2022
Cerebral arterial and ventricular morphology of the dogfish (Squalus acanthias), American bullfrog (Rana catesbeiana), and green iguana (Iguana iguana): Arterial high‐resolution micro‐CT, dissection, and radiography study
Kier E, Conlogue G, VanHouten J. Cerebral arterial and ventricular morphology of the dogfish (Squalus acanthias), American bullfrog (Rana catesbeiana), and green iguana (Iguana iguana): Arterial high‐resolution micro‐CT, dissection, and radiography study. The Anatomical Record 2022, 306: 2015-2029. PMID: 35778853, DOI: 10.1002/ar.25028.Peer-Reviewed Original ResearchConceptsMicro-CT imagesHigh-resolution micro-CTMicro-CTMicro-computed tomography (CT) imagingMicro-CT imagingArterial morphologyVenous cerebral circulationSequential displayGreen iguanasCerebral circulationVentricular morphologyRadiopaque contrastArterial circulationCorrosionArterial branchesVentricular systemRadiography studiesMorphologyArterial segmentsArterial structureAnatomic informationTomography imagingBrainArterial capillariesArterial network
2014
Evaluation of Cranial Bone Transport Distraction With and Without Adipose Grafting
Koch FP, Yuhasz MM, Travieso R, Wong K, Clune J, Zhuang ZW, Van Houten J, Steinbacher DM. Evaluation of Cranial Bone Transport Distraction With and Without Adipose Grafting. Journal Of Craniofacial Surgery 2014, 25: 766-771. PMID: 24820707, DOI: 10.1097/scs.0000000000000769.Peer-Reviewed Original ResearchComparing calvarial transport distraction with and without radiation and fat grafting
Yuhasz MM, Koch FP, Kwiatkowski A, Young C, Clune J, Travieso R, Wong K, Van Houten J, Steinbacher DM. Comparing calvarial transport distraction with and without radiation and fat grafting. Journal Of Cranio-Maxillofacial Surgery 2014, 42: 1412-1422. PMID: 24864072, DOI: 10.1016/j.jcms.2014.04.003.Peer-Reviewed Original ResearchConceptsNon-irradiated animalsFat graftingBone densityTransport distractionMale New Zealand white rabbitsNew Zealand white rabbitsZealand white rabbitsTransport distraction osteogenesisOsseous fillBony regenerateWhite rabbitsDistraction osteogenesisDistraction siteBone formationCranial reconstructionAnimalsOssificationCranial defectsGraftingDistractionChapter Seven Use of Osmium Tetroxide Staining with Microcomputerized Tomography to Visualize and Quantify Bone Marrow Adipose Tissue In Vivo
Scheller EL, Troiano N, VanHoutan JN, Bouxsein MA, Fretz JA, Xi Y, Nelson T, Katz G, Berry R, Church CD, Doucette CR, Rodeheffer MS, MacDougald OA, Rosen CJ, Horowitz MC. Chapter Seven Use of Osmium Tetroxide Staining with Microcomputerized Tomography to Visualize and Quantify Bone Marrow Adipose Tissue In Vivo. Methods In Enzymology 2014, 537: 123-139. PMID: 24480344, PMCID: PMC4097010, DOI: 10.1016/b978-0-12-411619-1.00007-0.Peer-Reviewed Original ResearchMeSH KeywordsAdipogenesisAdipose Tissue, WhiteBone MarrowCell DifferentiationHumansOsmium TetroxideStaining and LabelingStromal CellsX-Ray MicrotomographyConceptsStromal vascular fractionBone marrowAdipose tissueBone marrow adipose tissueWhite adipose tissue depotsMicrocomputerized tomographyAdipose tissue depotsMarrow recoveryDrug treatmentMedullary canalTissue depotsMetabolic diseasesVascular fractionStromal cellsMarrow fatEndothelial cellsAdipocyte progenitorsMature adipocytesLong bonesMAT volumeAdipocytesStainingOsmium tetroxide stainingHistochemical stainingConventional quantitation
2013
The remarkable migration of the medial collateral ligament
Wang M, Nasiri A, VanHouten JN, Tommasini SM, Broadus AE. The remarkable migration of the medial collateral ligament. Journal Of Anatomy 2013, 224: 490-498. PMID: 24266550, PMCID: PMC3954274, DOI: 10.1111/joa.12145.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsChondrocytesKnee JointMedial Collateral Ligament, KneeMiceOsteoclastsX-Ray MicrotomographyConceptsMedial collateral ligamentMigratory tractsCollateral ligamentParathyroid hormone-related proteinOsteoclastic bone resorptionHormone-related proteinCortical surfaceInsertions of tendonsInsertion siteBone resorptionLong bone growthPTHrP functionsOsteoclastic activityPeriosteal osteoclastsRegulatory moleculesOsteoblast activityGrowth spurtLong bonesOsteoclastsCortical boneLigamentRecent evidenceHistological techniquesBone surfaceTract
2011
Site‐specific changes in bone microarchitecture, mineralization, and stiffness during lactation and after weaning in mice
Liu XS, Ardeshirpour L, VanHouten JN, Shane E, Wysolmerski JJ. Site‐specific changes in bone microarchitecture, mineralization, and stiffness during lactation and after weaning in mice. Journal Of Bone And Mineral Research 2011, 27: 865-875. PMID: 22189918, DOI: 10.1002/jbmr.1503.Peer-Reviewed Original ResearchConceptsWhole bone stiffnessNulliparous miceBone microarchitectureTissue mineralizationBone mineral density BMDIndividual trabecula segmentationDramatic bone lossBone mineral densityBone stiffnessRecovered miceBone lossMineral densityPup weaningEffect of lactationMouse modelSkeletal sitesBone quantityClinical observationsMicro-finite element analysisBone qualitySite-specific changesSkeletal changesDigital topological analysisMiceCortical structures