MASSACHUSETTS GENERAL HOSPITAL, THE
Heart transplantation is often the only available therapeutic option in end-stage heart disease. To monitor graft survival, recipients endure frequent invasive endomyocardial biopsies which carry a significant risk of complication and are prone to sampling-errors. There is thus a compelling need to develop noninvasive, more predictive and quantitative diagnostic tools to monitor individual patients and to compare new treatment regimen in different patient cohorts. An increasing body of work suggests that macrophages are highly abundant in rejected allografts, and exhibit cardinal cellular and molecular functions. The overall goal of this proposal is to evaluate macrophages and macrophage-associated functions as in vivo imaging biomarkers of transplant rejection. Specifically, we will validate a) nanoparticles as reporters of phagocytic activity, b) optical prodrugs as sensors of cysteine protease activity, and c) myeloperoxidase-targeted magnetic resonance imaging agents. We will investigate which of the above imaging marker correlates most closely with the ex vivo gold standard (ISHLT-graded histology) and CD68 expression and if imaging can detect earliest forms of rejection and/or tolerance at sufficiently high sensitivity and specificity. We will test these MU-targeted cardiac imaging tools to non-invasively investigate 3 specific therapeutic approaches to treat transplant rejection. First we will benchmark macrophage imaging during the use of routine immunosuppressants (calcineurin inhibitor, antimetabolite agent and corticosteroids). Next we will investigate emerging tolerance regimen (induction of mixed chimerism by bone marrow co- transplantation). Finally, we will use mice deficient for macrophage recruiting cytokines and adoptive cell transfer to reprogram prevalent macrophage populations in the heart from the inflammatory M1 to reparative M2 subsets. These longitudinal studies will be used to validate functional macrophage-targeted agents for noninvasive heart transplant imaging. PUBLIC HEALTH RELEVANCE: Our goal is the development of molecular imaging methods to detect heart transplant rejection non-invasively. We will first investigate and then exploit the role of macrophages, increasingly appreciated to contribute to rejection, as imaging targets. The approach will be tested in several therapy trials.
| AWARD OVERVIEW |
| Award Number |
1R01HL095629-01 |
Funding Agency |
Department of Health and Human Services |
| Total Award Amount |
$882,726 |
Project Location - City |
Boston |
| Award Date |
07/16/2009 |
Project Location - State |
MA |
| Project Status |
Completed |
Project Location - Zip |
02114-0000
|
| Jobs Reported |
2.40 |
Congressional District |
09 |
| Project Location - Country |
US |
|
|
Recipient Information
(Grants)
| Recipient Information (Grants) |
|
Recipient Name
|
MASSACHUSETTS GENERAL HOSPITAL, THE |
| Recipient DUNS Number |
073130411
|
| Recipient Address |
55 FRUIT ST |
| Recipient City |
BOSTON |
| Recipient State |
Massachusetts |
| Recipient Zip |
02114-2621 |
| Recipient Congressional District |
09 |
| Recipient Country |
USA |
Required to Report Top 5
Highly Compensated Officials |
No |
Projects and Jobs Information
| Projects and Jobs Information |
| Project Title |
Imaging of Cardiac Transplant Rejection |
| Project Status |
Completed |
| Final Project Report Submitted |
Yes |
| Project Activities Description |
General Medical and Surgical Hospitals |
| Quarterly Activities/Project Description |
In the last quarter, we have worked on the following:
Based on our finding that ACE inhibition reduced the nanoparticle PET signal, and that ACE inhibitor treated mice reject allografts slower, we wanted to study the mechanistic aspects in mice that are deficient for the angiotensin 2 receptor subset 1. We attempted to transplant allografts into the peritoneal cavity of knock out mice, however, there was excess mortality in these recipients. We assume that this may be caused by the somewhat lower blood pressure in these mice, and are now pursuing a less invasive model. We have submitted an IACUC protocol to the local animal ethic committee to use subcutaneous transplantation of hearts from newborn mice into a pocket created in the ear of recipients. This model is less demanding on the recipient animal, and should allow us to study graft survival in mice in which angiotensin 2 signaling was genetically disrupted.
We have made progress on the intravital imaging of major cell types involved in heart transplant rejection, including allografts in CD11c+ YFP recipients and in CX3CR1 GFP graft recipients, which allows us to image the presence of dendritic cells and monocytes, respectively. The immense technical hurdles of microscopy of the beating heart non-withstanding, we have now succeeded to record intravital microscopy videos of up to 45 minutes length. These display mobility of GFP-positive antigen presenting cells. We continue to optimize the imaging approach and will start to image APC/Tcell interactions in the next quarter.
In addition to the projects above, we have started to establish a model of autoimmune myocarditis induced by immunization with a Troponin I peptide. On the expected peak of inflammation (day 21), mice were imaged by MRI after injection with 30mg/kg of the magnetofluorescent nanoparticle CLIO-VT680. Using T2* weighted FLASH with an echo time of 5 ms, a diffuse hypodense signal was registered in the myocardium of mice with myocarditis. |
| Jobs Created |
2.40 |
| Description of Jobs Created |
Heart transplantation is often the only available therapeutic option in end-stage heart disease. To monitor graft survival, recipients endure frequent invasive endomyocardial biopsies which carry a significant risk of complication and are prone to sampling-errors. There is thus a compelling need to develop noninvasive, more predictive and quantitative diagnostic tools to monitor individual patients and to compare new treatment regimen in different patient cohorts. An increasing body of work suggests that macrophages are highly abundant in rejected allografts, and exhibit cardinal cellular and molecular functions. The overall goal of this proposal is to evaluate macrophages and macrophage-associated functions as in vivo imaging biomarkers of transplant rejection. Specifically, we will validate a) nanoparticles as reporters of phagocytic activity, b) optical prodrugs as sensors of cysteine protease activity, and c) myeloperoxidase-targeted magnetic resonance imaging agents. We will investigate which of the above imaging marker correlates most closely with the ex vivo gold standard (ISHLT-graded histology) and CD68 expression and if imaging can detect earliest forms of rejection and/or tolerance at sufficiently high sensitivity and specificity. We will test these M?-targeted cardiac imaging tools to non-invasively investigate 3 specific therapeutic approaches to treat transplant rejection. First we will benchmark macrophage imaging during the use of routine immunosuppressants (calcineurin inhibitor, antimetabolite agent and corticosteroids). Next we will investigate emerging tolerance regimen (induction of mixed chimerism by bone marrow co-transplantation). Finally, we will use mice deficient for macrophage recruiting cytokines and adoptive cell transfer to reprogram prevalent macrophage populations in the heart from the inflammatory M1 to reparative M2 subsets. These longitudinal studies will be used to validate functional macrophage-targeted agents for noninvasive heart transplant imaging.
|
Purchaser Information
(Grants)
| Purchaser Information |
| Contracting Office ID |
Not Reported |
| Contracting Office Name |
Not Available |
| Contracting Office Region |
Not Available |
| TAS Major Program |
75-0871 |
| Award Information |
| Award Date |
07/16/2009 |
| Award Number |
1R01HL095629-01 |
| Order Number |
|
| Award Type |
Grants |
| Funding Agency ID |
75 |
| Funding Agency Name |
Department of Health and Human Services |
| Funding Office Name |
Not Available |
| Awarding Agency ID |
75 |
| Awarding Agency Name |
Department of Health and Human Services |
| Amount of Award |
$882,726 |
| Funds Invoiced/Received |
$882,726 |
| Expenditure Amount |
$882,726 |
| Infrastructure Expenditure Amount |
$0 |
| Infrastructure Purpose and Rationale |
Not Reported |
| Infrastructure Point of Contact Name |
Not Reported |
| Infrastructure Point of Contact Email |
Not Reported |
| Infrastructure Point of Contact Phone |
Not Reported |
| Infrastructure Point of Contact Address |
Not Reported |
| Infrastructure Point of Contact City |
Not Reported |
| Infrastructure Point of Contact State |
Not Reported |
| Infrastructure Point of Contact Zip |
Not Reported |
Product or Service Information
(Grants)
| Product or Service Information |
| Primary Activity Code |
622110 |
| Activity Description |
General Medical and Surgical Hospitals |
| Sub-Awards Information |
| Sub-awards to Organizations |
0 |
| Sub-award Amounts to Organizations |
$0 |
| Sub-Awards to Individuals |
0 |
| Sub-Award Amounts to Individuals |
$0 |
| Number of Sub-awards less than $25,000/award |
0 |
| Amount of Sub-awards less than $25,000/award |
$0 |
| Number of payments to vendors greater than $25,000 |
0 |
| Total Amount of payments to vendors greater than $25,000/award |
$0 |
| Number of payments to vendors less than $25,000/award |
595 |
| Total Amount of payments to vendors less than $25,000/award |
$181,280 |
| Location Information |
| Latitude, Longitude |
42º 21' 44",
-71º 4' 11" |
| Congressional District |
09 |
| Address 1 |
55 Fruit Street |
| Address 2 |
|
| City |
Boston |
| County |
Suffolk |
| State |
MA |
| Zip |
02114-0000 |
|
 |