← Leaderboards
Steven D Schwartz
Albert Einstein Col Of Med Yeshiva Univ
$10,209,375
Attributed
$14,192,809
Total exposure
7
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 $1.5M · FY2005–25$2M$1.5M$1M$500K$0
'05
'06
'07
'08
'09
'10
'11
'12
'13
'14
'15
'16
'17
'18
'19
'20
'21
'22
'23
'24
'25
Funding mix
By agency
NIH$14,192,809 · 7
By mechanism
R01$9,355,644 · 3
P01$2,992,115 · 2
R35$1,450,270 · 1
R21$394,780 · 1
Top collaborators
- Jil C Tardiff17 shared
Others in their field
Top investigators on “Proteins”
- David Heimbrook · Leidos Biomedical Research, Inc.$354,061,551
- Randall J Bateman · Washington University$187,292,085
- Paul S. Aisen · Cognition Therapeutics, Inc.$175,382,342
- Reisa A. Sperling · Banner Health$145,046,481
- Barton F Haynes · Duke University$136,029,850
- Joseph L Goldstein · University Of Texas Sw Med Ctr/Dallas$102,433,280
Research focus
ProteinsProgramsProtein DynamicsCoupledMutationStructureSamplingChemistrySuccessEnzymesKineticsBiologicalMotionMolecularComplexDesignGenerationsCatalysisExperimental StudyReactionIn VitroCatalystCardiacCell Motility
Grant awards (39)
Protein dynamics from femtoseconds to milliseconds as crafted by natural and laboratory evolution: towards enzyme design$378,126
R35 · FY2025 · GM · contact PI
Protein dynamics from femtoseconds to milliseconds as crafted by natural and laboratory evolution: towards enzyme design$378,126
R35 · FY2024 · GM · contact PI
The interaction of myosin and the thin filament: how mutations cause allosteric dysfunction and their connection to genetic cardiomyopathy$537,089
R01 · FY2023 · HL
Protein dynamics from femtoseconds to milliseconds as crafted by natural and laboratory evolution: towards enzyme design$378,126
R35 · FY2023 · GM · contact PI
The interaction of myosin and the thin filament: how mutations cause allosteric dysfunction and their connection to genetic cardiomyopathy$537,089
R01 · FY2022 · HL
Protein dynamics from femtoseconds to milliseconds as crafted by natural and laboratory evolution: towards enzyme design$315,892
R35 · FY2022 · GM · contact PI
Rapid protein dynamics and catalysis: modulation by laboratory evolution, designed mutation, and protein control of electric field environment$297,047
R01 · FY2022 · GM · contact PI
The interaction of myosin and the thin filament: how mutations cause allosteric dysfunction and their connection to genetic cardiomyopathy$537,089
R01 · FY2021 · HL
A New Paradigm to Incorporate Protein Dynamics into Targeted Small Molecule Design for Sarcomeric Cardiomyopathies: A Proof of Concept for Thin Filament Therapeutics$465,498
R01 · FY2021 · HL
Rapid protein dynamics and catalysis: modulation by laboratory evolution, designed mutation, and protein control of electric field environment$297,500
R01 · FY2021 · GM · contact PI
The interaction of myosin and the thin filament: how mutations cause allosteric dysfunction and their connection to genetic cardiomyopathy$585,711
R01 · FY2020 · HL
A New Paradigm to Incorporate Protein Dynamics into Targeted Small Molecule Design for Sarcomeric Cardiomyopathies: A Proof of Concept for Thin Filament Therapeutics$499,268
R01 · FY2020 · HL
Rapid protein dynamics and catalysis: modulation by laboratory evolution, designed mutation, and protein control of electric field environment$297,920
R01 · FY2020 · GM · contact PI
Computation to animal: thin filament mutations and genetic cardiomyopathy$534,913
R01 · FY2019 · HL
A New Paradigm to Incorporate Protein Dynamics into Targeted Small Molecule Design for Sarcomeric Cardiomyopathies: A Proof of Concept for Thin Filament Therapeutics$490,058
R01 · FY2019 · HL
Rapid protein dynamics and catalysis: modulation by laboratory evolution, designed mutation, and protein control of electric field environment$298,308
R01 · FY2019 · GM · contact PI
Rapid protein dynamics and catalysis: modulation by laboratory evolution, designed mutation, and protein control of electric field environment$198,000
R01 · FY2019 · GM · contact PI
Computation to animal: thin filament mutations and genetic cardiomyopathy$485,793
R01 · FY2018 · HL
A New Paradigm to Incorporate Protein Dynamics into Targeted Small Molecule Design for Sarcomeric Cardiomyopathies: A Proof of Concept for Thin Filament Therapeutics$482,383
R01 · FY2018 · HL
Enzyme design and protein dynamics.$307,518
P01 · FY2018 · GM · contact PI
Computation to animal: thin filament mutations and genetic cardiomyopathy$475,048
R01 · FY2017 · HL
Enzyme design and protein dynamics.$382,763
P01 · FY2017 · GM · contact PI
Computation to animal: thin filament mutations and genetic cardiomyopathy$474,677
R01 · FY2016 · HL
Enzyme design and protein dynamics.$382,763
P01 · FY2016 · GM · contact PI
Enzyme design and protein dynamics.$382,763
P01 · FY2015 · GM · contact PI
A molecular study linking cTnT dynamics to genetic cardiomyopathy$364,196
R01 · FY2015 · HL
Enzyme design and protein dynamics.$256,164
P01 · FY2015 · GM · contact PI
Enzyme design and protein dynamics.$399,513
P01 · FY2014 · GM · contact PI
A molecular study linking cTnT dynamics to genetic cardiomyopathy$362,348
R01 · FY2014 · HL
A molecular study linking cTnT dynamics to genetic cardiomyopathy$332,769
R01 · FY2013 · HL
Quantum Nuclear Dynamics and Enzyme Chemistry$212,371
R21 · FY2013 · GM · contact PI
A molecular study linking cTnT dynamics to genetic cardiomyopathy$401,800
R01 · FY2012 · HL
Quantum Nuclear Dynamics and Enzyme Chemistry$182,409
R21 · FY2012 · GM · contact PI
A molecular study linking cTnT dynamics to genetic cardiomyopathy$401,140
R01 · FY2011 · HL
Promoting Vibrations in LDH and PNP$219,777
P01 · FY2008 · GM · contact PI
Promoting Vibrations in LDH and PNP$219,833
P01 · FY2007 · GM · contact PI
Promoting Vibrations in LDH and PNP$134,152
P01 · FY2006 · GM · contact PI
Promoting Vibrations in LDH and PNP$130,303
P01 · FY2005 · GM
Promoting Vibrations in LDH and PNP$176,566
P01 · FY2004 · GM