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Prosenjit Bagchi
Rutgers, The State Univ Of N.J.
$2,025,307
Attributed
$3,127,838
Total exposure
2
Grants
1
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 $1.3M · FY2021–25$2M$1.5M$1M$500K$0
'21
'22
'23
'24
'25
Funding mix
By agency
NIH$3,127,838 · 2
By mechanism
R01$3,127,838 · 2
Top collaborators
- Pingnian He2 shared
- Yongsoo Kim2 shared
Most similar at Rutgers, The State Univ Of N.J.
Same institution · by research overlap
- Christopher Eugene Ellison$5,027,509
- Kevin Tong$1,076,351
- Gutian Xiao$5,239,926
- Loredana Quadro$4,454,114
- Ioannis P Androulakis$1,559,773
Others in their field
Other Emerging Leaders on “In Silico”
- Leonard Freedman · Leidos Biomedical Research, Inc.$15,756,756
- Crystal Mackall · Children'S Hosp Of Philadelphia$10,785,733
- Feixiong Cheng · Cleveland Clinic Lerner Com-Cwru$5,423,704
- Michael Daniel Keller · Children'S Research Institute$4,910,377
- Matthew C. Altman · Benaroya Research Inst At Virginia Mason$4,720,035
- Steven H Olson · Sanford Burnham Prebys Medical Discovery Institute$4,671,820
Research focus
In SilicoBlood VesselsHemodynamicsEndothelial CellsBlood Cells3-DimensionalBlood FlowErythrocytesInsightIn VivoImpairmentClinical TreatmentComputer ModelsComplexCouplingClinical DiagnosisDiabeticDiabetic RetinopathyBlindnessAppearanceBiophysicsBloodBlood CapillariesBiophysical Properties
Grant awards (7)
Mechanisms of cognitive impairment caused by atherosclerosis and red blood cell released ATP$818,509
R01 · FY2025 · NS
Mechanisms of cognitive impairment caused by atherosclerosis and red blood cell released ATP$835,288
R01 · FY2024 · NS
Development and application of a high-fidelity computational model of diabetic retinopathy hemodynamics: Coupling single-cell biophysics with retinal vascular network topology and complexity$337,450
R01 · FY2024 · EY · contact PI
Development and application of a high-fidelity computational model of diabetic retinopathy hemodynamics: Coupling single-cell biophysics with retinal vascular network topology and complexity$131,000
R01 · FY2024 · EY · contact PI
Development and application of a high-fidelity computational model of diabetic retinopathy hemodynamics: Coupling single-cell biophysics with retinal vascular network topology and complexity$337,450
R01 · FY2023 · EY · contact PI
Development and application of a high-fidelity computational model of diabetic retinopathy hemodynamics: Coupling single-cell biophysics with retinal vascular network topology and complexity$316,825
R01 · FY2022 · EY · contact PI
Development and application of a high-fidelity computational model of diabetic retinopathy hemodynamics: Coupling single-cell biophysics with retinal vascular network topology and complexity$351,316
R01 · FY2021 · EY · contact PI