AY1AX000002
Cooperative Agreement
Overview
Grant Description
Health Enabling Advancements Through Regenerative Tissue Printing (HEART) - Despite decades of promise, tissue engineering has fallen far short of producing human-scale solid and densely cellular organs, such as liver, lung, kidney, brain, and heart. This inability to recreate human tissues and organs is slowing basic human developmental research, impacting hundreds of thousands of lives per year due to ever-lengthening donor organ waitlists or succumb to organ rejection, and costing countless billions of dollars due to failed drug trials from unrepresentative animal models.
With recent advances in stem cell biology, biomaterials, computational modeling, and 3D bioprinting, we now find ourselves on the cusp of producing functional human organs at scale. Cellular differentiation protocols are rapidly improving the function and safety of patient-specific stem cell-derived cells. Simultaneously, our ability to model the behavior of biological tissue could enable automated design of as-of-yet unimagined geometries, and advances in 3D biofabrication promise to turn these models into reality at production-level scales.
In particular, the use of bioprinting to rapidly incorporate branched and perfusable vessels that permeate tissue allows, for the first time, the production of thick and viable organs. A bold and dedicated effort to create human organs is now needed to bring tissue engineering out of the petri dish and into the clinic.
The Stanford Organ Engineering Initiative (SOEI) will innovate across cell production, predictive modeling, organ bioprinting hardware and biomaterials, and surgical techniques to validate the first human-scale, patient specific, and functional whole organ in a large animal model within five years. To accomplish this feat, the SOEI will team will innovate across four focus areas working synergistically.
The cell production team will increase therapeutic cell production capacity via innovations in cell culture, differentiation, and purification technologies. This includes generating multiple cardiovascular cell types (cardiomyocytes, cardiac fibroblasts, cardiac endothelial cells, and epicardial cells) at yields 2-3 orders of magnitude greater than typically produced.
The prediction & modeling team will create a unified predictive simulation that links tissue geometry, vascularization, perfusion, conduction, and biomechanics to optimize organ design, using both automated vascular network design and printing and multiphysics modeling for optimal cardiac output.
The bioprinting team will increase bioprinting speed by 100-fold to enable the high-resolution production of a functional heart whose design is guided by simulation results. This will be accomplished through the generation of novel tough and anisotropic bio-inks; new high throughput methods of multimaterial 3D printing.
The perfusion, transplantation, & validation team will oversee innovative methods to test and transplant a 3D bioprinted heart into a large animal (SCID pig) model to assess organ function in vivo. Data from validation studies will feed back into computational modeling to improve predictions.
In summary, integrating cell processing, modeling, and bioprinting at organ scale will introduce new capabilities that offer a truly curative solution for organ failure. While the SOEI will focus on heart biomanufacturing, our proposed innovations in cell production, tissue modeling, and bioprinting of cell-dense and vascularized tissue will advance capabilities across all organ-systems.
With recent advances in stem cell biology, biomaterials, computational modeling, and 3D bioprinting, we now find ourselves on the cusp of producing functional human organs at scale. Cellular differentiation protocols are rapidly improving the function and safety of patient-specific stem cell-derived cells. Simultaneously, our ability to model the behavior of biological tissue could enable automated design of as-of-yet unimagined geometries, and advances in 3D biofabrication promise to turn these models into reality at production-level scales.
In particular, the use of bioprinting to rapidly incorporate branched and perfusable vessels that permeate tissue allows, for the first time, the production of thick and viable organs. A bold and dedicated effort to create human organs is now needed to bring tissue engineering out of the petri dish and into the clinic.
The Stanford Organ Engineering Initiative (SOEI) will innovate across cell production, predictive modeling, organ bioprinting hardware and biomaterials, and surgical techniques to validate the first human-scale, patient specific, and functional whole organ in a large animal model within five years. To accomplish this feat, the SOEI will team will innovate across four focus areas working synergistically.
The cell production team will increase therapeutic cell production capacity via innovations in cell culture, differentiation, and purification technologies. This includes generating multiple cardiovascular cell types (cardiomyocytes, cardiac fibroblasts, cardiac endothelial cells, and epicardial cells) at yields 2-3 orders of magnitude greater than typically produced.
The prediction & modeling team will create a unified predictive simulation that links tissue geometry, vascularization, perfusion, conduction, and biomechanics to optimize organ design, using both automated vascular network design and printing and multiphysics modeling for optimal cardiac output.
The bioprinting team will increase bioprinting speed by 100-fold to enable the high-resolution production of a functional heart whose design is guided by simulation results. This will be accomplished through the generation of novel tough and anisotropic bio-inks; new high throughput methods of multimaterial 3D printing.
The perfusion, transplantation, & validation team will oversee innovative methods to test and transplant a 3D bioprinted heart into a large animal (SCID pig) model to assess organ function in vivo. Data from validation studies will feed back into computational modeling to improve predictions.
In summary, integrating cell processing, modeling, and bioprinting at organ scale will introduce new capabilities that offer a truly curative solution for organ failure. While the SOEI will focus on heart biomanufacturing, our proposed innovations in cell production, tissue modeling, and bioprinting of cell-dense and vascularized tissue will advance capabilities across all organ-systems.
Funding Goals
THE PURPOSE OF THIS PROGRAM IS TO COORDINATE THE ACCELERATION OF BIOMEDICAL AND HEALTH BREAKTHROUGHS TO DELIVER TRANSFORMATIVE, SUSTAINABLE, AND EQUITABLE HEALTH SOLUTIONS FOR EVERYONE BY (A) FACILITATING COLLABORATION BETWEEN ADVANCE RESEARCH PROJECTS AGENCY FOR HEALTH AND OTHER FEDERAL AGENCIES, RELEVANT INDUSTRIES, ACADEMIA, AND OTHER PERSONS, WITH RESPECT TO ADVANCE HIGH-POTENTIAL, HIGH IMPACT BIOMEDICAL AND HEALTH RESEARCH THAT CANNOT BE READILY ACCOMPLISHED THROUGH TRADITIONAL RESEARCH AND COMMERCIAL ACTIVITY, (B) IDENTIFYING AND PROMOTING REVOLUTIONARY ADVANCED IN HEALTH SCIENCES, (C) PROMOTING HIGH REWARD INNOVATION TO DEVELOP HIGH NEED CURES (D) ENSURING THAT THE UNITED STATES MAINTAINS, GLOBAL LEADERSHIP AND SCIENCE AND INNOVATION AND THE HIGHEST QUALITY OF LIFE AND HEALTH FOR ITS CITIZENS.
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Palo Alto,
California
94304
United States
Geographic Scope
Single Zip Code
Related Opportunity
The Leland Stanford Junior University was awarded
Regenerative Tissue Printing for Human Organs (HEART)
Cooperative Agreement AY1AX000002
worth $15,479,192
from the National Institutes of Health in September 2023 with work to be completed primarily in Palo Alto California United States.
The grant
has a duration of 5 years and
was awarded through assistance program 93.384 ADVANCED RESEARCH PROJECTS AGENCY for HEALTH (ARPA-H).
The Cooperative Agreement was awarded through grant opportunity ARPA-H Open Office BAA.
Status
(Ongoing)
Last Modified 12/5/24
Period of Performance
9/25/23
Start Date
9/24/28
End Date
Funding Split
$15.5M
Federal Obligation
$0.0
Non-Federal Obligation
$15.5M
Total Obligated
Activity Timeline
Transaction History
Modifications to AY1AX000002
Additional Detail
Award ID FAIN
AY1AX000002
SAI Number
AY1AX000002-2234376173
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Private Institution Of Higher Education
Awarding Office
75N992 ADVANCED RESEARCH PROJECTS AGENCY FOR HEALTH (ARPA-H)
Funding Office
75N992 ADVANCED RESEARCH PROJECTS AGENCY FOR HEALTH (ARPA-H)
Awardee UEI
HJD6G4D6TJY5
Awardee CAGE
1KN27
Performance District
CA-16
Senators
Dianne Feinstein
Alejandro Padilla
Alejandro Padilla
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| Advanced Research Projects Agency for Health-NIH, National Institutes of Health, Department of Health and Human Services (075-0837) | Health research and training | Grants, subsidies, and contributions (41.0) | $15,479,192 | 100% |
Modified: 12/5/24