FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2029183890> ?p ?o ?g. }

• W2029183890 endingPage "224" @default.
• W2029183890 startingPage "215" @default.
• W2029183890 abstract "It was proposed that the power stroke in primates has two distinct periods of occlusal contact, each with a characteristic motion of the mandibular molars relative to the maxillary molars. The two movements are called phase I and phase II, and they occur sequentially in that order (Kay and Hiiemae [1974] Am J. Phys. Anthropol. 40:227–256, Kay and Hiiemae [1974] Prosimian Biology, Pittsburgh: University of Pittsburgh Press, p. 501–530). Phase I movement is said to be associated with shearing along a series of crests, producing planar phase I facets and crushing on surfaces on the basins of the molars. Phase I terminates in centric occlusion. Phase II movement is said to be associated with grinding along the same surfaces that were used for crushing at the termination of phase I. Hylander et al. ([1987] Am J. Phys. Anthropol. 72:287–312; see also Hiiemae [1984] Food Acquisition and Processing, London: Academic Press, p. 257–281; Hylander and Crompton [1980] Am J. Phys. Anthropol. 52:239–251, [1986] Arch. Oral. Biol. 31:841–848) analyzed data on macaques and suggested that phase II movement may not be nearly as significant for food breakdown as phase I movement simply because, based on the magnitude of mandibular bone strain patterns, adductor muscle and occlusal forces are likely negligible during movement out of centric occlusion. Our goal is to better understand the functional significance of phase II movement within the broader context of masticatory kinematics during the power stroke. We analyze vertical and transverse mandibular motion and relative activity of the masseter and temporalis muscles during phase I and II movements in Papio anubis. We test whether significant muscle activity and, by inference, occlusal force occurs during phase II movement. We find that during phase II movement, there is negligible force developed in the superficial and deep masseter and the anterior and posterior temporalis muscles. Furthermore, mandibular movements are small during phase II compared to phase I. These results suggest that grinding during phase II movement is of minimal importance for food breakdown, and that most food breakdown on phase II facets occurs primarily at the end of phase I movement (i.e., crushing during phase I movement). We note, however, that depending on the orientation of phase I facets, significant grinding also occurs along phase I facets during phase I. Am J Phys Anthropol, 2006. © 2005 Wiley-Liss, Inc." @default.
• W2029183890 created "2016-06-24" @default.
• W2029183890 creator A5029272728 @default.
• W2029183890 creator A5034525278 @default.
• W2029183890 creator A5057013950 @default.
• W2029183890 creator A5057881932 @default.
• W2029183890 creator A5078962062 @default.
• W2029183890 date "2006-02-01" @default.
• W2029183890 modified "2023-10-07" @default.
• W2029183890 title "Phase II jaw movements and masseter muscle activity during chewing inPapio anubis" @default.
• W2029183890 cites W1903768000 @default.
• W2029183890 cites W1911107452 @default.
• W2029183890 cites W1967361706 @default.
• W2029183890 cites W1981610192 @default.
• W2029183890 cites W2002381452 @default.
• W2029183890 cites W2025414715 @default.
• W2029183890 cites W2028970764 @default.
• W2029183890 cites W2029867109 @default.
• W2029183890 cites W2032382360 @default.
• W2029183890 cites W2033487770 @default.
• W2029183890 cites W2036619631 @default.
• W2029183890 cites W2038043763 @default.
• W2029183890 cites W2040540552 @default.
• W2029183890 cites W2042830339 @default.
• W2029183890 cites W2049953672 @default.
• W2029183890 cites W2050433338 @default.
• W2029183890 cites W2055326101 @default.
• W2029183890 cites W2070545065 @default.
• W2029183890 cites W2078222619 @default.
• W2029183890 cites W2096427188 @default.
• W2029183890 cites W2099915546 @default.
• W2029183890 cites W2145541011 @default.
• W2029183890 cites W2151491463 @default.
• W2029183890 cites W2477862234 @default.
• W2029183890 cites W40810164 @default.
• W2029183890 cites W65026509 @default.
• W2029183890 doi "https://doi.org/10.1002/ajpa.20290" @default.
• W2029183890 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/16278877" @default.
• W2029183890 hasPublicationYear "2006" @default.
• W2029183890 type Work @default.
• W2029183890 sameAs 2029183890 @default.
• W2029183890 citedByCount "56" @default.
• W2029183890 countsByYear W20291838902012 @default.
• W2029183890 countsByYear W20291838902013 @default.
• W2029183890 countsByYear W20291838902014 @default.
• W2029183890 countsByYear W20291838902015 @default.
• W2029183890 countsByYear W20291838902016 @default.
• W2029183890 countsByYear W20291838902017 @default.
• W2029183890 countsByYear W20291838902018 @default.
• W2029183890 countsByYear W20291838902019 @default.
• W2029183890 countsByYear W20291838902020 @default.
• W2029183890 countsByYear W20291838902021 @default.
• W2029183890 countsByYear W20291838902022 @default.
• W2029183890 countsByYear W20291838902023 @default.
• W2029183890 crossrefType "journal-article" @default.
• W2029183890 hasAuthorship W2029183890A5029272728 @default.
• W2029183890 hasAuthorship W2029183890A5034525278 @default.
• W2029183890 hasAuthorship W2029183890A5057013950 @default.
• W2029183890 hasAuthorship W2029183890A5057881932 @default.
• W2029183890 hasAuthorship W2029183890A5078962062 @default.
• W2029183890 hasConcept C105702510 @default.
• W2029183890 hasConcept C134018914 @default.
• W2029183890 hasConcept C154758884 @default.
• W2029183890 hasConcept C174093841 @default.
• W2029183890 hasConcept C193206974 @default.
• W2029183890 hasConcept C202271784 @default.
• W2029183890 hasConcept C2779594886 @default.
• W2029183890 hasConcept C2909888880 @default.
• W2029183890 hasConcept C29694066 @default.
• W2029183890 hasConcept C71924100 @default.
• W2029183890 hasConcept C86803240 @default.
• W2029183890 hasConceptScore W2029183890C105702510 @default.
• W2029183890 hasConceptScore W2029183890C134018914 @default.
• W2029183890 hasConceptScore W2029183890C154758884 @default.
• W2029183890 hasConceptScore W2029183890C174093841 @default.
• W2029183890 hasConceptScore W2029183890C193206974 @default.
• W2029183890 hasConceptScore W2029183890C202271784 @default.
• W2029183890 hasConceptScore W2029183890C2779594886 @default.
• W2029183890 hasConceptScore W2029183890C2909888880 @default.
• W2029183890 hasConceptScore W2029183890C29694066 @default.
• W2029183890 hasConceptScore W2029183890C71924100 @default.
• W2029183890 hasConceptScore W2029183890C86803240 @default.
• W2029183890 hasIssue "2" @default.
• W2029183890 hasLocation W20291838901 @default.
• W2029183890 hasLocation W20291838902 @default.
• W2029183890 hasOpenAccess W2029183890 @default.
• W2029183890 hasPrimaryLocation W20291838901 @default.
• W2029183890 hasRelatedWork W1988612711 @default.
• W2029183890 hasRelatedWork W2048038701 @default.
• W2029183890 hasRelatedWork W2086132793 @default.
• W2029183890 hasRelatedWork W2103152533 @default.
• W2029183890 hasRelatedWork W2130760193 @default.
• W2029183890 hasRelatedWork W2332983283 @default.
• W2029183890 hasRelatedWork W3097348660 @default.
• W2029183890 hasRelatedWork W3210811257 @default.
• W2029183890 hasRelatedWork W4214676561 @default.
• W2029183890 hasRelatedWork W4285741360 @default.
• W2029183890 hasVolume "129" @default.

• next