← Leaderboards
Narutoshi Hibino
Johns Hopkins University
$4,913,357
Attributed
$9,589,697
Total exposure
7
Grants
4
Lead (contact PI)
Attributed= this PI's even-split share of every grant they're on (the fair, additive number). Exposure = full size of all those grants.
Funding over time
peak $1.6M · FY2017–25$2M$1.5M$1M$500K$0
'17
'18
'19
'20
'21
'22
'23
'24
'25
Funding mix
By agency
NIH$9,589,697 · 7
By mechanism
R01$7,209,559 · 4
R33$1,236,013 · 1
R56$660,201 · 1
R21$483,924 · 1
Top collaborators
- Axel Krieger9 shared
- Mark Fuge4 shared
- Bozhi Tian3 shared
- Laura Ensign2 shared
- Manami Hara2 shared
Most similar at Johns Hopkins University
Same institution · by research overlap
- David Alan Kass$45,555,857
- Ronald A Li$3,886,490
- Natalia A. Trayanova$20,674,312
- Gordon Frank Tomaselli$21,784,029
- Jennifer E Van Eyk$35,842,385
Others in their field
Other Emerging Leaders on “Operative Surgical Procedures”
- Sonia M Thomas · Research Triangle Institute$701,865,642
- Tracy L Nolen · Research Triangle Institute$474,487,152
- Leonard Freedman · Leidos Biomedical Research, Inc.$63,381,339
- Leonard Freedmand · Leidos Biomedical Research, Inc.$52,916,621
- Craig Reist · Research Triangle Institute$22,725,934
- Lisa Newman · Research Triangle Institute$22,725,934
Research focus
Operative Surgical ProceduresBlood VesselsTechnologyAnimalsIn VivoStructureTissuesMorbidity - Disease RateVascular GraftGrowthIn VitroReconstructionEnsureNanofiberAnatomySheepMetalsPerformanceCardiovascular SystemDesignPhysiologicalLeadSurgery OutcomeComplex
Grant awards (19)
Blood flow crosstalk between the endocrine and exocrine pancreas$762,046
R01 · FY2025 · DK
Multi-site photostimulation devices using porosity-based semiconductor heterojunctions for cardiac resynchronization therapy$588,164
R01 · FY2025 · EB
Blood flow crosstalk between the endocrine and exocrine pancreas$764,894
R01 · FY2024 · DK
Multi-site photostimulation devices using porosity-based semiconductor heterojunctions for cardiac resynchronization therapy$606,609
R01 · FY2024 · EB
Nanoporous semiconductor-enabled multi-site photostimulation for cardiac resynchronization therapy$660,201
R56 · FY2023 · EB
Novel drug-eluting sutures to prevent vascular graft anastomosis stenosis$310,420
R01 · FY2022 · HL · contact PI
Patient specific 3D printed tissue engineered vascular graft for aortic reconstruction designed by artificial intelligence algorithm.$643,908
R01 · FY2021 · HL · contact PI
Patient Specific Tissue Engineered Vascular Graft Creation Using 3D Printing Technology$372,963
R33 · FY2021 · HD · contact PI
Novel drug-eluting sutures to prevent vascular graft anastomosis stenosis$310,420
R01 · FY2021 · HL · contact PI
Patient specific 3D printed tissue engineered vascular graft for aortic reconstruction designed by artificial intelligence algorithm.$568,300
R01 · FY2020 · HL · contact PI
Patient Specific Tissue Engineered Vascular Graft Creation Using 3D Printing Technology$424,178
R33 · FY2020 · HD · contact PI
Novel drug-eluting sutures to prevent vascular graft anastomosis stenosis$325,920
R01 · FY2020 · HL · contact PI
Patient specific 3D printed tissue engineered vascular graft for aortic reconstruction designed by artificial intelligence algorithm.$734,159
R01 · FY2019 · HL · contact PI
Patient Specific Tissue Engineered Vascular Graft Creation Using 3D Printing Technology$438,872
R33 · FY2019 · HD · contact PI
Novel drug-eluting sutures to prevent vascular graft anastomosis stenosis$409,375
R01 · FY2019 · HL · contact PI
Patient specific 3D printed tissue engineered vascular graft for aortic reconstruction designed by artificial intelligence algorithm.$776,125
R01 · FY2018 · HL · contact PI
Novel drug-eluting sutures to prevent vascular graft anastomosis stenosis$409,219
R01 · FY2018 · HL · contact PI
Patient Specific Tissue Engineered Vascular Graft Creation Using 3D Printing Technology$232,455
R21 · FY2018 · HD · contact PI
Patient Specific Tissue Engineered Vascular Graft Creation Using 3D Printing Technology$251,469
R21 · FY2017 · HD · contact PI