2023
X-linked hypophosphatemia in 4 generations due to an exon 13–15 duplication in PHEX, in the absence of the c.*231A>G variant
Soto Barros J, Sanchez S, Cabral K, Beggs A, Agrawal P, Genetti C, Brownstein C, Carpenter T. X-linked hypophosphatemia in 4 generations due to an exon 13–15 duplication in PHEX, in the absence of the c.*231A>G variant. Bone 2023, 172: 116763. PMID: 37059315, PMCID: PMC10198939, DOI: 10.1016/j.bone.2023.116763.Peer-Reviewed Original Research
2022
The efficacy and safety of burosumab in two patients with cutaneous skeletal hypophosphatemia syndrome
Sugarman J, Maruri A, Hamilton D, Tabatabai L, Luca D, Cimms T, Krolczyk S, Roberts M, Carpenter T. The efficacy and safety of burosumab in two patients with cutaneous skeletal hypophosphatemia syndrome. Bone 2022, 166: 116598. PMID: 36341949, DOI: 10.1016/j.bone.2022.116598.Peer-Reviewed Original ResearchConceptsCutaneous skeletal hypophosphatemia syndromeTumor-induced osteomalaciaBurosumab therapyDaily dosesMild injection site reactionsActive vitamin D analoguesExtra-cutaneous manifestationsMore daily dosesMultiple daily dosesSafety of burosumabTreatment of XLHDihydroxyvitamin D levelsInjection site reactionsCurrent treatment optionsLow serum phosphorusPromising therapeutic optionVitamin D analogsHuman monoclonal antibodyOral phosphorusAdult patientsAdverse eventsBone healthSerum phosphorusTherapeutic optionsD levels
2020
Long-Term Follow-up of Hypophosphatemic Bone Disease Associated With Elemental Formula Use: Sustained Correction of Bone Disease After Formula Change or Phosphate Supplementation
Eswarakumar AS, S. N, Ward LM, Backeljauw P, Wasserman H, Weber DR, DiMeglio LA, Imel EA, Gagne J, Cody D, Zimakas P, Topor LS, Agrawal S, Calabria A, Tebben P, Faircloth RS, Gordon R, Casey L, Carpenter TO. Long-Term Follow-up of Hypophosphatemic Bone Disease Associated With Elemental Formula Use: Sustained Correction of Bone Disease After Formula Change or Phosphate Supplementation. Clinical Pediatrics 2020, 59: 1080-1085. PMID: 32666808, DOI: 10.1177/0009922820941097.Peer-Reviewed Original ResearchConceptsElemental formula useBone diseaseFormula useHypophosphatemic bone diseaseTerm Follow-upLong-term outcomesSerum phosphorus concentrationSerum alkaline phosphatase activitySerum alkaline phosphataseSeverity/durationTime of correctionChart reviewSerum phosphorusDisease AssociatedFollow-upPhosphate supplementationExtent of recoveryDiseaseDiagnosisFormula changesRadiology reportsSupplementationAlkaline phosphataseAlkaline phosphatase activityReportEffects of Iron Isomaltoside vs Ferric Carboxymaltose on Hypophosphatemia in Iron-Deficiency Anemia
Wolf M, Rubin J, Achebe M, Econs MJ, Peacock M, Imel EA, Thomsen LL, Carpenter TO, Weber T, Brandenburg V, Zoller H. Effects of Iron Isomaltoside vs Ferric Carboxymaltose on Hypophosphatemia in Iron-Deficiency Anemia. JAMA 2020, 323: 432-443. PMID: 32016310, PMCID: PMC7042864, DOI: 10.1001/jama.2019.22450.Peer-Reviewed Original ResearchConceptsIron deficiency anemiaFerric carboxymaltoseIncidence of hypophosphatemiaIron isomaltosideDay 0Oral ironBone homeostasisCommon adverse drug reactionsFibroblast growth factor 23Trial ABiomarkers of mineralIntravenous iron isomaltosideRisk of hypophosphatemiaPrimary end pointReduced kidney functionGrowth factor 23Adverse drug reactionsIntravenous ironSerum phosphateFactor 23Kidney functionParathyroid hormoneRandomized trialsClinic sitesDrug reactions
2017
Unexpected widespread hypophosphatemia and bone disease associated with elemental formula use in infants and children
Ballesteros L, S. N, Gordon RJ, Ward L, Backeljauw P, Wasserman H, Weber DR, DiMeglio LA, Gagne J, Stein R, Cody D, Simmons K, Zimakas P, Topor LS, Agrawal S, Calabria A, Tebben P, Faircloth R, Imel EA, Casey L, Carpenter TO. Unexpected widespread hypophosphatemia and bone disease associated with elemental formula use in infants and children. Bone 2017, 97: 287-292. PMID: 28167344, PMCID: PMC5884631, DOI: 10.1016/j.bone.2017.02.003.Peer-Reviewed Original ResearchMeSH KeywordsAlkaline PhosphataseBone DiseasesCalciumChildChild, PreschoolFemaleHumansHypophosphatemiaInfantInfant FormulaMalePhosphorusRicketsConceptsElemental formula useFormula useSkeletal diseaseRetrospective chart reviewInadequate dietary intakeCertain clinical settingsFormula productsEffect of treatmentSevere malabsorptionChart reviewSevere hypocalcemiaClinical featuresClinical profileRenal excretionDietary intakeCommon findingMineral metabolismBone diseaseHypophosphatemiaPhosphate supplementationSkeletal radiographsCareful monitoringComplex illnessRenal conservationClinical setting
2016
Hypophosphatemia promotes lower rates of muscle ATP synthesis
Pesta DH, Tsirigotis DN, Befroy DE, Caballero D, Jurczak MJ, Rahimi Y, Cline GW, Dufour S, Birkenfeld AL, Rothman DL, Carpenter TO, Insogna K, Petersen KF, Bergwitz C, Shulman GI. Hypophosphatemia promotes lower rates of muscle ATP synthesis. The FASEB Journal 2016, 30: 3378-3387. PMID: 27338702, PMCID: PMC5024687, DOI: 10.1096/fj.201600473r.Peer-Reviewed Original ResearchConceptsMuscle ATP synthesisATP synthesisMuscle weaknessIsolated muscle mitochondriaSolute carrier familyWild-type littermate controlsSolute carrier family 34Carrier familyLower ratesInsulin-stimulated ratesMuscle mitochondriaChronic hypophosphatemiaHeart failureHypophosphatemic groupHypophosphatemic miceHypophosphatemiaLittermate controlsKnockout miceBlood PLow ratePlasma PPatientsSimilar findingsMember 1Plasma inorganic phosphate
2015
A Practical Clinical Approach to Paediatric Phosphate Disorders
Imel EA, Carpenter TO. A Practical Clinical Approach to Paediatric Phosphate Disorders. Endocrine Development 2015, 28: 134-161. PMID: 26138840, DOI: 10.1159/000381036.Peer-Reviewed Original ResearchConceptsPhosphate disordersPractical clinical approachChronic clinical conditionsPhosphate metabolismChronic hypophosphataemiaPhosphate abnormalitiesAppropriate therapyChronic disordersPathophysiologic assessmentClinical conditionsClinical approachPhosphate physiologyCareful evaluationHyperphosphataemiaHypophosphataemiaDisordersMetabolismPatientsTherapyEtiologyAbnormalitiesDisease
2009
Nuclear Isoforms of Fibroblast Growth Factor 2 Are Novel Inducers of Hypophosphatemia via Modulation of FGF23 and KLOTHO*
Xiao L, Naganawa T, Lorenzo J, Carpenter TO, Coffin JD, Hurley MM. Nuclear Isoforms of Fibroblast Growth Factor 2 Are Novel Inducers of Hypophosphatemia via Modulation of FGF23 and KLOTHO*. Journal Of Biological Chemistry 2009, 285: 2834-2846. PMID: 19933269, PMCID: PMC2807337, DOI: 10.1074/jbc.m109.030577.Peer-Reviewed Original ResearchAbsorptiometry, PhotonAnimalsCell NucleusFibroblast Growth Factor 2Fibroblast Growth Factor-23Fibroblast Growth FactorsGlucuronidaseHomeostasisHumansHypophosphatemiaIsomerismKidneyKlotho ProteinsMaleMiceMice, TransgenicMolecular WeightOsteoblastsOsteomalaciaPhenotypePhosphatesPromoter Regions, GeneticSkullSodium-Phosphate Cotransporter Proteins, Type IIaX-Ray Microtomography
2008
A translocation causing increased α-Klotho level results in hypophosphatemic rickets and hyperparathyroidism
Brownstein CA, Adler F, Nelson-Williams C, Iijima J, Li P, Imura A, Nabeshima Y, Reyes-Mugica M, Carpenter TO, Lifton RP. A translocation causing increased α-Klotho level results in hypophosphatemic rickets and hyperparathyroidism. Proceedings Of The National Academy Of Sciences Of The United States Of America 2008, 105: 3455-3460. PMID: 18308935, PMCID: PMC2265125, DOI: 10.1073/pnas.0712361105.Peer-Reviewed Original ResearchConceptsHypophosphatemic ricketsAlpha-KlothoExcessive renal lossPhosphate levelsParathyroid massRenal failureRenal osteodystrophyFGF23 levelsMajor complicationsParathyroid hyperplasiaKidney failureRenal lossBeta-glucuronidase activityNormal responseHyperparathyroidismEnergy homeostasisRicketsBone formationSkeletal abnormalitiesPhysiologic processesPhosphate homeostasisHyperphosphatemiaPatientsHyperplasiaBone defects
2005
Hypophosphatemia leads to rickets by impairing caspase-mediated apoptosis of hypertrophic chondrocytes
Sabbagh Y, Carpenter TO, Demay MB. Hypophosphatemia leads to rickets by impairing caspase-mediated apoptosis of hypertrophic chondrocytes. Proceedings Of The National Academy Of Sciences Of The United States Of America 2005, 102: 9637-9642. PMID: 15976027, PMCID: PMC1172249, DOI: 10.1073/pnas.0502249102.Peer-Reviewed Original ResearchConceptsParathyroid hormone levelsMineral ion homeostasisRachitic changesHormone levelsAbnormal mineral ion homeostasisDihydroxyvitamin D levelsVitamin D deficiencyDegree of hypophosphatemiaHypertrophic chondrocyte layerVitamin D receptorHypertrophic chondrocytesNormal phosphorus levelsGrowth plate maturationD deficiencyD levelsNormal calciumD receptorChondrocyte layerHypophosphatemiaVDR actionChondrocyte apoptosisNull miceRicketsCaspase-mediated apoptosisHypercalcemia
1998
Osteocalcin production in primary osteoblast cultures derived from normal and Hyp mice.
Carpenter T, Moltz K, Ellis B, Andreoli M, McCarthy T, Centrella M, Bryan D, Gundberg C. Osteocalcin production in primary osteoblast cultures derived from normal and Hyp mice. Endocrinology 1998, 139: 35-43. PMID: 9421395, DOI: 10.1210/endo.139.1.5677.Peer-Reviewed Original ResearchConceptsPrimary osteoblast culturesOsteoblast culturesRegulation of osteocalcinMessenger RNAMurine osteoblastsOsteocalcin productionOsteocalcin messenger RNASpecies-specific effectsPrimary murine osteoblastsMaturation-dependent fashionHyp mouse modelHyp miceMutant strainOsteoblast differentiationMurine cellsCultured cellsHYP culturesMurine culturesOsteoblastsRNACell viabilityPrimary culturesRegulationAltered responseNormal litter mates