2020
Minimally Invasive Image-Guided Ablation, Osteoplasty, Reinforcement, and Internal Fixation (AORIF) for Osteolytic Lesions in the Pelvis and Periarticular Regions of Weight-Bearing Bones
Lee FY, Latich I, Toombs C, Mungur A, Conway D, Alder K, Ibe I, Lindskog D, Friedlaender G. Minimally Invasive Image-Guided Ablation, Osteoplasty, Reinforcement, and Internal Fixation (AORIF) for Osteolytic Lesions in the Pelvis and Periarticular Regions of Weight-Bearing Bones. Journal Of Vascular And Interventional Radiology 2020, 31: 649-658.e1. PMID: 32139256, DOI: 10.1016/j.jvir.2019.11.029.Peer-Reviewed Original ResearchMeSH KeywordsAblation TechniquesAdultAgedAged, 80 and overBone CementsBone NeoplasmsBone RemodelingBone ScrewsCalcaneusCementoplastyFemaleFemoral NeoplasmsFemurFracture Fixation, InternalHumansMaleMiddle AgedOsteolysisPelvic BonesPostoperative ComplicationsProspective StudiesRecovery of FunctionTibiaTime FactorsTreatment OutcomeWeight-BearingConceptsOsteolytic lesionsInternal fixationVisual analog scale pain scoreMusculoskeletal Tumor Society scoreProspective clinical cohort studyFunctional ambulation scoreOsteolytic skeletal lesionsPainful osteolytic lesionsScale pain scoresClinical cohort studyInvasive percutaneous approachWeight-bearing boneInternal fixation screwsBalloon osteoplastyPain scoresCohort studyProphylactic stabilizationSevere painSociety ScoreConsecutive patientsSurgical treatmentEarly outcomesTreatment optionsPercutaneous approachFunctional improvement
1991
Postfracture irradiation effects on the biomechanical and histologic parameters of fracture healing
Brown R, Pelker R, Friedlaender G, Peschel R, Panjabi M. Postfracture irradiation effects on the biomechanical and histologic parameters of fracture healing. Journal Of Orthopaedic Research® 1991, 9: 876-882. PMID: 1919851, DOI: 10.1002/jor.1100090614.Peer-Reviewed Original ResearchConceptsFracture healingControl fracturesDelay groupMature Sprague-Dawley ratsClosed femoral fracturesLong-term resultsSprague-Dawley ratsContralateral intact femurFemoral fracturesHistologic parametersLocal irradiationFracture repairFractured femurRadiation exposureWeeksIntact femurBiomechanical propertiesRatsDeleterious effectsShort-term deleterious effectsFemurDaysFracturesHealingGroup
1985
Effects of short‐term Cyclosporin‐A on biomechanical properties of intact and fractured bone in the rat
Warren S, Pelker R, Friedlaender G. Effects of short‐term Cyclosporin‐A on biomechanical properties of intact and fractured bone in the rat. Journal Of Orthopaedic Research® 1985, 3: 96-100. PMID: 3981300, DOI: 10.1002/jor.1100030112.Peer-Reviewed Original ResearchConceptsControl animalsSolid organ allograft survivalFracture repairCurrent biomechanical dataOrgan allograft survivalShort-term cyclosporinBiomechanical propertiesSolid organ transplantationEffect of cyclosporinShort-term clinical useMidshaft femoral fractureNew immunosuppressant drugsAllograft survivalFemoral fracturesBone turnoverRat modelSkeletal toxicityOrgan transplantationSystemic effectsHistomorphometric studyImmunosuppressant drugsIntramedullary pinBiologic effectsFractured femurCyclosporinChemotherapy‐induced alterations in the biomechanics of rat bone
Pelker R, Friedlaender G, Panjabi M, Markham T, Hausman M, Doganis A, McKay J. Chemotherapy‐induced alterations in the biomechanics of rat bone. Journal Of Orthopaedic Research® 1985, 3: 91-95. PMID: 3981299, DOI: 10.1002/jor.1100030111.Peer-Reviewed Original Research
1984
Radiation‐induced alterations of fracture healing biomechanics
Pelker R, Friedlaender G, Panjabi M, Kapp D, Doganis A. Radiation‐induced alterations of fracture healing biomechanics. Journal Of Orthopaedic Research® 1984, 2: 90-96. PMID: 6491804, DOI: 10.1002/jor.1100020114.Peer-Reviewed Original Research