grant

The Development of a Biatrial Catheter for a Cardiopulmonary Support System in Pulmonary Arterial Hypertension

Organization ICAHN SCHOOL OF MEDICINE AT MOUNT SINAILocation NEW YORK, UNITED STATESPosted 15 Sept 2023Deadline 31 Jul 2026
NIHUS FederalResearch GrantFY2025AcuteAddressAllelism TestAnimalsAortaArteriesAtrialBed restBedrestBiomechanicsBloodBlood Reticuloendothelial SystemBlood flowBrainBrain Nervous SystemCannulasCardiacCardiac AtriumCardiac OutputCardiopulmonaryCathetersCessation of lifeChronicChronic DiseaseChronic IllnessClinicClinicalComplementation TestComputer SimulationComputer based SimulationCoupledCustomDataDeathDevelopmentDevicesDiseaseDisorderDockingDysfunctionEncephalonEngineeringEventExtracorporeal Membrane OxygenationFunctional disorderFutureGasesGenerationsGenetic Complementation TestGoalsHeartHeart AtriumHeart failureHospitalsHourHypoxemiaIn VitroIn vivo analysisInequityInternal Jugular VeinInternal jugular vein structureLeftLeft AtriumLeft VentriclesLeft atrial structureLeft ventricular structureLower ExtremityLower LimbLung GraftingLung TransplantationMarketingMechanicsMedicalMembrum inferiusMonitorMorphologyOperative ProceduresOperative Surgical ProceduresOrganOrgan DonorOvineOvisOxygenatorsPatientsPerfusionPhysiopathologyPositionPositioning AttributeProcessPulmonary ArteryPulmonary EdemaPulmonary GraftPulmonary HypertensionPulmonary TransplantPulmonary TransplantationPulmonary artery structurePulmonary vesselsPumpRecoveryRefractoryResearch ResourcesResourcesRight AtriumRight VentriclesRight atrial structureRight ventricular structureRiskSeriesSheepShuntShunt DeviceSideSightSocial Support SystemSpecific qualifier valueSpecifiedSupport SystemSurgeonSurgicalSurgical InterventionsSurgical ProcedureSystemTestingTimeTrainingTrans TestTransplantationTreatment EfficacyValidationVenousVisionWaiting Listsatriumbench performance testingbench side testingbench testingbenchtop testingbiomechanicalcardiac failurecare costschronic disordercohortcomplementation analysiscomplementation approachcomputational simulationcomputer designcomputerized simulationcontinuous monitoringcustomsdesigndesigningdevelopmentaleffective therapyeffective treatmentfabricationheart outputhemodynamicshypoxemicimprovedin vivo evaluationin vivo testinginjury to the vasculatureinnovateinnovationinnovativeinstrumentintervention designintervention efficacylung artery blood pressurelung edemalung transplantlung vascular remodelingmechanicmechanicalmortalitynew drug treatmentsnew drugsnew pharmacological therapeuticnew therapeuticsnew therapynext generation therapeuticsnovelnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel therapeuticsnovel therapyoperationoperationsovine animal modelovine modelpathophysiologypatient responsepatient specific responsepharmacologicportabilitypressurepressure in pulmonary arteriespressure sensorpreventpreventingprototypepulmonarypulmonary arterial blood pressurepulmonary arterial hypertensionpulmonary arterial pressurepulmonary artery hypertensionpulmonary artery pressurepulmonary artery systolic pressurepulmonary vascular remodelingresponsive patientright heart failureright sided heart failureright ventricle failureright ventricular failureright ventricular heart failuresheep modelshuntssuccesssurgerytherapeutic efficacytherapy designtherapy efficacytime usetransplanttreatment designvalidationsvascular injuryvisual functionwaitlist
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Full Description

ABSTRACT
Pulmonary arterial hypertension continues to be a devastating chronic disease. Despite a variety of new
therapies, this disease process remains highly morbid and fatal. Most therapies are only temporizing and are
minimally effective because of the insidious onset and late recognition of this disease process. Double lung
transplantation is the only effective treatment; however, because of scarcity of organs and listing inequities, most
patients are unlikely to receive a transplant while on the waiting list. Developing an effective long-term support
system that can offload the right ventricle and protect the pulmonary vasculature would provide a bridge of
support and potential for recovery or management on pharmacological support. The objective and long-term
goal of this project is to design a catheter that will eventually be coupled with a pulmonary support system that
can prolong the survival and enhance the ability to medically treat patients with pulmonary artery hypertension,
as well as provide a chance for those on the lung transplant waiting list to receive an organ. We intend to
accomplish this by developing an innovative dual lumen catheter that can be positioned and fixed for a prolonged
period of time using a novel engineering mechanism and will properly unload the right ventricle and pulmonary
vasculature via an inter-atrial configuration. This will further include an innovative monitoring system to monitor
and control flows and protect a deconditioned left ventricle, preventing left sided heart failure.

Grant Number: 5R33HL163755-03
NIH Institute/Center: NIH
Principal Investigator: RAYMOND Benza

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