{"id":13,"date":"2013-02-22T11:56:47","date_gmt":"2013-02-22T19:56:47","guid":{"rendered":"http:\/\/faculty.washington.edu\/ssantana\/wordpress\/?page_id=13"},"modified":"2026-03-12T10:55:13","modified_gmt":"2026-03-12T17:55:13","slug":"publications","status":"publish","type":"page","link":"http:\/\/faculty.washington.edu\/ssantana\/wordpress\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\n

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\"J<\/a> \"\" <\/a>\"Functional<\/a>\u00a0<\/a>\"\"<\/a>\u00a0<\/span>\"\"<\/a>\"\"<\/a>\"\"<\/a> \"\"<\/a><\/p>\n

Preprints (Bold = lab members)<\/span><\/strong><\/p>\n

Mello M.A.R., Santana S.E.<\/strong>, Forget P.-M., Kita C., Lotfi N., Machado I., Muylaert R., Rodrigues F., Straka T.M., and Dormann C.F. A novel semantic theory of the assembly rules of interaction networks. Preprint<\/a><\/p>\n

Published\/in press (Bold = lab members)<\/span><\/strong><\/p>\n

Quinche L.L.<\/strong>, Garz\u00f3n-Agudelo F., Santana S.E.<\/strong>, L\u00f3pez-Ar\u00e9valo H.F, and Rico-Guevara A. 2026. Convergent mechanisms, divergent strategies: a comparison of nectar intake between a generalist and a specialized bat species. Journal of Experimental Biology<\/em> 229 (5): jeb251404. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>, Aggarwal A.<\/strong>, Sil S.<\/strong>, and Chaverri G. 2026. The ecology of attraction: fruit traits and frugivore diversity in Neotropical Piper<\/em>. Functional Ecology <\/em>40:611\u2013623. PDF<\/a><\/span><\/p>\n

King N.A., Loeffler J., Rosenberger V., Wagner F., Chhaya V.<\/strong>, DeLeon V.B., Curtis A.<\/strong>, Eiting T.P., Santana S.E.<\/strong>, and Smith T.D. 2026. Functional microanatomy of nasal turbinals in bats. The Anatomical Record <\/em>309(4):1073\u20131132. PDF<\/a><\/span><\/p>\n

Smith T.D., Downing S.E., Rosenberger V.B., Loeffler J.R., King N.A., Curtis A.A.<\/strong>, Eiting T.P., and Santana S.E.<\/strong> 2026. Functional microanatomy of the vomeronasal complex of bats. The Anatomical Record <\/em>309(4):1133\u20131160. <\/em>PDF<\/a><\/span><\/p>\n

McLean B., Bloom D., Lafrance R., Guralnick R., Santana S.E.<\/strong>, and Davis E. 2026. Ranges Network collected mammal trait measurements and summary from western North America (Version 1.0) [Data set]. Zenodo<\/em>\u00a0https:\/\/doi.org\/10.5281\/zenodo.18201648<\/a><\/p>\n

Santana S.E.<\/strong>, Bernal-Rivera A., Chhaya V., Guerra E.B., Quinche L.L., Visconti F., <\/strong>and Law C.J. <\/strong>2025. An integrative perspective of bat evolution. Annual Review of Ecology, Evolution, and Systematics <\/em>56:291\u2013314.<\/em> PDF<\/a><\/span><\/p>\n

McLean B., Bloom D., Davis E., Guralnick R., Santana S.E.<\/strong> et al. 2025. Extending mammal specimens with their essential phenotypic traits. Journal of Mammalogy<\/em> 106(5): 1282\u20131291. PDF<\/a><\/span><\/p>\n

Yohe, L.R., Leiser-Miller L.B.<\/strong>, Kaliszewska Z.A.<\/strong>, Whitehead S.R., Santana S.E.<\/strong>, and D\u00e1valos L.M. 2025. Testing for reciprocal trait influence in plant-frugivore interactions using generalized joint attribute modeling. Ecology and Evolution<\/em> 15(1): e70772. PDF<\/a><\/span><\/p>\n

Ramos R., Pham K.T., Prince R.C., Leiser-Miller L.B.<\/strong>, Prasad M.S., Wang X., Nordberg R.C., Bielajew B.J., Hu J.C., Yamaga K., Oh J.W., Peng T., Datta R., Astrowskaja A., Almet A.A., Burns J.T., Liu Y., Guerrero-Juarez C.F., Tran B.Q., Chu Y.-L., Nguyen A.M., Hsi T.-C., Lim N.T.-L., Schoeniger S., Liu R., Pai Y.-L., Vadivel C.K., Ingleby S., McKechnie A.E., van Breukelen F., Hoehn K.L., Rasweiler J.J., Kohara M., Loughry W.J., Weldy S.H., Cosper, R. Yang, C.-C., Lin S.-J., Cooper K.L., Santana S.E.<\/strong>, Bradley J.E.<\/strong>, Kiebish M.A., Digman M., James D.E., Merrill A.E., Nie Q., Schilling T.F., Astrowski A.A., Potma E.O., Garc\u00eda-Castro M.I., Athanasiou K.A., Behringer R.R., and Plikus M. V. 2025. Superstable lipid vacuoles endow cartilage with its shape and biomechanics. Science<\/em> 387: eads9960. PDF<\/a><\/span><\/p>\n

Gill D., Santana S.E.<\/strong>, and Arbour J.H. 2025. Macroevolutionary and biomechanical implications of rostral flexion in bat skulls: a major early driver of cranial evolution in bats. Biological Journal of the Linnean Society <\/em>144(1): blae123. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>, Sadier A., and Mello M.A.R. 2024. The ecomorphological radiation of phyllostomid bats. Evolutionary Journal of the Linnean Society <\/em>3(1): kzae032. PDF<\/a><\/span><\/p>\n

Sil S., Visconti F.<\/strong>, Chaverri G., and\u00a0Santana S.E.<\/strong> 2024. Effects of habitat and fruit scent on the interactions between short-tailed fruit bats and\u00a0Piper<\/em> plants.Integrative Organismal Biology <\/em>obae028. PDF<\/a><\/span><\/p>\n

Burtner A.E., Grossnickle D.M., Santana S.E., <\/strong>and Law C.J.<\/strong> 2024. Gliding towards an understanding of the origin of flight in bats. PeerJ<\/em> 12:e17824. PDF<\/a><\/span><\/p>\n

Kelly R.M.<\/strong> and Santana S.E.<\/strong> 2024. Island area and diet predict diversity and distribution of bats in a Pacific Northwest archipelago. Journal of Mammalogy <\/em>105(5): 976-987. PDF<\/a><\/span><\/p>\n

Smith T.D., Stanchak K.E., Downing S.E., King N.A., Rosenberger V.B., Eiting T.P., Curtis A.A., Faure P.A., and Santana S.E.<\/strong> 2024. Postnatal ontogeny of nasal turbinals in the big brown bat, Eptesicus fuscus<\/em>. Journal of North American Bat Research <\/em>2(3):1-16. PDF<\/a><\/span><\/p>\n

Grossnickle, D.M.<\/strong>, Sadier A.A., Patterson E.<\/strong>, Cortes-Viruet N.N., Jimenez Rivera S., Sears K.E., and Santana S.E. <\/strong>2024. The hierarchical radiation of phyllostomid bats as revealed by adaptive molar morphology.\u00a0Current Biology<\/em> 34(6): 1284-1294.e3. PDF<\/a><\/span><\/p>\n

Smith T.D., Santana S.E.<\/strong>, and Eiting T.P. 2023. Ecomorphology and sensory biology of bats. The Anatomical Record<\/em> 306(11): 2660-2669. PDF<\/a><\/span><\/p>\n

Sadier A., Anthwal N., Krause A.L., Dessalles R., Lake M., Bentolila L.A., Haase R., Nieves N.A., Santana S.E.,<\/strong> and Sears K.E. 2023. Bat teeth illuminate the diversification of mammalian tooth classes. Nature Communications <\/em>14, 4687. PDF<\/a><\/span><\/p>\n

Stanchak K.E., Faure P.A., and Santana S.E.<\/strong> 2023. Ontogeny of cranial musculoskeletal anatomy and its relationship to allometric increase in bite force in an insectivorous bat (Eptesicus fuscus<\/em>). The Anatomical Record<\/em>. 306(11): 2842-2852. PDF<\/a><\/span><\/p>\n

Dickinson E., Tomblin E., Rose M., Tate Z., Gottimikkula M., Granatosky M.C., Santana S.E.<\/strong>, Hartstone-Rose A. 2023. Ecomorphological correlates of inner and middle ear anatomy within phyllostomid bats. The Anatomical Record <\/em>306(11): 2751-2764. PDF<\/a><\/span><\/p>\n

Rickman J., Burtner A.E., Linden T.J., Santana S.E., <\/strong>and Law C.J.<\/strong> 2023. Size and locomotor ecology have differing effects on the external and internal morphologies of squirrel (Rodentia: Sciuridae) limb bones. Integrative Organismal Biology <\/em>obad017. PDF<\/span><\/a><\/p>\n

Linden T.J., Burtner A.E., Rickman J., McFeely A., Santana S.E., <\/strong>and Law C.J. <\/strong>2023. Scaling patterns of body plans differ among squirrel ecotypes. PeerJ<\/em> 11:e14800. PDF<\/a><\/span><\/p>\n

Quinche L., Santana S.E.<\/strong>, and Rico-Guevara A. 2022. Morphological specialization to nectarivory in Phyllostomus discolor<\/em> (Wagner, 1843) (Chiroptera: Phyllostomidae). The Anatomical Record <\/em>306(11): 2830-2841. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong> and Grossnickle D.M.<\/strong> 2022. Bursts in skull evolution weakened with time. Science <\/em>378(6618): 355-356. PDF<\/a><\/span><\/p>\n

Holding M., Trevine V., Zinenko O., Strickland J., Rautsaw R., Mason A., Hofmann E., Hogan M., Parkinson C., Grazziotin F., Davis M., Santana S.E.<\/strong>, and Rokyta D. 2022. Evolutionary allometry, climate, and dietary specialization explain fang length evolution in vipers. Proceedings of the Royal Society B <\/em>289(1982): 20221132.<\/em>PDF<\/a><\/span><\/p>\n

Law C.J.<\/strong>, Blackwell E.A., Curtis A.A.<\/strong>, Dickinson E., Hartstone-Rose A., and Santana S.E.<\/strong> 2022. Decoupled evolution of the cranium and mandible in carnivoran mammals. Evolution <\/em>76(12): 2959-2974. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>, Grossnickle D.M.<\/strong>, Sadier A., Patterson E.<\/strong>, and Sears K.E. 2022. Bat dentitions: a model system for studies at the interface of development, biomechanics, and evolution. Integrative and Comparative Biology <\/em>62(3): 762\u2013773. PDF<\/a><\/span><\/p>\n

Villalobos Chaves D.A.<\/strong> and <\/span>Santana S.E. <\/strong>2022. Dental topography predicts feeding performance differences in a community of Neotropical free-tailed bats (Molossidae). <\/span>Functional Ecology\u00a0<\/em>36(7): 1690-1699. PDF<\/a><\/span><\/p>\n

Smith T.D., DeLeon V.B., Eiting T.P., Corbin H., Bhatnagar K.P. and Santana S.E. <\/strong>2022. Networks in the upper airways of bats: A histological and diceCT study. The Anatomical Record <\/em>305(8): 1871-1891. PDF<\/a><\/span><\/p>\n

Florez-Montero G.L., Muylaert, R.L., Nogueira M.R., Geiselman C.; Santana S.E.<\/strong>, Stevens R.D., Tschapka M., Rodrigues F.A. and Mello M.A.R. 2022. NeoBat Interactions: a data set of bat-plant interactions in the Neotropics. Ecology <\/em>103(4): e3640. PDF<\/a><\/span><\/p>\n

Dickinson E., Pastor F., Santana S.E.<\/strong> and Hartstone-Rose A. 2022. Functional and ecological correlates of the primate jaw abductors. The Anatomical Record <\/em>305(5): 1245-1263. PDF<\/a><\/span><\/p>\n

Leiser-Miller L.B.<\/strong> and Santana S.E.<\/strong> 2021. Functional differences in echolocation call design in an adaptive radiation of bats. Ecology and Evolution<\/em> 11(22): 16153-16164. PDF<\/a><\/span><\/p>\n

Santana S.E., Kaliszewska Z.A., Leiser-Miller L.B<\/strong>., Lauterbur M.E., Arbour J.H.<\/strong>, D\u00e1valos L.M. and Riffell J.A. 2021. Fruit odorants mediate co-specialization in a multispecies plant-animal mutualism. Proceedings of the Royal Society B: Biological Sciences <\/em>288: 20210312. <\/em>PDF<\/a><\/span><\/p>\n

Yohe L.R., Leiser-Miller L.B., Kaliszewska Z.A., <\/strong>Donat P., Santana S.E. <\/strong>and D\u00e1valos L.M. 2021. Diversity in olfactory receptor repertoires is associated with dietary specialization in a genus of frugivorous bat. G3 Genes|Genomes|Genetics<\/em> jkab260. PDF<\/a><\/span><\/p>\n

Higham T.E., Ferry L.A., Schmitz L., Irschick D.J., Starko S., Anderson P.S.L., Bergmann P.J., Jamniczky H.A., Monteiro L.R., Navon D., Messier J., Carrington E., Farina S.C., Feilich K.L., Hernandez L.P., Johnson M.A., Kawano S.M., Law C.J.<\/strong>, Longo S.J., Martin C.H., Martone P.T., Rico-Guevara A., Santana S.E.<\/strong>, Niklas S.E. 2021. Linking ecomechanical models and functional traits to understand phenotypic diversity. Trends in Ecology and Evolution <\/em>36(9): P860-873. PDF<\/a><\/span><\/p>\n

Esquivel D.A., Maestri R. and Santana S.E. <\/strong>2021. Evolutionary implications of dental anomalies in bats. Evolution <\/em>75(5): 1087\u20131096. PDF<\/a><\/span><\/p>\n

Arbour J.H.<\/strong>, Curtis A.A.<\/strong> and Santana S.E.<\/strong> 2021. Sensory adaptations reshaped intrinsic factors underlying morphological diversification in bats. BMC Biology<\/em> 19: 88. PDF<\/a><\/span><\/p>\n

Smith T.D., Curtis A.<\/strong>, Bhatnagar K.P. and Santana S.E.<\/strong>\u00a0 2021. Fissures, folds and scrolls: the ontogenetic basis for complexity of the nasal cavity in a fruit bat (Rousettus leschenaultii<\/em>). The Anatomical Record <\/em>304: 883\u2013900. PDF<\/a><\/span><\/p>\n

Sadier A., Santana S.E.<\/strong> and Sears K.E. 2020. The role of core and variable Gene Regulatory Network modules in tooth development and evolution. Integrative and Comparative Biology <\/em>icaa116. PDF<\/a><\/span><\/p>\n

Leiser-Miller L.<\/strong>, and Santana S.E.<\/strong> 2020. Morphological diversity in the sensory system of phyllostomid bats: implications for acoustic and dietary ecology. Functional Ecology <\/em>34: 1416\u20131427. PDF<\/a><\/span><\/p>\n

Leiser-Miller L., Kaliszewska Z.A.<\/strong>, Lauterbur E., Mann B.<\/strong>, Riffell J.A., and Santana S.E.<\/strong> 2020. A fruitful endeavor: scent cues and echolocation behavior used by Carollia castanea<\/em> to find fruit. Integrative Organismal Biology <\/em>2(1): obaa007. <\/em>PDF<\/a><\/span><\/p>\n

Curtis A.A.<\/strong>,Arbour J.H.<\/strong> and Santana S.E. <\/strong>2020. <\/strong>Mind the gap: natural cleft palates reduce biting performance in bats. Journal of Experimental Biology <\/em>223: jeb196535. <\/em>PDF<\/a><\/span><\/p>\n

Luo B., Leiser-Miller L<\/strong>., Santana S.E.<\/strong>, Zhang L., Liu T., Zhao J., Liu Y. and Feng J. 2019. Echolocation call divergence in bats: a comparative analysis. Behavioral Ecology and Sociobiology \u00a0<\/em>73: 15 . <\/em>PDF<\/a><\/span><\/p>\n

Mello M.A.R., Moreira Felix G., Barros Pereira Pinheiro R., Muylaert R.L., Geiselman C., Santana S.E.<\/strong>, Tschapka M., Lotfi N., Rodrigues F., and Stevens R.D. 2019. Insights on the assembly rules of a continent-wide multilayer network. Nature Ecology and Evolution\u00a0<\/em>3: 1525\u20131532. PDF<\/a><\/span><\/p>\n

Leiser-Miller L.<\/strong>, Kaliszewska Z.A.<\/strong>, Villalobos-Chaves D.<\/strong> and Santana S.E.<\/strong> 2019. A pygmy rice rat eats a peppery snack. Frontiers in Ecology and the Environment; EcoPics<\/em> 17(7): 369. PDF<\/a><\/span><\/p>\n

Vander Linden A., Campbell K., Bryar E.K. <\/strong>and Santana S.E.<\/strong> 2019. Head-turning morphologies: predictors of shape diversity in the mammalian atlas-axis complex. Evolution <\/em>73(10): 2060\u20132071. PDF<\/a><\/span><\/p>\n

Stanchak K.E.<\/strong>, Arbour J.H.<\/strong>, and Santana S.E.<\/strong> 2019. Anatomical diversification of a skeletal novelty in bat feet. Evolution <\/em>73(8): 1591\u20131603.<\/em> PDF<\/a><\/span><\/p>\n

Santana S.E., Arbour J.H., Curtis A.A. <\/strong>and Stanchak K.E.<\/strong> 2019. 3D digitization in functional morphology: Where is the point of diminishing returns? Integrative and Comparative Biology <\/em>59(3): 656\u2013668. <\/em>PDF<\/a><\/span><\/p>\n

Arbour J.H.<\/strong>, Curtis A.A.<\/strong> and Santana S.E.<\/strong> 2019. Arbour J.H., Curtis A.A. and Santana S.E. 2019. Signatures of echolocation and dietary ecology in the adaptive evolution of skull shape in bats. Nature Communications<\/em> 10: 2036. PDF<\/a><\/span><\/p>\n

Luo B., Santana S.E.<\/strong>, Pang Y., Wang M., Xiao Y., and Feng J. 2019. Wing morphology predicts geographic range size in vespertilionid bats. Scientific Reports<\/em> 9:4526. PDF<\/a><\/span><\/p>\n

Stanchak K.E.<\/strong> and Santana S.E.<\/strong> 2019. Do ecogeographical rules explain morphological variation in a diverse, Holarctic genus of small mammals? Journal of Biogeography\u00a0<\/em>46:110\u2013122. PDF<\/a><\/span><\/p>\n

Stone D., Lyons A.C., Huang Y.S., Vanlandingham D.L., Higgs S., Blitvich B.J., Adesiyun A.A., Santana S.E.<\/strong>, Leiser-Miller L.<\/strong>, and Cheetham S. 2018. Serological evidence of widespread exposure of Grenada fruit bats to chikungunya virus. Zoonoses and Public Health<\/em> 65(5): 505-511.\u00a0PDF<\/a><\/span><\/p>\n

Kelly R.M.<\/strong>, Friedman R.<\/strong> and Santana S.E.<\/strong> 2018. Primary productivity explains size variation across the Pallid bat\u2019s western geographic range. Functional Ecology <\/em>32:1520\u20131530.\u00a0PDF<\/a><\/span><\/p>\n

Stanchak K.E.<\/strong> and Santana, S.E.<\/strong> 2018. Assessment of the hindlimb membrane musculature of bats: implications for active control of the calcar. The Anatomical Record\u00a0<\/em>301:441-448. PDF<\/a><\/span><\/p>\n

Curtis A.A.<\/strong> and Santana S.E.<\/strong> 2018. Jaw-dropping: functional variation in the digastric muscle in bats. The Anatomical Record<\/em> 301: 279\u2013290. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong> 2018. Comparative anatomy of bat jaw musculature via Diffusible Iodine-Based Contrast-Enhanced Computed Tomography. The Anatomical Record<\/em> 301: 267\u2013278. PDF<\/a><\/span><\/p>\n

Hartstone-Rose and Santana S.E.<\/strong> 2018. Behavioral correlates of cranial muscle functional morphology. The Anatomical Record<\/em> 301: 197\u2013201. PDF<\/a><\/span><\/p>\n

Thiagavel J., Cechetto C., Santana S.E.<\/strong>, Jakobsen L., Warrant E.J. and Ratcliffe J.M.\u00a0 2018. Auditory opportunity and visual constraint enabled the evolution of echolocation in bats. Nature Communications<\/em> 9: 98. PDF<\/a><\/span><\/p>\n

Caro T., Walker H., Santana S.E.<\/strong> and Stankowich T. 2017. The evolution of anterior coloration in carnivorans. Behavioral Ecology and Sociobiology<\/em> 71: 177. PDF<\/a><\/span><\/p>\n

Campbell K.<\/strong> and Santana, S.E.<\/strong> 2017. Do differences in skull morphology and bite performance explain dietary specialization in sea otters? Journal of Mammalogy<\/em>.\u00a098(5): 1408\u20131416. PDF<\/a><\/span><\/p>\n

Ziegler U., Cheetam S., Santana S.E.<\/strong>, Miller L.<\/strong>, Matthew-Belmar V., Goharriz H. and Fooks A.R. 2017. Natural exposure of bats in Grenada to rabies virus. Infection Ecology and Epidemiology\u00a0<\/em>7:1, 1332935. PDF<\/a><\/span><\/p>\n

Diogo R. and Santana S.E.<\/strong> 2017. Evolution of facial musculature. In: Russel R. and Dols J.M.F. (eds.), The Science of Facial Expression<\/a><\/em>, Oxford University Press, Oxford, UK.<\/p>\n

Arbour J.H. <\/strong>and Santana S.E.<\/strong> 2017. A major shift in diversification rate helps explain macroevolutionary patterns in primate species diversity. Evolution\u00a0<\/em>71(6): 1600\u20131613. PDF<\/a><\/span><\/p>\n

Thiagavel J., Santana S.E.<\/strong> and Ratcliffe J. 2017. Body size predicts echolocation call peak frequency better than gape height in vespertilionid bats. Scientific Reports\u00a0<\/em>7:828. PDF<\/a><\/span><\/p>\n

Gignac P.M. and Santana S.E.<\/strong> 2016. A Bigger Picture: Organismal function at the nexus of development, ecology, and evolution. Integrative and Comparative Biology\u00a0<\/em>56(3): 369-372. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong> and Miller K.E. 2016. Extreme postnatal scaling in bat feeding performance: a view of ecomorphology from ontogenetic and macroevolutionary perspectives. Integrative and Comparative Biology\u00a0<\/em>56(3): 459-468.\u00a0PDF<\/a><\/span><\/p>\n

Santana S.E. <\/strong>and Cheung E.<\/strong> 2016. Go big or go fish: Morphological specializations in carnivorous bats. Proceedings of the Royal Society B: Biological Sciences <\/em>283: 20160615. PDF<\/a><\/span><\/p>\n

Linde M., Boughner J., Santana S.E.<\/strong> and Diogo R. 2016. Are more diverse parts of the mammalian skull more labile? Ecology and Evolution\u00a0<\/em>6(8):2318-2324. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong> 2016. Quantifying the effect of gape and morphology on bite force: biomechanical modeling and in vivo measurements in bats. Functional Ecology<\/em>\u00a030(4): 557-565. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>, Dobson S. and Diogo R. 2014. Plain faces are more expressive: comparative study of facial color, mobility and musculature in primates. Biology Letters<\/em> 10, 20140275. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>,\u00a0Lynch Alfaro J. W., Noonan A. and Alfaro M. 2013. Adaptive response to sociality and ecology drives the diversification of facial color patterns in catarrhines. Nature Communications<\/em> 4: 2765. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong> and Lofgren S. E. 2013. Does nasal echolocation influence the modularity of the mammal skull? Journal of Evolutionary Biology<\/em>\u00a026(11): 2520-2526. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>, Grosse I. and Dumont E.R. 2012. Dietary hardness, loading behavior and the evolution of skull form in bats. Evolution<\/em> 66 (8): 2587-2598. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>, Lynch Alfaro J. W. and Alfaro M. 2012. Adaptive evolution of facial colour patterns in Neotropical primates. Proceedings of the Royal Society B: Biological Sciences<\/em> 279 (1736): 2204-2211. PDF<\/a><\/span>
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Dumont E.R., D\u00e1valos L.M., Goldberg A.,\u00a0Santana S.E.<\/strong>,\u00a0Rex K. and Voigt C.C. 2012. Morphological innovation, diversification and the invasion of a new adaptive zone. Proceedings of the Royal Society B: Biological Sciences<\/em> 279 (1734): 1797-1805. PDF<\/a><\/span><\/p>\n

Santana S.E.<\/strong>,\u00a0Geipel I., Dumont E.R., Kalka M.B. and Kalko E.K.V. 2011. All you can eat: high performance capacity and plasticity of the common big-eared bat,\u00a0Micronycteris microtis<\/em>\u00a0(Chiroptera: Phyllostomidae). PLoS ONE\u00a0<\/em>6(12): e28584. PDF<\/a><\/span>
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Santana S.E.<\/strong>, Dial T.O., Eiting T. P. and Alfaro M.E. 2011. Roosting ecology and the evolution of pelage markings in bats.\u00a0PLoS ONE\u00a0<\/em>6(10): e25845. PDF<\/a><\/span>
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Santana S.E.<\/strong>, Strait S. and Dumont E.R. 2011. The better to eat you with: functional correlates of tooth structure in bats. Functional Ecology<\/em> 25: 839-847. PDF<\/a><\/span><\/p>\n

Santana S. E.<\/strong>\u00a0and Dumont E. R.. 2011. Do roost-excavating bats have stronger skulls? Biological Journal of the Linnean Society<\/em> 102 (1):1-10. PDF<\/a><\/span><\/p>\n

Santana S. E.<\/strong>, Dumont E. R. and Davis J. L. 2010. Mechanics of bite force production and its relationship to diet in bats. Functional Ecology<\/em> 24 (4): 776-784. PDF<\/a><\/span><\/p>\n

Davis J. L.,\u00a0Santana S. E.<\/strong>, Dumont E. R. and Grosse I. 2010. Predicting bite force in mammals: two-dimensional versus\u00a0<\/em>three-dimensional lever models. Journal of Experimental Biology<\/em> 213 (11):1844-1851. PDF<\/a><\/span><\/p>\n

Andersen J.C., Wu J., Gruwell M.E., Gwiazdowski R.,\u00a0Santana S.E.<\/strong>, Feliciano N.M., Morse G.E. and Normark B.B. 2010. A phylogenetic analysis of armored scale insects (Hemiptera: Diaspididae), based upon nuclear, mitochondrial, and endosymbiont gene sequences. Molecular Phylogenetics and Evolution<\/em> 57 (3):992-1003. PDF<\/span><\/a><\/p>\n

Santana S.E.<\/strong>\u00a0and Dumont E. R. 2009. Connecting behaviour and performance: The evolution of biting behaviour and bite performance in bats. Journal of Evolutionary Biology<\/em> 22 (11): 2131-2145. PDF<\/a><\/span><\/p>\n

Dechmann D.,\u00a0Santana S.E.\u00a0<\/strong>and Dumont E.R. 2009. Roost making in bats – adaptations for excavating active termite nests. Journal of Mammalogy<\/em> 90 (6): 1461-1468. PDF<\/a><\/span><\/p>\n

Dumont E. R., Herrel A., Medellin R. A., Vargas J. and\u00a0Santana S.E.<\/strong>\u00a02009. Built to bite: cranial design and function in the wrinkle faced bat (Centurio senex<\/em>). Journal of Zoology<\/em> 279 (4): 329-337. PDF<\/a><\/span><\/p>\n\n\n

<\/p>\n","protected":false},"excerpt":{"rendered":"

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