← Leaderboards
Deborah M Muoio
Duke University
$18,719,990
Attributed
$25,325,448
Total exposure
10
Grants
7
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 $2M · 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$25,325,448 · 10
By mechanism
R01$23,018,338 · 6
P01$1,870,812 · 1
K01$377,583 · 1
F32$43,715 · 1
R13$15,000 · 1
Top collaborators
- Daniel Patrick Kelly12 shared
- Paul A. Grimsrud4 shared
- Paul B Rosenberg4 shared
Most similar at Duke University
Same institution · by research overlap
- Ashley Silberman Williams$694,464
- Paul B Rosenberg$6,076,972
- Chad A Grotegut$1,715,936
- Kathleen Anne Hershberger$73,126
- Kelsey Fisher-Wellman$129,799
Others in their field
Top investigators on “Mitochondria”
- Bruce M Spiegelman · Dana-Farber Cancer Inst$30,163,696
- Shi Du Yan · Columbia University Health Sciences$29,685,201
- Peipei Ping · University Of California Los Angeles$27,344,561
- Mary McGrae McDermott · Northwestern University$25,752,019
- Vamsi Krishna Mootha · Massachusetts General Hospital$23,004,991
- Kenneth D. Tew · Fox Chase Cancer Center$22,000,362
Research focus
MitochondriaMetabolicOxidationFatty AcidsTissuesCarbonMetabolomicsPhysiologicalStressGlucoseHomeostasisMuscleFunctional DisorderEnzymesEventLinkObesityMetabolismDiabetes MellitusHeartProteomicsResponseAgingBase
Grant awards (52)
Novel roles of PDK4 in regulating mitochondrial protein phosphorylation, carbon flux and metabolic resilience$634,926
R01 · FY2025 · DK · contact PI
Mechanisms of lipid-induced bioenergetic stress in muscle$632,687
R01 · FY2025 · DK · contact PI
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$700,832
R01 · FY2024 · HL · contact PI
Mechanisms of lipid-induced bioenergetic stress in muscle$632,687
R01 · FY2024 · DK · contact PI
Novel roles of PDK4 in regulating mitochondrial protein phosphorylation, carbon flux and metabolic resilience$617,385
R01 · FY2024 · DK · contact PI
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$719,480
R01 · FY2023 · HL
Novel roles of PDK4 in regulating mitochondrial protein phosphorylation, carbon flux and metabolic resilience$651,498
R01 · FY2023 · DK · contact PI
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$723,674
R01 · FY2022 · HL
Novel roles of PDK4 in regulating mitochondrial protein phosphorylation, carbon flux and metabolic resilience$660,100
R01 · FY2022 · DK · contact PI
Mechanisms of lipid-induced bioenergetic stress in muscle$589,999
R01 · FY2022 · DK · contact PI
FASEB SRC: The Molecular Metabolism Conference: From Cell Biology to Systems Physiology$15,000
R13 · FY2022 · DK · contact PI
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$743,357
R01 · FY2021 · HL
Mechanisms of lipid-induced bioenergetic stress in muscle$589,999
R01 · FY2021 · DK · contact PI
Mechanisms of lipid-induced bioenergetic stress in muscle$589,999
R01 · FY2020 · DK · contact PI
STIM1 and metabolic flexibility$575,706
R01 · FY2020 · DK
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$713,632
R01 · FY2019 · HL
Mechanisms of lipid-induced bioenergetic stress in muscle$602,749
R01 · FY2019 · DK · contact PI
STIM1 and metabolic flexibility$575,706
R01 · FY2019 · DK
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$722,090
R01 · FY2018 · HL
STIM1 and metabolic flexibility$575,706
R01 · FY2018 · DK
Role of Carnitine Acetyltransferase in Mitochondrial and Metabolic Function$495,874
R01 · FY2018 · DK · contact PI
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$622,524
R01 · FY2017 · HL
STIM1 and metabolic flexibility$575,706
R01 · FY2017 · DK
Role of Carnitine Acetyltransferase in Mitochondrial and Metabolic Function$498,736
R01 · FY2017 · DK · contact PI
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$247,089
R01 · FY2017 · HL
Probing the Role of Mitochondrial Short-chain Carbon Homeostasis in the Hypertrophied and Failing Heart$925,193
R01 · FY2016 · HL
Role of Carnitine Acetyltransferase in Mitochondrial and Metabolic Function$498,736
R01 · FY2016 · DK · contact PI
Mitochondrial Stress and Metabolic dysfunction Skeletal Muscle$376,800
P01 · FY2016 · DK · contact PI
Role of Carnitine Acetyltransferase in Mitochondrial and Metabolic Function$497,204
R01 · FY2015 · DK · contact PI
Mitochondrial Stress and Metabolic dysfunction Skeletal Muscle$376,800
P01 · FY2015 · DK · contact PI
Mitochondrial Stress and Metabolic dysfunction Skeletal Muscle$376,800
P01 · FY2014 · DK · contact PI
A Genomic/Metabolomic Strategy to Characterize Cardiac Mitochondrial Dysfunction$691,570
R01 · FY2013 · HL
Mitochondrial Stress and Metabolic dysfunction Skeletal Muscle$363,612
P01 · FY2013 · DK · contact PI
Carnitine Acetyltransferase in Defending Mitochondrial and Metabolic Function$340,791
R01 · FY2013 · DK · contact PI
A Genomic/Metabolomic Strategy to Characterize Cardiac Mitochondrial Dysfunction$727,018
R01 · FY2012 · HL
Mitochondrial Stress and Metabolic dysfunction Skeletal Muscle$376,800
P01 · FY2012 · DK · contact PI
Carnitine Acetyltransferase in Defending Mitochondrial and Metabolic Function$353,155
R01 · FY2012 · DK · contact PI
A Genomic/Metabolomic Strategy to Characterize Cardiac Mitochondrial Dysfunction$727,580
R01 · FY2011 · HL
Carnitine Acetyltransferase in Defending Mitochondrial and Metabolic Function$353,149
R01 · FY2011 · DK · contact PI
A Genomic/Metabolomic Strategy to Characterize Cardiac Mitochondrial Dysfunction$780,976
R01 · FY2010 · HL
Role of Carnitine Acetyltransferase in Defending Mitochondrial and Metabolic Func$449,617
R01 · FY2010 · DK · contact PI
Mechanisms linking the adipogenic phenotype of aging muscle to insulin resistance$361,491
R01 · FY2010 · AG · contact PI
Mechanisms linking the adipogenic phenotype of aging muscle to insulin resistance$365,143
R01 · FY2009 · AG · contact PI
Mechanisms linking the adipogenic phenotype of aging muscle to insulin resistance$152,052
R01 · FY2009 · AG · contact PI
Mechanisms linking the adipogenic phenotype of aging muscle to insulin resistance$365,143
R01 · FY2008 · AG · contact PI
Mechanisms linking the adipogenic phenotype of aging muscle to insulin resistance$363,427
R01 · FY2007 · AG · contact PI
Mechanisms linking the adipogenic phenotype of aging muscle to insulin resistance$373,952
R01 · FY2006 · AG · contact PI
Ketone Dysregulation and Muscle Insulin Resistance$125,861
K01 · FY2006 · DK · contact PI
Ketone Dysregulation and Muscle Insulin Resistance$125,861
K01 · FY2005 · DK
Ketone Dysregulation and Muscle Insulin Resistance$125,861
K01 · FY2004 · DK
UNCOUPLING PROTEIN 3 AND MUSCLE SUBSTRATE UTILIZATION$11,299
F32 · FY2001 · DK
UNCOUPLING PROTEIN 3 AND MUSCLE SUBSTRATE UTILIZATION$32,416
F32 · FY2000 · DK