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Aaron T Smith
Northwestern University
$3,289,380
Attributed
$3,643,433
Total exposure
5
Grants
5
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 $829.7K · FY2013–25$1M$750K$500K$250K$0
'13
'14
'15
'16
'17
'18
'19
'20
'21
'22
'23
'24
'25
Funding mix
By agency
NIH$3,643,433 · 5
By mechanism
R35$2,410,863 · 1
T32$708,106 · 2
R21$365,926 · 1
F32$158,538 · 1
Top collaborators
- Katherine L Radtke2 shared
- Steven Fletcher1 shared
Most similar at Northwestern University
Same institution · by research overlap
- Annelise Emily Barron$17,092,592
- Amy C Rosenzweig$16,295,619
- Brian M Hoffman$21,407,164
- Nicholas Philip Cianciotto$18,999,068
Others in their field
Top investigators on “Structure”
- David Heimbrook · Leidos Biomedical Research, Inc.$475,333,582
- Barton F Haynes · Duke University$444,977,767
- Lawrence Corey · Fred Hutchinson Cancer Center$334,646,086
- Gary D Acton · University Of California-Davis$320,373,312
- Mitchell J Malone · Texas A&M Research Foundation$320,373,312
- Michael David Hughes · Harvard University D/B/A Harvard School Of Public Health$315,257,203
Research focus
StructureBiochemicalProteinsEnzymesPathogenicityMediatingMolecularTherapeutic InterventionLinkVirulenceInsightBacteriaPathogenIronFutureTherapeutic DevelopmentInfectionResearch PersonnelNervous System DisorderNeurogenesisSmall MoleculeCardiovascular DiseasesHuman DiseasePositioning Attribute
Grant awards (19)
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$398,354
R35 · FY2025 · GM · contact PI
Graduate Training at The Chemistry Biology Interface$280,122
T32 · FY2025 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$280,589
R35 · FY2024 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$287,352
R35 · FY2023 · GM · contact PI
Graduate Training at The Chemistry Biology Interface$155,895
T32 · FY2023 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$11,784
R35 · FY2023 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$287,352
R35 · FY2022 · GM · contact PI
Graduate Training at The Chemistry Biology Interface$272,089
T32 · FY2022 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$199,540
R35 · FY2022 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$70,706
R35 · FY2022 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$287,352
R35 · FY2021 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$58,922
R35 · FY2021 · GM · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$264,032
R35 · FY2020 · GM · contact PI
FeoA-based Regulation of Pathogenic Ferrous Iron Acquisition$172,668
R21 · FY2020 · DE · contact PI
Deciphering the Mechanisms of Pathogenic Ferrous Iron Acquisition and Eukaryotic Post-Translational Arginylation$264,880
R35 · FY2019 · GM · contact PI
FeoA-based Regulation of Pathogenic Ferrous Iron Acquisition$193,258
R21 · FY2019 · DE · contact PI
Characterization of the P1B-5ATPase Hemerythrin-like and Metal-Binding Domains$56,042
F32 · FY2015 · GM · contact PI
Characterization of the P1B-5ATPase Hemerythrin-like and Metal-Binding Domains$53,282
F32 · FY2014 · GM · contact PI
Characterization of the P1B-5ATPase Hemerythrin-like and Metal-Binding Domains$49,214
F32 · FY2013 · GM · contact PI