← Leaderboards
Marc Kantorow
West Virginia University
$8,325,279
Attributed
$10,784,839
Total exposure
3
Grants
2
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 $888.4K · FY2005–25$1M$750K$500K$250K$0
'05
'06
'07
'08
'09
'10
'11
'12
'13
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'22
'23
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'25
Funding mix
By agency
NIH$10,784,839 · 3
By mechanism
R01$10,784,839 · 3
Top collaborators
- A. Sue Menko10 shared
Most similar at West Virginia University
Same institution · by research overlap
- Peter H Mathers$1,840,620
Others in their field
Top investigators on “Crystallins”
- Jeffery Dill · Battelle Centers/Pub Hlth Res & Evaluatn$30,023,104
- Vincent H Crespi · Pennsylvania State Univ University Park$24,363,763
- Ales Cvekl · Yeshiva University$21,460,918
- Wah Chiu · Baylor College Of Medicine$21,410,530
- Nicholas L Abbott · University Of Wisconsin-Madison$20,535,652
- Michael F Rubner · Massachusetts Institute Of Technology$19,990,500
Research focus
CrystallinsLensProgramsProteinsCellsCataractEventLinkLens FiberTissuesRegulationPathway InteractionsEpithelial CellsFiber CellGenesOrganellesComplexMitochondriaExhibitsGene ExpressionPatternPlayMonitorEpithelium
Grant awards (30)
Hypoxia regulation of the lens$381,250
R01 · FY2025 · EY · contact PI
Regulatory role of PI3K signaling pathways in lens differentiation and function$582,440
R01 · FY2024 · EY
Regulatory role of PI3K signaling pathways in lens differentiation and function$518,305
R01 · FY2023 · EY
Hypoxia Regulation of the Lens$370,138
R01 · FY2023 · EY · contact PI
Regulatory role of PI3K signaling pathways in lens differentiation and function$502,755
R01 · FY2022 · EY
Hypoxia Regulation of the Lens$359,034
R01 · FY2022 · EY · contact PI
Regulatory role of PI3K signaling pathways in lens differentiation and function$502,755
R01 · FY2021 · EY
Hypoxia Regulation of the Lens$322,780
R01 · FY2021 · EY · contact PI
Regulatory role of PI3K signaling pathways in lens differentiation and function$532,305
R01 · FY2020 · EY
Hypoxia Regulation of the Lens$332,763
R01 · FY2020 · EY · contact PI
Repurposing classical death pathways for signaling roles in lens differentiation$542,130
R01 · FY2019 · EY
Hypoxia Regulation of the Lens$332,763
R01 · FY2019 · EY · contact PI
Repurposing classical death pathways for signaling roles in lens differentiation$542,130
R01 · FY2018 · EY
Repurposing classical death pathways for signaling roles in lens differentiation$542,130
R01 · FY2017 · EY
Repurposing classical death pathways for signaling roles in lens differentiation$100,000
R01 · FY2017 · EY
Repurposing classical death pathways for signaling roles in lens differentiation$554,170
R01 · FY2016 · EY
Molecular Analysis of Microdissected Human Lenses$329,460
R01 · FY2013 · EY · contact PI
Molecular Analysis of Microdissected Human Lenses$346,800
R01 · FY2012 · EY · contact PI
Molecular Analysis of Microdissected Human Lenses$346,800
R01 · FY2011 · EY · contact PI
Molecular Analysis of Microdissected Human Lenses$249,176
R01 · FY2010 · EY · contact PI
Molecular Analysis of Microdissected Cataractous Human Lenses$303,820
R01 · FY2009 · EY · contact PI
Mol. Anal. of Microdissected Cataractous Human Lenses$189,788
R01 · FY2009 · EY · contact PI
Molecular Analysis of Microdissected Cataractous Human Lenses$297,745
R01 · FY2008 · EY · contact PI
Molecular Analysis of Microdissected Cataractous Human Lenses$303,820
R01 · FY2007 · EY · contact PI
Mol. Anal. of Microdissected Cataractous Human Lenses$305,531
R01 · FY2006 · EY · contact PI
Mol. Anal. of Microdissected Cataractous Human Lenses$310,050
R01 · FY2005 · EY
MOLECULAR ANALY MICRODISSECTED CATARACTOUS HUMAN LENSES$202,219
R01 · FY2003 · EY
MOLECULAR ANALY MICRODISSECTED CATARACTOUS HUMAN LENSES$206,111
R01 · FY2002 · EY
MOLECULAR ANALY MICRODISSECTED CATARACTOUS HUMAN LENSES$190,612
R01 · FY2001 · EY
MOLECULAR ANALY MICRODISSECTED CATARACTOUS HUMAN LENSES$185,059
R01 · FY2000 · EY