← Leaderboards
Eben Alsberg
Cleveland Clinic Lerner Com-Cwru
$6,769,050
Attributed
$9,736,961
Total exposure
10
Grants
9
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 · FY2012–25$2M$1.5M$1M$500K$0
'12
'13
'14
'15
'16
'17
'18
'19
'20
'21
'22
'23
'24
'25
Funding mix
By agency
NIH$9,736,961 · 8
VA$0 · 2
By mechanism
R01$8,615,493 · 5
R21$775,499 · 2
R56$345,969 · 1
I01$0 · 2
Top collaborators
- Ali Khademhosseini6 shared
- Marsha W Rolle4 shared
- Oju Jeon3 shared
- Robert Tracy Ballock2 shared
- Allen Po-Chih Liu2 shared
Others in their field
Top investigators on “Defect”
- Lawrence Corey · Fred Hutchinson Cancer Center$207,121,712
- Margaret Juliana McElrath · Fred Hutchinson Cancer Center$110,264,229
- William George Nelson · Johns Hopkins University$80,153,436
- John A Tainer · Scripps Research Institute$73,493,996
- Stacey Gabriel · Massachusetts Institute Of Technology$48,168,194
- Steven G. Self · Fred Hutchinson Cancer Research Center$43,947,468
Research focus
DefectTissuesCellsIn VivoTissue EngineeringMesenchymal Stem CellsEngineeringAffectCartilageMechanicsTechnologyHealingGrowth FactorOryctolagus CuniculusHydrogelsBiocompatible MaterialsScaffoldDesignBiochemicalRepairedChondrogenesisNatural RegenerationSourceCrosslink
Grant awards (35)
Individual cell bioprinting to generate multi-tissue type condensations for osteochondral tissue regeneration$391,536
R01 · FY2025 · AR · contact PI
In situ bioprinting of high-density cell-laden core-shell microgel bioinks enabling cellular condensation for vascularized bone tissue regeneration$0
I01 · FY2025 · VA · contact PI
Multi-tissue type condensations for trachea tissue regeneration via individual cell bioprinting$0
I01 · FY2025 · VA · contact PI
Individual cell bioprinting to generate multi-tissue type condensations for osteochondral tissue regeneration$391,536
R01 · FY2024 · AR · contact PI
In situ bioprinting of high-density cell-laden core-shell microgel bioinks enabling cellular condensation for vascularized bone tissue regeneration$0
I01 · FY2024 · VA · contact PI
Multi-tissue type condensations for trachea tissue regeneration via individual cell bioprinting$0
I01 · FY2024 · VA · contact PI
Individual cell bioprinting to generate multi-tissue type condensations for osteochondral tissue regeneration$403,645
R01 · FY2023 · AR · contact PI
Mechanosensitive synthetic cell-regulatable hydrogels for tissue engineering$200,428
R21 · FY2023 · AR · contact PI
Multi-tissue type condensations for trachea tissue regeneration via individual cell bioprinting$0
I01 · FY2023 · VA · contact PI
Mechanosensitive synthetic cell-regulatable hydrogels for tissue engineering$183,160
R21 · FY2022 · AR · contact PI
Opposing RNAi Molecule Gradient Constructs to Repair Osteochondral Defects$341,226
R01 · FY2021 · AR · contact PI
Engineering a Self-assembled, multi-tissue Tracheal Replacement$465,966
R01 · FY2020 · EB · contact PI
High-Throughput Microenvironment Regulation for Chondrogenesis$408,254
R01 · FY2020 · AR · contact PI
Opposing RNAi Molecule Gradient Constructs to Repair Osteochondral Defects$355,686
R01 · FY2020 · AR · contact PI
Engineering a Self-assembled, multi-tissue Tracheal Replacement$491,711
R01 · FY2019 · EB · contact PI
Engineering a self-assembled, multi-tissue tracheal replacement$478,894
R01 · FY2018 · EB · contact PI
Opposing RNAi Molecule Gradient Constructs to Repair Osteochondral Defects$372,934
R01 · FY2018 · AR · contact PI
High-Throughput Microenvironment Regulation for Chondrogenesis$273,044
R01 · FY2018 · AR · contact PI
High-Throughput Microenvironment Regulation for Chondrogenesis$135,308
R01 · FY2018 · AR · contact PI
Opposing RNAi molecule gradient constructs to repair osteochondral defects$1
R01 · FY2018 · AR · contact PI
Engineering a self-assembled, multi-tissue tracheal replacement$486,276
R01 · FY2017 · EB · contact PI
High-Throughput Microenvironment Regulation for Chondrogenesis$406,560
R01 · FY2017 · AR · contact PI
Opposing RNAi molecule gradient constructs to repair osteochondral defects$348,700
R01 · FY2017 · AR · contact PI
High-Throughput Microenvironment Regulation for Chondrogenesis$406,560
R01 · FY2016 · AR · contact PI
Opposing RNAi molecule gradient constructs to repair osteochondral defects$348,700
R01 · FY2016 · AR · contact PI
Driving tissue formation by inductive stem cell sheet technology$249,209
R01 · FY2016 · AR · contact PI
Driving Tissue Formation by Inductive Stem Cell Sheet Technology$105,350
R01 · FY2016 · AR · contact PI
High-Throughput Microenvironment Regulation for Chondrogenesis$421,034
R01 · FY2015 · AR · contact PI
Driving tissue formation by inductive stem cell sheet technology$344,821
R01 · FY2015 · AR · contact PI
Driving tissue formation by inductive stem cell sheet technology$338,317
R01 · FY2014 · AR · contact PI
Driving tissue formation by inductive stem cell sheet technology$328,325
R01 · FY2013 · AR · contact PI
Growth Plate Regeneration$234,911
R21 · FY2013 · AR
Controlled, Sustained Delivery of siRNA to hMSCs for Enhanced Bone Regeneration$345,969
R56 · FY2012 · DE · contact PI
Driving tissue formation by inductive stem cell sheet technology$321,900
R01 · FY2012 · AR · contact PI
Growth Plate Regeneration$157,000
R21 · FY2012 · AR