Showing 25 ideas for tag "cells"

Goal 1: Promote Human Health

Mechanisms of Vascular Stiffness

Increased vascular stiffness has been identified as an important cardiovascular event that accompanies aging and cardiovascular disease. Although multiple vascular changes have been identified and suggested to cause increased vascular stiffness, our understanding of the underlying mechanisms needs to be refined in order to develop useful therapeutic strategies to prevent or reverse these changes. An example of critical... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

Ultimately, addressing this CQ would impact treatment of CV disease, reduce incidence of significant and life threatening CV events and improve quality of life. This area of investigation is relevant to therapeutics and potentially lifestyle changes that will improve CV health and slow CV age related changes linked to disease.

Feasibility and challenges of addressing this CQ or CC

Current advances in our technologies make it very feasible to address new questions to improve our knowledge of the mechanisms underlying vascular stiffness. Challenges will include developing multi-scale and cross disciplinary strategies that will, by design, facilitate an integrated understanding of the process leading to altered vascular stiffness.

Name of idea submitter and other team members who worked on this idea Gerald A. Meininger

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55 net votes
88 up votes
33 down votes
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Goal 2: Reduce Human Disease

The role of Extracorporeal Photopheresis (ECP) in the prevention and treatment of rejection of heart and lung transplants

According to the ISHLT, more than 4,000 patients undergo a heart transplant each year, and almost 4,000 receive single or double lung transplants. Their prognosis depends heavily on the avoidance of rejection, which claims the majority of their lives. For heart transplant recipients, the median survival is 11 years, while for lung transplant recipients, it is approximately 5 years. The current most common anti-rejection... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

Patients who are fortunate to receive a matched heart or one or two lungs transplants are at high risk of dying from rejection early and even years after the operation. Thus, they are given cocktails of highly toxic anti-rejection drugs for the rest of their lives. Unfortunately, despite compliance with their drug regimens, many patients still suffer repeated episodes of rejection that may be fatal. In addition, they develop serious side-effects such as diabetes, infections, malignancies, renal failure, etc. ECP has been shown efficacy in preventing and treating cardiac transplant rejection, but the data are limited. ECP appears to benefit such patients by causing an increase in the number of circulating T regulatory (“T regs”) cells. T regs are known to mediate immune tolerance, the ultimate goal of a long-term successful transplant. The role of ECP in lung transplantation is mostly unknown. Very preliminary data have been gathered from retrospective studies. We suspect that patients with early bronchiolitis obliterans syndrome (“BOS”) will benefit from ECP prior to developing irreversible pulmonary damage. In both types of transplants, however, it is unknown when should ECP be started, how often it should be employed (treatment schedule), and for how long. Finally, the most compelling argument to use ECP in heart and lung transplantation is its excellent side-effect profile. Furthermore, ECP may allow a decrease in the number of drugs needed to prevent rejection.

Feasibility and challenges of addressing this CQ or CC

Many patients with heart and lung transplants develop severe and often fatal rejection despite the current drug options to prevent rejection. ECP could be added to their treatment regimens and decrease side-effects, improving long-term survival.

ECP is generally well tolerated and complications are extremely infrequent.

There is a great potential for multi-disciplinary collaboration between Apheresis Medicine, Cardiology, and Pulmonary specialists.

It is conceivable that manufacturers of ECP instruments will be interested in contributing to the design and support of these studies.

Such studies could shed light in the mechanism of action of ECP in heart and lung transplantation.

There is a need to develop standardized treatment regimens based on well designed clinical trials to further optimize the use of ECP. Development and standardization of measurable outcomes is critical for the success of clinical studies in apheresis in general, and ECP in particular.

Challenges:

  1. Limited number of institutions providing ECP treatment.
  2. Cost of ECP procedures.
  3. Small number of animal models available for apheresis research. Thus, limited studies of ECP mechanism(s) of action. However, understanding pathological mechanisms and their relationship to response to apheresis is critical for optimization and advancement of patient care in heart and lung transplantation.
  4. Lack of infra-structure for apheresis research.

Name of idea submitter and other team members who worked on this idea Marisa Marques on behalf of ASFA

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80 net votes
102 up votes
22 down votes
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Goal 3: Advance Translational Research

Increasing Regenerative Medical Strategies in Pulmonary Arterial Hypertension

Pulmonary arterial hypertension (PAH) is a complex, progressive condition characterized by high blood pressure in the lungs and restriction of flow through the pulmonary arterial system. Current PAH therapies mainly act of the vasoconstrictive component of the disease; however there is a widely accepted view that another contributor to the disease is an abnormal overgrowth of cells that line the pulmonary arteries, which... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

In the past twenty years, 12 PAH targeted-therapies have been approved by the FDA. This increase in disease state awareness and in the treatment armamentarium have contributed to an increase in average survival from 2.8 years to an estimated 8-10 years. However, current treatments primarily address the vasoconstrictive component of the disease and do not address the now accepted theory of post-apoptotic overgrowth of hyperproliferative cells of the pulmonary vessels. A number of circulating stem and progenitor cells, derived from the bone marrow, have been identified that could have roles in repair of the pulmonary vascular system when interacting with the quickly, abnormally growing cells in the lung vessels. Work in this area has been named as a future research opportunity in the NHLBI-ORDR Strategic Plan for Lung Vascular Research (Erzurum S, et al. 2010).

Feasibility and challenges of addressing this CQ or CC

Basic and translational research support is needed—including high-throughput approaches such as phage display and large-scale proteomic analysis—to better understand the relationship between circulating bone marrow-derived cells, lung-resident stem and progenitor cells, and endothelial cells of the pulmonary arterial system.

Name of idea submitter and other team members who worked on this idea Pulmonary Hyeprtension Association, Michael Gray, Katie Kroner

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71 net votes
81 up votes
10 down votes
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Goal 2: Reduce Human Disease

Stem Cell Biology

There is a need to develop an artificial and functional hematopoietic stem cell (HSC) niche that allows for the expansion of repopulating HSCs.

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Critical Challenge (CC)

Details on the impact of addressing this CQ or CC

Methods to expand hematopoietic stem cells have continued to be examined extensively because stem cell numbers in the graft are important for clinical outcomes following transplantation. These numbers are particularly relevant in umbilical cord blood (UCB) transplantation, where low numbers of stem cells are directly related to delayed hematopoietic and immune reconstitution. Improved HSC expansion strategies may significantly impact transplantation outcome, enabling broader applications beyond UCB transplantation. Furthermore, these strategies are also needed to realize the full therapeutic potential of genome editing technologies to correct hematopoietic stem cells derived from patients with hematologic disorders. Since efforts to expand HSCs in cytokine-supported liquid cultures have been largely unsuccessful, efficient expansion will require an appropriate context that is provided by the hematopoietic stem cell niche. Future studies must also evaluate how niche signals regulate stem cell function to optimize cell expansion, and proper humanized mouse models must be developed to help predict stem cell function and regulation by the niche.

Name of idea submitter and other team members who worked on this idea Alice Kuaban on behalf of the American Society of Hematology (ASH)

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28 net votes
46 up votes
18 down votes
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Goal 2: Reduce Human Disease

Stem Cell Immunology

We now can create critical cell types like cardiomyocytes etc. from stem cells. Additionally, we are learning the rules of using these cells to rebuild tissues. A major gap in our knowledge relates to the immunobiology of these cells. Lessons from transplantation medicine are only partially applicable, because solid organs are more complex and likely more immunogenic than defined cell populations.

How does the immune... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

We now can generate large quantities of critical cell types whose deficiencies underlie many chronic diseases like heart failure. This breakthrough brings us to the next-level impediment: the immune system. While induced pluripotent stem cells have the potential to obviate rejection, in practical terms this is cost-prohibitive: It will cost huge amounts of money to produce and qualify a single patient's cell dose. Moreover, human cardiomyocytes are potent when given to infarcted hearts in the acute or sub-acute phase of infarction, but they have no benefit with chronic heart failure. The 6 months required to produce iPSC-cardiomyocytes precludes their autologous use for myocardial infarction.

We need an off the shelf cell therapy product for myocardial infarction that can be mass produced and qualified for large numbers of patients. This means an allogeneic product is necessary. Identifying the immune response to cardiomyocytes or other cell products will teach us how to precisely immunosuppress the patient, thereby minimizing complications, or alternatively, how to engineer the cells so as to avoid immunogenicity in the first place.

Lessons from the study of cardiomyocyte transplantation could extend to dopamine neurons, pancreatic beta-cells, retinal cells, myelinating cells and many other areas that cause common chronic disease.

Feasibility and challenges of addressing this CQ or CC

We know a great deal of transplant immunology from hematopoietic stem cell transplantation (graft versus host) and from solid organ transplantation (host versus graft). There are good mouse and large animal (including non-human primate) models of stem cell differentiation and organ transplantation. This offers low hanging fruit where, in perhaps 5 years, we could discern the critical similarities and differences between transplanting stem cell derivatives and organ or marrow transplantation. These studies will inform clinical trials of allogeneic human stem cell derivatives that will be underway by then.

Success in this area will require bringing together researchers interested in stem cell biology and transplant immunology. A properly resourced RFA from NIH could be just the thing needed to promote this interaction.

Name of idea submitter and other team members who worked on this idea Charles Murry, MD, PhD

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23 net votes
45 up votes
22 down votes
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Goal 1: Promote Human Health

Funding of Stem Cell/Lung Regeneration Research

How to "cure" a chronic, incurable disease - A potential giant step in saving the lives of many thousands of Americans, and potentially millions worldwide, who are afflicted with COPD, the third leading cause of death in the U.S.
The financial effect of COPD in the United States alone is well over $50 billion per year. It is estimated that some 30 million Americans have COPD, which of course means that at least that... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Critical Challenge (CC)

Details on the impact of addressing this CQ or CC

COPD is chronic and presently incurable. Although it sickens and disables nearly 30 million Americans, and kills 140,000 of them each year, the only "cure" is a lung transplant. Due to the scarcity of organ donors and the requirements that lungs be removed from the donor in a hospital setting, only about 1,400 lung transplants are performed in the Unites States each year. Unfortunately, transplants are fraught with complications, side effects, and potential rejections, and on the average, add only about 5 years to the life of the recipient. The best potential solution lies with the stem cell and lung regeneration research that is presently occurring at a few centers around the country. Ideally, the re-engineered lungs would be composed of the patient's own stem cells, eliminating a great many of the current transplant issues.

Feasibility and challenges of addressing this CQ or CC

Research is presently in process on construction or reconstruction of human organs. There has been success in creating some of the simpler organs, such as the esophagus and bladder, and a Medical Center in Galveston has implanted re-engineered lung is a pig. As of my latest conversation with the lead Doctor on the project, results so far are promising.
There is general agreement among the researchers with whom I have communicated that we are between 5 and 20 years away from human trials of re-generated lungs using the patient's own stem cells, but more funding means more research which means more possibilities of the saving of lives.

Name of idea submitter and other team members who worked on this idea Jim Nelson - COPD Foundation MASAC/CAC/BOARD Committee Member

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25 net votes
32 up votes
7 down votes
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Goal 3: Advance Translational Research

To find specific medical therapies to treat the wide array of human vascular malformations and vascular tumors.

Vascular malformations and vascular tumors, together referred to as vascular anomalies, comprise a complex and wide array of diseases in which there is a fundamental disruption in blood and lymphatic vasculature. The lesions disrupt organ function, destroy tissue, cause bleeding, increase infections and can threaten life. At present, there are some medical therapies but none are specifically targeted to an underlying... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Critical Challenge (CC)

Details on the impact of addressing this CQ or CC

Deciphering the cellular and molecular basis of human vascular anomalies will have a critical impact for patients with these lesions and it will also have a broad, far-reaching impact on cardiovascular research because the mechanisms and insights learned from these specific vascular anomalies will teach us the fundamental rules that are needed, and must be followed, to build and maintain a stable functional vasculature in humans. This will have an impact on a variety of areas of research including regenerative medicine.

Feasibility and challenges of addressing this CQ or CC

With the enormous advances in next generations sequencing technologies, the time is ripe for a concerted push to find the gene mutations that cause human vascular malformations and vascular tumors, both the most common and the rare. Cellular models for human endothelial cells are vastly improved and far superior to murine endothelial models, making research on patient-derived cells highly feasible.
The challenges will be to develop animal models of the individual human vascular anomalies that reflect as closely as possible the critical and specific features of the vascular malformation or vascular tumor. Such animal models, as well as relevant cellular in vitro models, would then be ideal for screen drug libraries for ability to reverse or slow the formation of the malformation or tumor. Such drugs might then be candidates to test in pilot clinical trials.

Name of idea submitter and other team members who worked on this idea Joyce Bischoff

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18 net votes
20 up votes
2 down votes
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Goal 1: Promote Human Health

The coupling of mechanical stress to biochemistry, molecular biology and electrophysiology

Cells aren’t beakers holding soluble reactants waiting to be mixed. Cells are structured objects where life forms as a flow of free energy between three pools: chemical, electrical and mechanical. Most papers in the literature ignore structure (except of Xray or EM of specific proteins) and almost all ignore the coupling of mechanics to the other pools. Cells cannot be studied with in vitro experiments. We can study single... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Critical Challenge (CC)

Details on the impact of addressing this CQ or CC

If we learn how a third of all cellular energy is used we have a better chance of understanding the other 2/3.

Feasibility and challenges of addressing this CQ or CC

Name of idea submitter and other team members who worked on this idea Dr. Frederick Sachs

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9 net votes
29 up votes
20 down votes
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Goal 3: Advance Translational Research

Regenerative Medicine 2.0 in Heart and Lung Research - Back to the Drawing Board

Stem cell therapies have been quite successful in hematologic disease but the outcomes of clinical studies using stem cells for cardiopulmonary disease have been rather modest.

Explanations for this discrepancy such as the fact that our blood has a high rate of physiologic, endogenous turnover and regeneration whereas these processes occur at far lower rates in the heart and lung. Furthermore, hematopoietic stem cells... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Critical Challenge (CC)

Details on the impact of addressing this CQ or CC

Some barriers to successfully implementing cardiopulmonary regeneration include the complex heterogeneous nature of the heart and lung.

Hematopoietic stem cells can give rise to all hematopoietic cells but the heart and lung appear to contain numerous pools of distinct regenerative stem and progenitor cells, many of which only regenerate a limited cell type in the respective organ. The approach of injecting one stem cell type that worked so well for hematopoietic stem cells is unlikely to work in the heart and lung.

We therefore need new approaches which combine multiple regenerative cell types and pathways in order to successfully repair and regenerate heart and lung tissues. These cell types will likely also require specific matrix cues since there are numerous, heterogeneous microenvironments in the heart and lung.

If we rethink our current approaches to regenerating the heart and lung and we use combined approaches in which multiple cell types and microevironments are concomitantly regenerated (ideally by large scale collaborations between laboratories), we are much more likely to achieve success.

This will represent a departure from the often practiced "Hey, let us inject our favorite cell" approach that worked so well in hematologic disease but these novel, combined approaches targeting multiple endogenous and/or exogenous regenerative cells could fundamentally change our ability to treat heart and lung disease.

Name of idea submitter and other team members who worked on this idea Jalees Rehman

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7 net votes
11 up votes
4 down votes
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Goal 2: Reduce Human Disease

Engineered ECM for heart repair

Utilizing advances in nano, bio, tissue and related engineering technologies to construct cardiac ECM for heart repair.

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Critical Challenge (CC)

Details on the impact of addressing this CQ or CC

Will advance cell and gene based therapeutics for cardiac repair. Despite promise, efficacy of cell based therapies remains largely unproven and this may in part be due to poor understanding of cell-ECM interactions. Research efforts in engineering cardiac ECM have the potential to greatly advance such therapeutic approaches.

Feasibility and challenges of addressing this CQ or CC

This research field is ripe for experimentation and testing.
A major thrust of recent efforts in repairing cardiac injury has focused on cell therapies. However, since the ECM provides the necessary scaffold for the cells it is important to consider the cell-ECM interactions when utilizing these approaches.

Will require multi-disciplinary expertise.

Name of idea submitter and other team members who worked on this idea NHLBI Staff

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3 net votes
19 up votes
16 down votes
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Goal 2: Reduce Human Disease

Harnessing Lung Regenerative Capacity to Improve and Increase Donor Lungs for Transplantation.

Using knowledge of matrix biology and lung development, what are useable methods to modify cadaveric donor lungs to provide a durable, effective organ replacement therapy?

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

A major advance in this area will increase the number of donor lungs available for lung transplantation

Feasibility and challenges of addressing this CQ or CC

A number of stem and progenitor cells involved in lung repair and regeneration have been identified. Targeting them for expansions in damaged donor lungs may turn these damaged lungs into healthier lungs that can then be used for lung transplant safely.
Most of the donor lungs are not suitable for lung transplantation because the premorbid conditions of the donors often also damaged the lungs. Bioreactors have been used to “rehab” these damaged lungs and optimizing the ex vivo condition in these bioreactors may accelerate the lung repair process.

Name of idea submitter and other team members who worked on this idea NHLBI Staff

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1 net vote
18 up votes
17 down votes
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Goal 2: Reduce Human Disease

Influence of the Gut Microbiome on Pulmonary Immunity in HIV-Infected Individuals

It has become increasingly clear that gut microbiota have a tremendous impact on human health and disease. While it is well known that commensal gut bacteria are crucial in maintaining immune homeostasis in the intestine, there is also evidence of indirect effects on the lung. Multiple studies have shown that alterations in gut microbiota can lead to severe defects in pulmonary immune responses and reduced ability to... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

HIV-infected individuals are at significant risk of developing and dying from infectious and non-infectious pulmonary complications. Alteration of gut microbiota have been shown to have dramatic effects on pulmonary immunity and severity of lung infections. For instance, multiple studies have indicated that probiotic treatment with certain Lactobacillus and Bifidobacterium strains results in reduced incidence and severity of upper respiratory tract infections in children. Similarly, a recent study showed that treatment with the minimally absorbed antibiotic neomycin was associated with alterations in gut microbiota composition and concomitant reduced pulmonary immunity and the inability to control Influenza infection in mice. It was recently described that HIV infection is associated with a dramatic alteration in gut microbiota and that these changes persist with antiretroviral therapy (ART). Thus, it is important to understand how these alterations may effect lung immunity, since the majority of HIV-infected individuals develop pulmonary infections. Furthermore, gut microbiota contribute to development of non-infectious complications such as atherosclerosis, metabolic disease, obesity and diabetes. It is thus highly plausible that the gut microbiota may also play a role in the development of non-infectious complications of the lung such as Chronic Obstructive Pulmonary Disease and Pulmonary Hypertension, the rates of which are elevated in HIV-infected individuals.

Feasibility and challenges of addressing this CQ or CC

A better understanding of how alterations in gut microbiota associated with HIV infection affects pulmonary infectious and noninfectious complication could lead to therapies to protect this “at risk” group. Furthermore, manipulation of the gut microbiota in HIV-infected individuals using pro- and/or pre-biotics, antibiotics or diet modification to a composition that is associated with increased pulmonary immunity, reduced infections and lung complications are all low risk therapeutic strategies that could substantially improve lung heath in these individuals.

Name of idea submitter and other team members who worked on this idea Brent Palmer (NHLBI-INHALD group member) and Catherine Lozupone

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3 net votes
7 up votes
4 down votes
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Goal 2: Reduce Human Disease

Mitigating risks due to the RBC storage lesion and vulnerable patients

What are the underlying dependencies (genomic, metabolic, disease) in individual donors that either accelerate or delay the changes to red blood cells during refrigerated storage? What methods of preparation might protect patients from the risks posed by the accelerated degradation of RBCs provided by "poor storers"? What characteristics of individual patients make them particularly vulnerable to transfusion of red... more »

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

The changes in red blood cells during refrigerated storage have been well documented and associated with negative clinical sequelae in the peer reviewed literature. While the impact of this so-called storage lesion does not impact every patient during every transfusion it is reasonable to expect that when a unit of blood is transfused to a particularly vulnerable patient from a donor that has red blood cells pre-disposed to degradation, stored in a manner that has allowed significant change to occur, the risk of a negative clinical sequelae is increased. In this case it will be important to understand what underlies the likelihood of a donors blood to store poorly, the changes that occur during storage that could impact vulnerable patients and design approaches to mitigate the degradation that could result.

Feasibility and challenges of addressing this CQ or CC

We believe mitigating the impact of the storage lesion is feasible by reducing and controlling the oxygen concentration in the RBC unit prior to refrigerated storage. We are continuing our development of a device to do this and to generate the data demonstrating the effect of deoxygenation and anaerobic storage.

Name of idea submitter and other team members who worked on this idea Andrew Dunham

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3 net votes
3 up votes
0 down votes
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Goal 2: Reduce Human Disease

Biology of the intact alveolar wall – the new frontier in lung research

HOW DO WE STUDY THE BIOLOGY OF THE INTACT ALVEOLAR WALL IN THE CONTEXT OF LUNG DISEASE AND REPAIR?

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Details on the impact of addressing this CQ or CC

SEE UPLOADED FILE

Feasibility and challenges of addressing this CQ or CC

SEE UPLOADED FILE

Name of idea submitter and other team members who worked on this idea JAHAR BHATTACHARYA

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2 net votes
2 up votes
0 down votes
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Goal 2: Reduce Human Disease

Human Lung Progenitor Cells, Lung Epithelial Differentiated iPSCs, and Therapeutics

What are the biological properties and key surface markers of human lung progenitor cells and lung epithelial differentiated iPSCs? How can these cell populations be targeted for therapeutic purposes, including regenerative therapy?

Is this idea a Compelling Question (CQ) or Critical Challenge (CC)? Compelling Question (CQ)

Name of idea submitter and other team members who worked on this idea Cystic Fibrosis Foundation

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2 net votes
6 up votes
4 down votes
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