreliable for inferring function across the full diversity of... - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/10/jeb249261/368018/Relationship-between-joint-shape-and-function-as) Bhagavatula PS, Biewener AA. [Landing on a swinging perch: peach-faced lovebirds prefer extremes](/publication/landing-swinging-perch-peach-faced-lovebirds-prefer-extremes). Journal of Experimental Biology. 2025;228(8). doi:10.1242/jeb.249692 Bhagavatula PS, Biewener AA. [Landing on a swinging perch: peach-faced lovebirds prefer extremes](/publication/landing-swinging-perch-peach-faced-lovebirds-prefer-extremes). Journal of Experimental Biology. 2025;228(8). doi:10.1242/jeb.249692 - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/8/jeb249692/367743/Landing-on-a-swinging-perch-peach-faced-lovebirds) Birds frequently must land (safely) on moving branches, and seemingly accomplish this with acrobatic precision. To examine how birds target and land on moving supports, we investigated how lovebirds approach and land on a swinging perch, driven at three... - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/8/jeb249692/367743/Landing-on-a-swinging-perch-peach-faced-lovebirds) Biewener AA, Wilson AM. [Integrating biomechanics, energetics and ecology perspectives in locomotion. (Commentary) ](/publication/integrating-biomechanics-energetics-and-ecology-perspectives-locomotion-commentary). Journal of Experimental Biology. 2025;228(Suppl_1). doi:10.1242/jeb.249585 Biewener AA, Wilson AM. [Integrating biomechanics, energetics and ecology perspectives in locomotion. (Commentary) ](/publication/integrating-biomechanics-energetics-and-ecology-perspectives-locomotion-commentary). Journal of Experimental Biology. 2025;228(Suppl_1). doi:10.1242/jeb.249585 - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/Suppl_1/JEB249585/365529/Integrating-biomechanics-energetics-and-ecology) - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/Suppl_1/JEB249585/365529/Integrating-biomechanics-energetics-and-ecology) Zhang ZM, Konow N, Biewener AA. [Hummingbirds excel at maneuvering and flying through tight spaces](/publication/hummingbirds-excel-maneuvering-and-flying-through-tight-spaces). Journal of Experimental Biology. 2025;228(11). doi:10.1242/jeb.250269 Zhang ZM, Konow N, Biewener AA. [Hummingbirds excel at maneuvering and flying through tight spaces](/publication/hummingbirds-excel-maneuvering-and-flying-through-tight-spaces). Journal of Experimental Biology. 2025;228(11). doi:10.1242/jeb.250269 - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/11/jeb250269/368159/Hummingbirds-excel-at-maneuvering-and-flying) Flying animals (birds, bats and insects) often negotiate cluttered environments, sometimes involving the need to safely transit through tight spaces between obstacles. Considering their remarkable flight capabilities, hummingbirds are suitable for gaining... - [ descriptionPublisher's Version](https://journals.biologists.com/jeb/article/228/11/jeb250269/368159/Hummingbirds-excel-at-maneuvering-and-flying) ### 2023 Schwaner M, Gordon JC, Biewener, Daley. [Muscle force-length dynamics during walking over obstacles indicates delayed recovery and a shift towards more ‘strut-like’ function in birds with proprioceptive deficit.](/publications/muscle-force-length-dynamics-during-walking-over-obstacles-indicates-delayed) J. Exp. Biology. 2023;266:12. Schwaner M, Gordon JC, Biewener, Daley. [Muscle force-length dynamics during walking over obstacles indicates delayed recovery and a shift towards more ‘strut-like’ function in birds with proprioceptive deficit.](/publications/muscle-force-length-dynamics-during-walking-over-obstacles-indicates-delayed) J. Exp. Biology. 2023;266:12. - [ descriptionPublisher's Version](https://doi.org/10.1242/jeb.245199) - [ picture\_as\_pdfschwaneretal\_muscle-fldyn...](/sites/g/files/omnuum6301/files/schwaneretal_muscle-fldynamicsobstaclewalking_jeb2023.pdf) - [ descriptionPublisher's Version](https://doi.org/10.1242/jeb.245199) - [ picture\_as\_pdfschwaneretal\_muscle-fldyn...](/sites/g/files/omnuum6301/files/schwaneretal_muscle-fldynamicsobstaclewalking_jeb2023.pdf) ### 2022 Biewener AA. [Physiology – Woodpecker skulls are not shock absorbers](/publications/physiology-%E2%80%93-woodpecker-skulls-are-not-shock-absorbers). Current Biology. 2022;32(14):R767-R769. Biewener AA. [Physiology – Woodpecker skulls are not shock absorbers](/publications/physiology-%E2%80%93-woodpecker-skulls-are-not-shock-absorbers). Current Biology. 2022;32(14):R767-R769. - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://doi.org/10.1016/j.cub.2022.06.037) Woodpeckers are well-known for their audible percussive wood drilling. A new study shows that these birds benefit from their small size and key skull features to safely hammer at wood for insect food and nesting excavations. - [ descriptionPublisher's Version](https://doi.org/10.1016/j.cub.2022.06.037) Biewener AA, Bomphrey RN, Daley MA, Isjpeert AJ. [Stability and manoeuvrability in animal movement: lessons from biology, modelling, and robotics](/publications/stability-and-manoeuvrability-animal-movement-lessons-biology-modelling-and). Proceedings of the Royal Society, B. 2022;289(1967):1–5. Biewener AA, Bomphrey RN, Daley MA, Isjpeert AJ. [Stability and manoeuvrability in animal movement: lessons from biology, modelling, and robotics](/publications/stability-and-manoeuvrability-animal-movement-lessons-biology-modelling-and). Proceedings of the Royal Society, B. 2022;289(1967):1–5. - [ descriptionPublisher's Version](https://doi.org/10.1098/rspb.2021.2492) - [ descriptionPublisher's Version](https://doi.org/10.1098/rspb.2021.2492) Harrison J, Biewener A, Bernhardt J, Burger J, Brown J, Coto Z, Duell M, Lynch M, Moffett E, Norin T, et al. [White paper: An Integrated Perspective on the Causes ofHypometric Metabolic Scaling in Animals.](/publications/white-paper-integrated-perspective-causes-ofhypometric-metabolic-scaling) Int. Comp. Biology. 2022;62(5):1395–1418. Harrison J, Biewener A, Bernhardt J, Burger J, Brown J, Coto Z, Duell M, Lynch M, Moffett E, Norin T, et al. [White paper: An Integrated Perspective on the Causes ofHypometric Metabolic Scaling in Animals.](/publications/white-paper-integrated-perspective-causes-ofhypometric-metabolic-scaling) Int. Comp. Biology. 2022;62(5):1395–1418. - [ descriptionPublisher's Version](https://doi.org/10.1093/icb/icac136) - [ picture\_as\_pdfharrisonetal\_causeshypome...](/sites/g/files/omnuum6301/files/harrisonetal_causeshypometricmetabolicscaling_icb2022.pdf) - [ descriptionPublisher's Version](https://doi.org/10.1093/icb/icac136) - [ picture\_as\_pdfharrisonetal\_causeshypome...](/sites/g/files/omnuum6301/files/harrisonetal_causeshypometricmetabolicscaling_icb2022.pdf) Biewener. [Primer: Biomechanics of avian flight.](/publications/primer-biomechanics-avian-flight) Current Biology. 2022;32:R1110–1114. Biewener. [Primer: Biomechanics of avian flight.](/publications/primer-biomechanics-avian-flight) Current Biology. 2022;32:R1110–1114. - [ descriptionPublisher's Version](https://doi.org/10.1016/j.cub.2022.06.079) - [ picture\_as\_pdfbiewener\_biomechanicsavia...](/sites/g/files/omnuum6301/files/biewener_biomechanicsavianflight_currbiol_2022.pdf) - [ descriptionPublisher's Version](https://doi.org/10.1016/j.cub.2022.06.079) - [ picture\_as\_pdfbiewener\_biomechanicsavia...](/sites/g/files/omnuum6301/files/biewener_biomechanicsavianflight_currbiol_2022.pdf) ### 2021 Tijs C, Konow, Biewener AA. [Effect of muscle stimulation intensity on the heterogeneous function of compartments within an architecturally complex muscle](/publications/effect-muscle-stimulation-intensity-heterogeneous-function-compartments-within). Journal of Applied Physiology. 2021;130(4):941–951. Tijs C, Konow, Biewener AA. [Effect of muscle stimulation intensity on the heterogeneous function of compartments within an architecturally complex muscle](/publications/effect-muscle-stimulation-intensity-heterogeneous-function-compartments-within). Journal of Applied Physiology. 2021;130(4):941–951. - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://doi.org/10.1152/japplphysiol.00514.2020) Skeletal muscle has fiber architectures ranging from simple to complex, alongside variations in fiber-type and neuro-anatomical compartmentalization. However, the functional implications of muscle subdivision into discrete functional units remain... - [ descriptionPublisher's Version](https://doi.org/10.1152/japplphysiol.00514.2020) Biewener AA, Wakeling JM, Konow N. [Modeling muscle function using experimentally determined subject-specific muscle properties](/publications/modeling-muscle-function-using-experimentally-determined-subject-specific). Journal of Biomechanics. 2021;117(110242). Biewener AA, Wakeling JM, Konow N. [Modeling muscle function using experimentally determined subject-specific muscle properties](/publications/modeling-muscle-function-using-experimentally-determined-subject-specific). Journal of Biomechanics. 2021;117(110242). - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](doi.org/10.1016/j.jbiomech.2021.110242) ## Abstract Muscle models are commonly based on intrinsic properties pooled across a number of individuals, often from a different species, and rarely validated against directly measured muscle forces. Here we use a rich data set of rat medial [gastrocnemius](https://www.sciencedirect.com/topics/medicine-and-dentistry/gastrocnemius-muscle)... - [ descriptionPublisher's Version](doi.org/10.1016/j.jbiomech.2021.110242) - Previous page chevron\_left - [1](?page=0 "Current page") - [2](?page=1 "Go to page 2") - [3](?page=2 "Go to page 3") - [ Last page 15 ](?page=14 "Go to last page") - [ Next page chevron\_right ](?page=1 "Go to next page")