Expired RFA-CA-09-025: Cancer Intervention and Surveillance Modeling Network (CISNET) (U01)

Part I Overview Information

Department of Health and Human Services

Participating Organizations
National Institutes of Health (NIH) (http://www.nih.gov/)

Components of Participating Organizations
National Cancer Institute (NCI) http://www.cancer.gov/

Title: Cancer Intervention and Surveillance Modeling Network (CISNET) (U01)

Announcement Type
This funding announcement is a reissuance of RFA-CA-05-018.

Request For Applications (RFA) Number: RFA-CA-09-025

Catalog of Federal Domestic Assistance Number(s)
93.393, 93.394, 93.395, 93.396, 93.399

Key Dates
Release Date: June 25, 2009
Letters of Intent Receipt Date: October 3, 2009
Application Receipt Date: November 3, 2009
Peer Review Date(s): February/March 2010
Council Review Date: May 2010
Earliest Anticipated Start Date: September 2010
Additional Information To Be Available Date (URL Activation Date): Not Applicable
Expiration Date: November 4, 2009

Due Dates for E.O. 12372

Not Applicable

Pre-application Teleconference

The NCI will hold a pre-application teleconference (via conference call arrangements) open to all interested prospective applicants. NCI program staff members will explain the goals and objectives for the CISNET and will answer questions from the participants. For updated announcements and details on this pre-application informational conference call, see http://cisnet.cancer.gov/foa.html..

Additional Overview Content

Executive Summary

Purpose. Through this funding opportunity announcement (FOA), the National Cancer Institute (NCI) solicits applications for the Cancer Intervention and Surveillance Modeling Network (CISNET). The goal of CISNET is to use simulation and other modeling techniques (a) to understand the impact of cancer control interventions (i.e., screening, treatment, prevention) on national trends in cancer rates, and (b) to inform national/regional/local decisions on the most efficient utilization of existing and emerging technologies and strategies for the control of cancer. This FOA expands CISNET efforts focused on four cancer sites (prostate, lung, colorectal, breast) and will also cover two additional sites (cervical and esophageal cancer). Expansion into new areas of modeling (identified in the FOA) is also encouraged. This FOA will support collaborative, interactive projects involving groups of researchers that would put forward a program of comparative modeling, as well as to allow coverage across the important cancer control issues and relevant specific focus areas for the selected organ site. Investigators may propose the application, extension, and/or merging of existing models. However, de novo model development will NOT be supported. Because of the requirement of conducting cross-model comparisons (i.e. comparative modeling) and coverage of a broad range of cancer control issues, it is expected that each award will support between approximately 2 and 5 modeling groups working together. This FOA is an open competition for all qualified investigators, irrespective of their previous involvement in the CISNET program.
Mechanism of Support. This FOA will utilize the NIH U01 cooperative agreement mechanism.
Funds Available and Anticipated Number of Awards. The NCI expects to commit $5.4 million in year 1 and $6.0 million per year in years 2-5 to fund approximately four to six awards.
Budget and Project Period. An applicant may request a project period of up to 5 years and budget for up to $1.3M total costs for the first year. For more details on the budget restrictions, see Section IV.5 - Funding Restrictions of this FOA.
Eligible Institutions/Organizations. Institutions/organizations listed in Section III, 1.A. are eligible to apply.
Eligible Project Directors/Principal Investigators (PDs/PIs). Individuals with the skills, knowledge, and resources necessary to carry out the proposed research are invited to work with their institution/organization to develop an application for support. Individuals from underrepresented racial and ethnic groups as well as individuals with disabilities are always encouraged to apply for NIH support.
Number of PDs/PIs. More than one PD/PI (i.e., multiple PDs/PIs) may be designated on the application.
Number of Applications. Applicants may submit more than one application, provided they are scientifically distinct.
Resubmissions. Resubmission applications are not permitted in response to this FOA.
Renewals. Renewal applications are not permitted in response to this FOA. Applications from current CISNET awardees will be considered as new applications.
Special Date(s). This FOA uses non-standard due dates. See Receipt, Review and Anticipated Start Dates.
Application Materials. See Section IV.1 for application materials.
Hearing Impaired. Telecommunications for the hearing impaired are available at: TTY 301-451-5936.

Table of Contents

Part I Overview Information

Part II Full Text of Announcement

Section I. Funding Opportunity Description
1. Research Objectives

Section II. Award Information
1. Mechanism(s) of Support
2. Funds Available

Section III. Eligibility Information
1. Eligible Applicants
A. Eligible Institutions
B. Eligible Individuals
2. Cost Sharing or Matching
3. Other - Special Eligibility Criteria

Section IV. Application and Submission Information
1. Address to Request Application Information
2. Content and Form of Application Submission
3. Submission Dates and Times
A. Receipt, Review and Anticipated Start Dates
1. Letter of Intent
B. Sending an Application to the NIH
C. Application Processing
D. Application Assignment
4. Intergovernmental Review
5. Funding Restrictions
6. Other Submission Requirements

Section V. Application Review Information
1. Criteria
2. Review and Selection Process
A. Additional Review Criteria
B. Additional Review Considerations
C. Resource Sharing Plan(s)
3. Anticipated Announcement and Award Dates

Section VI. Award Administration Information
1. Award Notices
2. Administrative and National Policy Requirements
A. Cooperative Agreement Terms and Conditions of Award
1. Principal Investigator Rights and Responsibilities
2. NIH Responsibilities
3. Collaborative Responsibilities
4. Arbitration Process
3. Reporting

Section VII. Agency Contact(s)
1. Scientific/Research Contact(s)
2. Peer Review Contact(s)
3. Financial/ Grants Management Contact(s)

Section VIII. Other Information - Required Federal Citations

Part II - Full Text of Announcement

Section I. Funding Opportunity Description

1. Research Objectives

Purpose

This funding opportunity announcement (FOA) is a continuation of Cancer Intervention and Surveillance Modeling Network (CISNET) program. Through this FOA, the Division of Cancer Control and Population Sciences (DCCPS), National Cancer Institute (NCI), solicits applications for collaborative research projects using simulation and other modeling techniques for specific cancer sites (see below). The proposed research is expected to generate sophisticated, evidence-based decision tools that could inform national/regional/local decisions on the most efficient utilization of existing and emerging technologies and strategies for the control of cancer. These tools should allow for the following:

1) Enhanced understanding of the impact of cancer control interventions (screening, treatment, prevention) on current and future trends in incidence and mortality;

2) Determination of the most efficient and cost-effective strategies for implementing technologies in the population, based on extrapolated evidence from clinical trials, epidemiologic studies, and observational studies; and

3) Helping to determine which new, emerging technologies are the most promising for scaling up to the population level, based on data from limited-scale studies.

Modeling - Definition: Modeling in the context of this FOA is defined as the use of mathematical and statistical techniques within a logical framework to integrate and synthesize known biological, epidemiological, clinical, behavioral, genetic, and economic information.

Overall goals of CISNET Program. The overall purpose of the CISNET Program is to explore the areas where modeling can assist in optimizing the translation of discoveries in basic cancer research to clinical practice. This FOA will support CISNET activities in a systematic manner across all four main phases of the translation process (i.e., T1 initial discovery to health application; T2 health application to evidence-based practice guidelines; T3 practice guidelines to health practice; and T4 health practice to population health impact). CISNET models must provide a platform for evaluating the potential downstream consequences of decisions and strategies that are made in earlier phases. Ultimately, applications of these models should provide effective tools for helping to optimize cancer-relevant decisions.

Main areas of focus and key required attributes. Whereas the overall theme of this FOA is similar to the previous issuance of the CISNET Program, there are several important differences. The main characteristics include the following:

Models. Investigators may propose the application, extension, refinement and/or merging of existing models. If well justified, an existing model can be reformulated using a more robust statistical/mathematical framework. However, de novo model development will NOT be supported.
Applicability to Public Health Issues. The emphasis of the proposed research must be on applications of modeling approaches to important public health issues.
Cancer Sites. Each proposed project must be limited to a single eligible cancer site. The eligible six sites include: (a) prostate, colorectal, breast, and lung cancers (i.e., the sites covered by the original CISNET issuance); as well as (b) cervical and esophageal cancers (added for this CISNET re-issuance). Applications focused on other cancer sites are non-responsive to this FOA (and will be returned without review).
Comprehensive Coverage. Each application submitted in response to this FOA is expected to provide a coordinated plan of reasonably comprehensive coverage of the cancer control issues amenable to modeling facing that cancer site (a new requirement for this CISNET re-issuance).
Areas of Interest. There are nine specific areas of interest (see below) that are targeted by this FOA. Each application should provide coverage in as many of these areas as feasible and appropriate for the cancer site of interest. Nonetheless, these areas are listed as suggestive and are not mandatory, i.e. applicants could exclude areas that are less appropriate for a particular cancer site, and add different areas that are more germane.

To facilitate collaborative, transdisciplinary research, comparative modeling, and coverage across the cancer control spectrum and of the specific area of interest, applicants are encouraged to take advantage of the available multiple principal investigator (multiple PD/PIs) option.

This initiative is an open competition FOA and all qualified investigators are invited to apply, regardless of whether or not they were original CISNET awardees.

Background

The Concept of CISNET Program. CISNET program stems from the original concept to create virtual laboratories performing in silico experiments of potential public health strategies. Thus, the CISNET modeling approach advances the practice of modeling to inform clinical and policy decisions. Collaborative, interactive projects involving groups of researchers promote efficient gathering and sharing of the most important data resources, and critical evaluation of the strengths and weaknesses of these resources. A systematic comparative modeling approach brings transparency to the modeling process. The key factor in the CISNET modeling approach is a joint evaluation of results from a range of models, as opposed to a single estimate from one model. This multi-model approach increases the overall credibility of the modeling process, and enhances the accuracy and reproducibility of the results. Obviously, these highly desirable attributes are of fundamental significance for cancer control planning and policy guidelines and decisions.

CISNET models are capable of translating evidence from randomized trials and epidemiological studies to the population setting. Key to such translation is the extrapolation of evidence from tightly controlled studies to the general population accounting for actual usage patterns of these technologies in less controlled settings. Modeling real and hypothetical scenarios allows for the identification of key factors influencing outcomes and efficient cancer control strategies. CISNET research can inform clinical practice and guidelines by synthesizing existing, although often incomplete, knowledge in a modeling framework under clearly specified assumptions, in order to better understand the impact of interventions over the entire life course. This type of information is not directly observable since it involves the pre-clinical natural history of disease, and many studies exclude the elderly and rarely have enough extended follow-up to reflect the full life course of individuals. CISNET provides a suite of models that are able to meet the challenges of the increasing pace of scientific discovery and are poised to address emerging questions, and to determine the most efficient and cost-effective strategies for implementing technologies in the population.

Phases of CISNET Implementation. Initially (2000-2005), CISNET funded projects focused on breast, colorectal, prostate cancers, lung cancers, and colorectal cancers. Support was provided to develop applicable mathematical and statistical methodologies and incorporate those methodologies into multi-cohort population models. During this initial phase, an infrastructure was put into place to facilitate communication among modelers and cross-model comparisons. This phase involved the development of basic mathematical and statistical methodology that is necessary to build multi-cohort population models. Models were validated using available data and applied to the population setting to answer relevant research questions. These initial CISNET projects focused on understanding the impact of interventions (i.e., prevention, screening, and treatment) on current population trends in incidence and mortality.

The next phase (2005-2010) focused on the application of already developed models to study the population impact of existing or emerging cancer control interventions. CISNET II was an opportunity for new applicants who had working models of one of the CISNET cancer sites to apply for funding to join the CISNET consortium as well as for applicants funded under earlier solicitations to be re-funded. CISNET II also provided the opportunity to establish centers that are dedicated to a specific cancer site for coordinating activities such as joint analyses and synthesis papers, collaborations with outside researchers, and group requests for data resources. The goal of CISNET II was to promote the application and extension of models to answer vital questions related to emerging cancer trends, the impact of interventions on future trends, and the identification of optimal strategies for reducing the cancer burden.

Overall Characteristics of the CISNET Approach to Modeling. Major goals of CISNET include building the capacity and an approach for comparative analysis using population-based models to answer important policy-based questions. This CISNET approach to modeling includes the following components:

Flexible broad-based disease models: CISNET models incorporate a central cancer module, which can be modified by the full range of cancer control interventions (i.e., changing risk factor profiles of the population, new screening modalities, and treatment regimens). Outputs can include the full range of the benefits and harms/costs of the interventions. Flexible models of this type can be easily adapted to incorporate the costs, operating characteristics, and unique logistics of emerging technologies as they are developed. For example, colorectal cancer models were easily modified to take into account the unique features of CT Colonography (i.e. virtual colonoscopy), even though this technology was still in its infancy when most of the colorectal models were first being developed.

Multiple birth-cohort modeling: This type of modeling captures a range of birth cohorts and changing risk factor profiles, screening behaviors, and treatments used by each cohort as it ages, allowing investigators to represent the impact(s) of intervention(s) in the actual U.S. population. There is increasing recognition that modeling a single hypothetical cohort often does not fully capture the entire impact and/or potential cost effectiveness of an intervention as implemented in the U.S. population.

Comparative modeling: Independent modeling efforts often yield disparate results that are difficult to reconcile. A comparative modeling approach explores differences between models in a systematic way. Comparative modeling produces a range of results across models and, when consensus can be reached, greatly enhances the credibility of modeling results by highlighting their reproducibility. Disparate results can help to pinpoint areas for which the knowledge base is insufficient and further research is needed. These advantages of the CISNET comparative approach have been recognized by the International Society for Pharmacoeconomics and Outcomes Research (ISPOR) Task Force on Good Modeling Practices.

Transparency in model structure and assumptions: CISNET has developed and implemented standardized model documentation. Model profiles (available online at http://cisnet.cancer.gov/profiles/) are standardized descriptions that facilitate the comparison of models and their results. Users can read documentation about a single model or read side-by-side descriptions that contrast how models address different components of the process. Journal articles seldom contain extensive model descriptions; links from publications to model profiles provide a more complete model description.

Outreach and collaboration: To achieve fully the goals of CISNET, the created modeling capacity/approaches must made available to the research and policy communities through appropriate collaborations. With outreach being one of CISNET’s core values, CISNET initiated a series of webinars to encourage discussions with colleagues in the fields of advocacy, public policy, legislative affairs, cancer control planning, and clinical science on the potential use(s) of CISNET’s decision support tools to guide evidence-based recommendations and cancer control planning. Examples of groups that have collaborated with CISNET include the U.S. Preventive Services Task Force, the Center for Medicare and Medicaid Services, the Division of Cancer Prevention and Control of the Centers for Disease Control and Prevention (CDC), and the American College of Radiology Imaging Network.

Highlights of CISNET Accomplishments: CISNET currently consists of 14 active modeling groups, and 7 affiliate members (who are modeling groups not funded by CISNET but who have joined the collaboration). CISNET investigators have contributed significantly to answering research questions related to modeling the natural history of cancer, performed analyses to synthesize results from both clinical trials and observational studies, and applied their models to answer policy-relevant questions. More information about CISNET accomplishments and the impact of CISNET work can be found at http://cisnet.cancer.gov/ and NIH Publication No. 09-7354 CISNET: The Cancer Intervention and Surveillance Modeling Network Modeling to Guide Public Health Research and Priorities, printed December 2008. Overall, the CISNET program and the resulting collaborations have resulted in numerous publications (over 135 as of May 2009) and created a solid foundation for the use of modeling decision tools for the cancer types covered by the initial focus of the program.

New Challenges for CISNET. There is a continued need for refining CISNET tools and expanding their applicability to synthesize emerging evidence as it becomes becomes available, including such areas as: (a) new cancer control technologies, (b) advances in molecular and biological determinants of cancer risk and prognosis, (c) results from new clinical trials, (d) interesting new trends in cancer incidence, survival, and mortality data (available from sources such as the United States Cancer Statistics (http://apps.nccd.cdc.gov/uscs/) and the NCI’s Cancer Statistics Review (http://seer.cancer.gov/csr/1975_2006/index.html), and (e) other new health-related data. Importantly, the successful testing of CISNET approaches for the initial set of cancer sites, and the maturation of cancer modeling approach, warrants the expansion of the program to cover additional cancer sites.

Specific Objectives, Research Scope, and Requirements for this FOA

All applications submitted in response to this FOA must be focused on the development of cancer control models for one of six selected cancer sites (breast, colorectal, lung, prostate, cervical, or esophageal). To be responsive, each proposed project must be limited to only one of these cancer sites. Applicants should also be aware that the NCI’s general intent is to fund one project per each eligible cancer site.

Modeling efforts proposed must adhere to the definition given above. Most models should include a natural history component, modeling the initiation, growth, and metastatic spread of the tumor, relevant precursor lesions, and biomarkers prior to (and possibly after) detection (although this is not a requirement for all models). Alternatively models without a natural history component can be included, but the application should describe how they complement the suite of models proposed.

Comprehensive Coverage. To meet the objectives of this FOA, applicants are expected to propose collaborative, interactive projects involving groups of researchers that would put forward a program of comparative modeling with coverage across the important cancer control issues and relevant specific focus areas for the selected organ site. The following specific aspects must be addressed in applications:

Investigators responding to this FOA may propose the application, extension, refinement and/or merging of existing models. If well justified, an existing model can be reformulated using a more robust statistical/mathematical framework. This FOA will NOT support the development of models de novo.
The emphasis must be on model applications to important public health issues in the U.S. context. International clinical trials, clinical studies, and health care issues can be included, but applicants should explain how they can serve to inform U.S. policies in related issues.
Beyond currently recognized issues that warrant modeling efforts, proposed projects are expected to address (and cover) emerging issues that will become more important or will become amenable to modeling during the course of the project (reflecting, e.g., the anticipated release of results from a major trial and/or other relevant study results). Consideration should also be given to the ability to scale up to take on new projects when additional funding opportunities arise.
Comprehensive coverage stipulates that proposed projects should, if possible, include in the modeling all the main aspects of the cancer control spectrum (i.e., prevention, screening, diagnosis, treatment, surveillance, and end-of-life care). Not all individual models are expected to cover the full spectrum, and not all portions of the spectrum are equally applicable, or of current critical interest, for all cancer sites. Limited availability of data and studies for certain cancers may limit the ability to include certain areas. Efforts in specific areas should be commensurate with the potential of emerging findings in that area to ameliorate death and suffering from the disease.
To the extent possible, modeling should include the impact of comorbidities (or life expectancy) on relevant issues.
Modeling efforts can focus on interpreting past trends and evolving trends in incidence and mortality, future trends, and informing cancer control and policy related issues.
CISNET applicants are strongly encouraged to form appropriate collaborations, for example, with: (a) investigators who are involved with cancer-relevant clinical prevention, treatment, or screening trials and/or epidemiologic or observational studies; (b) investigators involved in other cancer-relevant programs; (c) policy and/or guideline setting organizations/entities;(d) professional societies; and (d) other relevant government agencies.
In addition to the extension of models and their application, it is essential that the proposed activities emphasize the communication and transfer of modeling results to policy makers and members of other organizations who could utilize the results for decision making.

Targeted Areas of Special Interest: Modeling areas of special interest to this round of CISNET funding include the following:

1) Multi-scale modeling;

2) Incorporating genomic and family history risk profiles;

3) Upstream modeling;

4) Comparative effectiveness and downstream modeling;

5) Evaluation of diagnostic tests;

6) Optimizing biomarker development strategies;

7) Suggesting optimal routes to reducing health disparities;

8) Translation of trial results into clinical guidelines and public health policy; and

9) Interactive policy-level decision making tools.

Details and non-inclusive examples pertaining to these Areas of Special Interests are given below:

(1) Multi-scale modeling: Most CISNET models currently incorporate a tumor growth model, and are intended to project population level results. Applicants to this FOA are encouraged to integrate models developed at the molecular/cellular level into their tumor growth models. Results of multi-scale modeling at this level can help extrapolate the potential impact of basic science discoveries (e.g., mechanistic models of the action of drugs at smaller scales validated against clinical trials). Efforts of this type may help prioritize those basic science developments that show the most promise to have a desirable population impact. Models at these smaller scale levels need not be developed de novo. Rather, when possible, existing models at the molecular/cellular level can be integrated into tumor growth/population level models proposed in response to this FOA. Particularly suitable for these efforts could be models developed under NCI’s Integrative Cancer Biology Program (ICBP) (see http://icbp.nci.nih.gov/) or developed under funding initiatives as part of the Interagency Modeling and Analysis Group (IMAG) (http://www.nibib.nih.gov/Research/MultiScaleModeling/IMAG).

(2) Incorporating genomic and family history risk profiles: Utilizing risk profiles that are based on family history and genomic information has the promise of more effectively targeting prevention, screening, and treatment efforts. Incorporation of information on family history, genomics, and gene environment interactions into cancer models provides a platform for fitting together the pieces of this complex puzzle as it becomes available. Given a rapidly evolving state of knowledge with many gaps, modeling efforts are needed to help make more explicit assumptions about complex phenomena and expose the most important leverage points where knowledge gaps exist. The impact of awareness and appropriate usage of genetic screening tests among both physicians and the general public can also be included in modeling efforts. Examples of efforts of this type of modeling include: Ramsey SD et al., Cancer Epidemiol Biomarkers Prev. (2005); Gorlova OY et al., Hum Hered (2003); and Deng L et al., Int J Cancer (2009).

Some useful resources for this area include the following:

Evaluation of Genomic Applications in Practice and Prevention (EGAPP): an existing evidence-based synthesis and reviews with evidence-based recommendations (http://www.egappreviews.org/). The January 2009 issue of Genetics in Medicine is fully dedicated to EGAPP.

The Human Genome Epidemiology Network (Hu GENet) http://www.cdc.gov/genomics/hugenet/default.htm, and the accompanying informatics/knowledge display tool the Hu GENavigator http://www.hugenavigator.net/ are both very useful in finding genomic associations.

The proceedings of a December 2008 personal genomics workshop at NCI: http://www.cancercontrol.cancer.gov/od/phg/workshop.html

(3) Upstream modeling: Most models proposed in response to this CISNET FOA are expected to start with risk factor trends, screening behavior, and diffusion of new treatment advances. However, the expansion of such models upstream is highly desirable. Upstream modeling can add the social, political, cultural, economic, and individual determinants of risk factor changes, screening behavior, and treatment choices. These determinants put the models a step closer to the specific policies and programs that can help modify these factors in the future, and help evaluate specific programs. Upstream modeling efforts need not be developed de novo, and instead CISNET can integrate existing models or use outputs from other models as input into CISNET models.

(4) Comparative Effectiveness and Downstream Modeling: Comparative effectiveness is a rigorous evaluation of the impact of different options that are available for treating a given medical condition for a particular set of patients. In 2007, the Congressional Budget Office issued a report advocating research on the comparative effectiveness of medical treatments (http://www.cbo.gov/doc.cfm?index=8891). In 2005 AHRQ was authorized to conduct and support research on the outcomes, comparative clinical effectiveness, and appropriateness of health care items and services (including prescription drugs). The idea is to focus on what is known now, ensuring that individual choices and programs benefit from past investments in research and identifying what research gaps are critical to fill. Modeling can assist in extending current evidence from intermediate to long term outcomes, and helping to balance trade-offs (e.g., in prostate cancer treatment radical prostatectomy has been shown to have a survival advantage over watchful waiting, but has tradeoffs in terms of greater urinary and sexual dysfunction). In responding to this FOA, applicants should address the needs of comparative effectiveness research. Modeling groups should consider developing model components that are downstream from the initial diagnosis and staging of disease, including post diagnostic sequalae such as first line treatment, adjuvant therapy, post diagnosis surveillance, treatment at failure of first line therapy or recurrence, side effects of treatment, etc. Modeling can include important issues with respect to choices and quality of care. Examples of studies that can inform this type of modeling include the Prostate Cancer Outcomes Study (PCOS; http://www.cancer.gov/cancertopics/factsheet/pcos) and the Cancer Care Outcomes Research & Surveillance Consortium (CANCORS; http://outcomes.cancer.gov/cancors/).

(5) Evaluation of Diagnostics Tests: Empirical studies of the impact of diagnostic test utilization on patient outcomes are rarely done, because of both methodological and resource considerations. CISNET methods developed in the context of screening could be adapted for use in the diagnostic context and thus provide methods for synthesizing available information from all sources in order to make credible projections about the potential impact of the use of diagnostic tests in clinical practice and to estimate their benefit or cost-benefit profile. Examples of applications could include PET, PET/CT, and MRI for colorectal cancer, MRI and ultrasound for breast cancer, and PET/CT and CT for lung cancer, although this list should just be seen as illustrative. Modeling could be done in the context of technology assessments, when appropriate, as part of National Coverage Determination decisions for the Center for Medicare and Medicaid Services (CMS) (e.g., Decision Memo for Positron Emission Tomography [FDG] for Solid Tumors [CAG-00181R]; go to http://www.cms.hhs.gov/mcd/viewdecisionmemo.asp?from2=viewdecisionmemo.asp&id=218&). A potential partner in these types of modeling issues is the American College of Radiology Imaging Network (ACRIN; go to http://www.acrin.org/).

(6) Optimizing Biomarker Development Strategies: Biomarker development proceeds in five phases: Phase I discovery; Phase II validation; Phase III disease detection in serum from patients in longitudinal cohorts; Phase IV prospective screening studies on biomarker performance in large populations; and Phase V large scale studies to evaluate the role of biomarkers for cancer detection and overall screening impact. Each phase costs significantly more than the prior phase, but yields more information about the operating characteristics and impact of the biomarker. Applicants responding to CISNET FOA may propose efforts to explore how early in the development process reasonable models of the potential cost effectiveness can be developed, thus assisting in decisions of selecting the most promising biomarkers. Potential partners in modeling the potential of biomarkers are researchers in NCI’s Early Detection and Research Network, EDRN ((http://edrn.nci.nih.gov/ ). CISNET models can provide tools for EDRN investigators to project the likely impact of screening tests of given sensitivity on disease-specific deaths, investigate how early in the preclinical period the test needs to become sensitive in order to produce a target benefit in terms of lives saved, given specified test characteristics, project benefits and costs associated with different regimens of screening.

(7) Suggesting optimal routes to reducing health disparities: In response to this FOA, modelers are encouraged to move beyond the standard racial/ethnic characterizations of health disparties, and utilize data sources that will enable modeling as a function of disparities in terms of factors such as income/education, insurance status, and geography. Disparities and their downstream consequences can be studied in terms of smoking rates, obesity, and other risk factors; screening rates; follow-up to abnormal screening; treatment; and quality of care. Modeling efforts can focus on explaining why growing disparities in cancer mortality exist, how disparities can be alleviated in the future, how the mix of cancer control activities which may optimal for the general population can be more appropriately tailored for the needs in specific geographic areas or among population subgroups, or the potential population impact of programs which have shown promise in specific studies. Potential partners for this type of research can be found in programs initiated by the NCI Center to Reduce Cancer Health Disparities (go to http://www.cancer.gov/cancertopics/types/disparities).

(8) Translation of clinical trial results into clinical guidelines and public health policy: The translation of clinical trial results into guidelines and policy recommendations can be facilitated by modeling. In the next several years, the significance of this aspect will likely increase as controlled clinical trial results for PSA screening accrues more follow-up and CT screening for lung cancer in the U.S. and Europe become available. For both prostate and lung cancer screening, overdiagnosis and mortality benefits may coexist, complicating population-level recommendations. Controlled clinical trials in different countries are run under different protocols, and modeling may hold the key to translating results from one trial setting to another and reconciling the impact of putative or actual differences. Guideline setting bodies, such as the U.S. Preventive Services Task Force (USPSTF), contract for evidence reviews to assist in their analysis when specific issues are slated for review. More recently, recognizing that modeling could provide additional useful information by synthesizing information over the course of an entire human lifetime (e.g. different screening scenarios from age 40 to 80) modeling results have also been included in the USPSTF deliberations. One of the goals for this FOA is to promote collaborations that would facilitate the tasks of guideline setting bodies by integrating work from modelers evidence review groups, clinical trials, and ongoing studies of how screening and the follow-up of abnormal results operates in population-based settings. Potential collaborators for this latter type of analysis include groups such as the Breast Cancer Surveillance Consortium (BCSC) that collect population based data on screening utilization and test characteristics linked to cancer outcomes, (go to http://breastscreening.cancer.gov/). Therefore, applicants are encouraged to seek respective collaborations (to be documented by letters of support and evidence of intended working relationships with professional societies and guideline-setting bodies).

(9) Interactive policy-level decision-making tools: Another area of priority is the development of interactive interfaces for models that would allow cancer control planners and policy makers to explore the impact of varying key parameters involved in their decision-making options. These tools must be designed so as to facilitate evidence-based decisions, while ensuring that they are understandable and relevant for the target audiences. For this goal, it may not be necessary to design complete interfaces to models, but rather provide interactive reporting tools to visualize the pre-analyzed results for a specific set of relevant scenario/input conditions An example of an interactive interface to a pre-assembled set of outcome data is the CISNET colorectal cancer projections website(Go to http://cisnet.cancer.gov/projections/colorectal/).

Applicants should balance the tradeoffs of broad coverage across these areas with more focused efforts in a narrow range of areas. They should explain how those tradeoffs decisions were made in terms of the potential public health importance of the areas selected, as well as other considerations used in determining the breadth and depth of areas covered. The list of suggested areas is not binding, i.e. applicants could exclude areas that are less appropriate for a particular cancer site, and add different areas that are more germane.

Organizational Structure of Proposed CISNET Teams

Each applicant team must propose two types of components:

Modeling Groups (approximately two to five groups per application); and
A Coordinating Center (one per application).

Modeling Groups: Multiple modeling groups are needed to meet the requirements of comparative modeling as well as to allow coverage across the important cancer control issues and relevant specific focus areas for the selected cancer site. For the purpose of this FOA, a modeling group is defined as a group of researchers using a single model or a set of related models that are applicable to cancer control and/or policy related issues. A modeling group may include investigators from a single institution or multiple institutions. For example, if a policy level model will incorporate new model subcomponents (e.g., an upstream model or a model developed at the cellular level) then the builders of those subcomponents could be considered part of the same modeling group, even if they are at a different institution.

Applicants should carefully consider how many modeling groups to include, as this element will be an important consideration in the evaluation of applications. Too few groups may make it difficult to conduct comparative modeling, and to provide adequate coverage of the range of relevant topics for that cancer site. Too many groups may make collaboration, communications, and consensus difficult. The applicant team will need to jointly decide which areas are important and central enough to warrant full bases cases, i.e., collaborative modeling exercises among the all the modeling groups , which areas warrant mini-base cases , among a subset of the models, and which areas it will be sufficient for a single group to cover. Proposed CISNET teams should generally have between two to five modeling groups. Within this general guideline, applicants are expected to present a coherent and well thought out plan that will permit group work to proceed efficiently. Thus, applicants need to show how the type and number of modeling groups proposed can provide reasonable coverage (as defined above). In addition, these groups should be sufficient to provide enough diversity to conduct useful comparative analyses, but should not duplicate efforts. (For specific budget guidelines for modeling groups, see Section IV.5 - Funding Restrictions.)

Coordinating Centers: Each proposed CISNET team must include a coordinating center, which must be at the institution submitting the CISNET application in response to this FOA. Generally, the coordinating center can be led by the lead investigator (PI) of the modeling group(s) from the application submitting institution (although separate budgets are required for both components, see Section IV.5 Funding Restrictions). Applicants must plan for and describe in their applications the following coordination activities of the Center (which must include the priorities of the CISNET program and consensus of the leaders of the modeling groups of the applicant team):

Formulating, prioritizing, and coordinating work on base case and other questions (including outside requests with new funding opportunities);
Negotiating common requests for outside data sources;
Consensus building and coordinating critical evaluation of disparate results;
Preparing inputs and collecting and processing common outputs for model comparisons;
Coordinating synthesis papers and group responses bringing together disparate information to inform policy makers; and
Organizing conference calls and setting meeting agendas.

Although the coordinating center will provide an oversight, it is expected that certain coordination activities will be distributed across the modeling groups. For example, if there is a collaborative modeling activity among two groups, coordination of that work might be done by one of the modeling groups rather than through the coordinating center. If a meeting is held at a particular PD/PI’s institution, that group would be responsible for making local arrangements. Local specialized expertise included under one PD/PI (e.g., specific clinical expertise, an actuary, or demographer) might be shared across the group.

Because coordination activities will be somewhat decentralized, the budget for the coordinating center is expected to be relatively modest in Year 1. However, the ability of the coordinating center to direct funds to high priority areas will be enhanced in years 2-5 with the addition of discretionary funds. (See Section IV. 5. Funding Restrictions for budget guidelines for coordinating centers and discretionary funds.)

The coordinating center will be able to allocate discretionary funds for centralized administrative and scientific coordination, but will also be able to utilize these funds to tap outside expertise for particular tasks, pay for access to data sources, and provide funds to modeling groups to mount important efforts not originally anticipated. Through the coordinating center, each CISNET cancer site group will constitute an established expert knowledge base that can provide technical advice on evolving policy-relevant cancer control and surveillance questions. Even though one group will be tasked with being the coordinating center, CISNET would be run through consensus, as it has in the past.

See Section VIII, Other Information - Required Federal Citations, for policies related to this announcement.

Section II. Award Information

1. Mechanism of Support

This funding opportunity will use the NIH U01 award mechanism. The Project Director/Principal Investigator (PD/PI) will be solely responsible for planning, directing, and executing the proposed project.

This FOA uses Just-in-Time information concepts. It also uses non-modular budget formats described in the PHS 398 application instructions (see http://grants.nih.gov/grants/funding/phs398/phs398.html).

This funding opportunity will use a cooperative agreement award mechanism. In the cooperative agreement mechanism, the Project Director/Principal Investigator (PD/PI) retains the primary responsibility and dominant role for planning, directing, and executing the proposed project, with NIH staff being substantially involved as a partner with the Principal Investigator, as described under the Section VI. 2. Administrative Requirements, "Cooperative Agreement Terms and Conditions of Award."

2. Funds Available

The estimated amount of funds available for support of approximately 6 projects awarded as a result of this announcement is $5.4 million for fiscal year 2010 and $6.0 million for fiscal years 2011 through 2014, although amounts will depend on annual appropriations.

The NCI’s general intent is to fund not more than one project for the modeling of each of the identified cancer types.

Applicants may request project periods of up to 5 years and budget for up to $1.3M total costs for the first year. For more details on the budget restrictions, see Section IV.5 - Funding Restrictions of this FOA.

Because the nature and scope of the proposed research will vary from application to application, it is anticipated that the size and duration of each award will also vary.

Although the financial plans of the NCI provide support for this program, awards pursuant to this funding opportunity are contingent upon the availability of funds and the receipt of a sufficient number of meritorious applications.

NIH grants policies as described in the NIH Grants Policy Statement will apply to the applications submitted and awards made in response to this FOA.

Section III. Eligibility Information

1. Eligible Applicants

1.A. Eligible Institutions

The following organizations/institutions are eligible to apply:

Public/State Controlled Institutions of Higher Education
Private Institutions of Higher Education
Nonprofits with 501(c)(3) IRS Status (Other than Institutions of Higher Education)
Nonprofits without 501(c)(3) IRS Status (Other than Institutions of Higher Education)
Small Businesses
For-Profit Organizations (Other than Small Businesses)
State Governments
U.S. Territory or Possession
Non-domestic (non-U.S.) Entities (Foreign Organizations)
Other(s):
- Eligible Agencies of the Federal Government
- Units of Local Governments

1.B. Eligible Individuals

Any individual with the skills, knowledge, and resources necessary to carry out the proposed research as the PD/PI is invited to work with his/her institution to develop an application for support. Individuals from underrepresented racial and ethnic groups as well as individuals with disabilities are always encouraged to apply for NIH support.

More than one PD/PI, or multiple PDs/PIs, may be designated on the application for projects that require a team science approach and therefore clearly do not fit the single-PD/PI model. Additional information on the implementation plans, policies and procedures to formally allow more than one PD/PI on individual research projects is available at http://grants.nih.gov/grants/multi_pi. All PDs/PIs must be registered in the NIH eRA Commons prior to the submission of the application (see http://era.nih.gov/ElectronicReceipt/preparing.htm for instructions).

The decision of whether to apply for a grant with a single PD/PI or multiple PDs/PIs is the responsibility of the investigators and applicant organizations, and should be determined by the scientific goals of the project. Applications for grants with multiple PDs/PIs will require additional information, as outlined in the instructions below. The NIH review criteria for approach, investigators, and environment have been modified to accommodate applications involving either a single PD/PI or multiple PDs/PIs. When considering multiple PDs/PIs, please be aware that the structure and governance of the PD/PI leadership team as well as the knowledge, skills and experience of the individual PDs/PIs will be factored into the assessment of the overall scientific merit of the application. Multiple PDs/PIs on a project share the authority and responsibility for leading and directing the project, intellectually and logistically. Each PD/PI is responsible and accountable to the grantee organization, or, as appropriate, to a collaborating organization, for the proper conduct of the project or program, including the submission of required reports. For further information on multiple PDs/PIs, please see http://grants.nih.gov/grants/multi_pi.

2. Cost Sharing or Matching

This program does not require cost sharing as defined in the current NIH Grants Policy Statement.

3. Other-Special Eligibility Criteria

Number of Applications. Applicants may submit more than one application, provided each application is scientifically distinct.

Resubmissions. Resubmission applications are not permitted in response to this FOA.

Renewals. Renewal applications are not permitted in response to this FOA. Even applications from current CISNET awardees will be considered as new applications.

Section IV. Application and Submission Information

1. Address to Request Application Information

The PHS 398 application instructions are available at http://grants.nih.gov/grants/funding/phs398/phs398.html in an interactive format. Applicants must use the currently approved version of the PHS 398. For further assistance, contact GrantsInfo -- Telephone: (301) 710-0267; Email: [email protected].

Telecommunications for the hearing impaired: TTY 301-451-5936.

2. Content and Form of Application Submission

Applications must be prepared using the current PHS 398 research grant application instructions and forms with exceptions defined below. Applications must have a D&B Data Universal Numbering System (DUNS) number as the universal identifier when applying for Federal grants or cooperative agreements. The D&B number can be obtained by calling (866) 705-5711 or through the web site at http://www.dnb.com/us/. The D&B number should be entered on line 11 of the face page of the PHS 398 form.

The title and number of this funding opportunity must be typed in item (box) 2 only of the face page of the application form and the YES box must be checked.

Foreign Organizations (i.e., Non-Domestic [non-U.S.] Entities)

NIH policies concerning grants to Foreign (non-U.S.) organizations can be found in the NIH Grants Policy Statement at http://grants.nih.gov/grants/policy/nihgps_2003/NIHGPS_Part12.htm#_Toc54600260.

Applications from foreign organizations must:

Request budgets in U.S. dollars; and
Contain detailed budgets (see NOT-OD-06-096).

In addition, for applications from Foreign organizations, the following requirements apply.

Charge back of customs and import fees is not allowed.
Every effort should be made to comply with the format specifications, which are based upon a standard U.S. paper size of 8.5 x 11 within each PDF.
Funds for up to 8% Facilities and Administrative (F&A) costs (excluding equipment) may be requested. See NOT-OD-01-028, March 29, 2001.
Organizations must comply with Federal/NIH policies on human subjects, animals, and biohazards.
Organizations must comply with Federal/NIH biosafety and biosecurity regulations. See Section VI.2., Administrative and National Policy Requirements.

Proposed research should provide special opportunities for furthering research programs through the use of unusual talent, resources, populations, or environmental conditions in other countries that are not readily available in the United States or that augment existing U.S. resources.

SPECIAL INSTRUCTIONS

Applications with Multiple PDs/PIs

When multiple PD/PIs are proposed, use the Face Page-Continued page to provide items 3a 3h for all PD/PIs. NIH requires one PD/PI be designated as the contact PD/PI for all communications between the PD/PIs and the agency. The contact PD/PI must meet all eligibility requirements for PD/PI status in the same way as other PD/PIs, but has no special roles or responsibilities within the project team beyond those mentioned above. The contact PD/PI may be changed during the project period. The contact PD/PI should be listed in block 3 of Form Page 1 (the Face Page), with all additional PD/PIs listed on Form Page 1-Continued. When inserting the name of the PD/PI in the header of each application page, use the name of the Contact PD/PI, et. al. The contact PD/PI must be from the applicant organization if PD/PIs are from more than one institution.

All individuals designated as PD/PI must be registered in the eRA Commons and must be assigned the PD/PI role in that system (other roles such as SO or IAR will not give the PD/PI the appropriate access to the application records). Each PD/PI must include their respective eRA Commons ID in the eRA Commons User Name field.

All projects proposing Multiple PDs/PIs will be required to include a new section describing the leadership plan approach for the proposed project.

Multiple PD/PI Leadership Plan: For applications designating multiple PDs/PIs, a new section of the research plan, entitled Multiple PD/PI Leadership Plan must be included. A rationale for choosing a multiple PD/PI approach should be described. The governance and organizational structure of the leadership team and the research project should be described, and should include communication plans, process for making decisions on scientific direction, and procedures for resolving conflicts. The roles and administrative, technical, and scientific responsibilities for the project or program should be delineated for the PDs/PIs and other collaborators.

If budget allocation is planned, the distribution of resources to specific components of the project or the individual PDs/PIs should be delineated in the Leadership Plan. In the event of an award, the requested allocations may be reflected in a footnote on the Notice of Award.

Additional information is available in the PHS 398 grant application instructions.

3. Submission Dates and Times

Applications must be received on or before the receipt date described below (Section IV.3.A). Submission times N/A.

3.A. Receipt, Review, and Anticipated Start Dates
Letters of Intent Receipt Date: October 3, 2009
Application Receipt Date: November 3, 2009
Peer Review Date(s): February/March 2010
Council Review Date: May 2010
Earliest Anticipated Start Date: September 2010

3.A.1. Letter of Intent

Prospective applicants are asked to submit a letter of intent that includes the following information:

Descriptive title of proposed research;
Name(s), address(es), and telephone number(s) of the Principal Investigator(s);
Names of other key personnel;
Participating institutions; and
Number and title of this funding opportunity.

Although a letter of intent is not required, is not binding, and does not enter into the review of a subsequent application, the information that it contains allows NCI staff to estimate the potential review workload and plan the review.

The letter of intent is to be sent by the date listed in Section IV.3.A.

The letter of intent should be sent to:

Eric J. (Rocky) Feuer, Ph.D.
Division of Cancer Control and Population Sciences
National Cancer Institute
Surveillance Research Program
Division of Cancer Control and Population Sciences
National Cancer Institute
6116 Executive Blvd, Room 5041, MSC 8317
Bethesda, MD 20892-8317 (for U.S. Postal Service express and regular mail)
Rockville, MD 20852 (for non-U.S.P.S. delivery)
Phone: 301-496-5029 or 301-435-7739
Fax: 301-480-2046
Email: [email protected]

3.B. Sending an Application to the NIH

Applications must be prepared using the forms found in the PHS 398 instructions for preparing a research grant application. Submit a signed, typewritten original of the application, including the checklist, and three signed photocopies in one package to:

Center for Scientific Review
National Institutes of Health
6701 Rockledge Drive, Room 1040, MSC 7710
Bethesda, MD 20892-7710 (U.S. Postal Service Express or regular mail)
Bethesda, MD 20817 (for non-U.S.P.S. delivery)

Personal deliveries of applications are no longer permitted (see http://grants.nih.gov/grants/guide/notice-files/NOT-OD-03-040.html).

At the time of submission, two additional copies of the application and all copies of the appendix material must be sent to:

Referral Officer
Division of Extramural Activities
National Cancer Institute
6116 Executive Boulevard, Room 8041, MSC 8329
Bethesda, MD 20892-8329 (for U.S. Postal Service regular or express mail)
Rockville, MD 20852 (for non-USPS delivery)
Telephone: (301) 496-3428
Fax: (301) 402-0275
Email: [email protected]

3.C. Application Processing

Applications must be received on or before the application receipt date described above (Section IV.3.A.). If an application is received after that date, the application may be delayed in the review process or not reviewed. Upon receipt, applications will be evaluated for completeness by the CSR and for responsiveness by the reviewing Institute Incomplete and/or non-responsive applications will not be reviewed.

The NIH will not accept any application in response to this funding opportunity that is essentially the same as one currently pending initial review, unless the applicant withdraws the pending application. However, when a previously unfunded application, originally submitted as an investigator-initiated application, is to be submitted in response to a funding opportunity, it is to be prepared as a NEW application. That is, the application for the funding opportunity must not include an Introduction describing the changes and improvements made, and the text must not be marked to indicate the changes from the previous unfunded version of the application.

Information on the status of an application should be checked by the Principal Investigator in the eRA Commons at https://commons.era.nih.gov/commons/.

4. Intergovernmental Review

This initiative is not subject to intergovernmental review.

5. Funding Restrictions

All NIH awards are subject to the terms and conditions, cost principles, and other considerations described in the NIH Grants Policy Statement. The Grants Policy Statement can be found at NIH Grants Policy Statement.

Pre-award costs are allowable. A grantee may, at its own risk and without NIH prior approval, incur obligations and expenditures to cover costs up to 90 days before the beginning date of the initial budget period of a new award if such costs: 1) are necessary to conduct the project; and 2) would be allowable under the grant, if awarded, without NIH prior approval. If specific expenditures would otherwise require prior approval, the grantee must obtain NIH approval before incurring the cost. NIH prior approval is required for any costs to be incurred more than 90 days before the beginning date of the initial budget period of a new award.

The incurrence of pre-award costs in anticipation of a competing or non-competing award imposes no obligation on NIH either to make the award or to increase the amount of the approved budget if an award is made for less than the amount anticipated and is inadequate to cover the pre-award costs incurred. NIH expects the grantee to be fully aware that pre-award costs result in borrowing against future support and that such borrowing must not impair the grantee's ability to accomplish the project objectives in the approved time frame or in any way adversely affect the conduct of the project (see the NIH Grants Policy Statement at http://grants.nih.gov/grants/policy/nihgps_2003/NIHGPS_Part6.htm).

Specific Funding Restrictions for this FOA. Awards are limited to $1.3 million total costs in year 1. It is anticipated that most applicants will request budgets in the range from $600K to $1.2 million total cost in year 1. Additional justification should be given for a large number of modeling groups and budgets close to the maximum.

The budget of individual modeling groups should generally not exceed $275K in total costs in year 1, with up to 3% annual increases per year in years 2-5. (Budget requests for modeling groups with limited anticipated roles should be substantially smaller.)

The budget of the coordinating centers should generally not exceed $125K in total costs in year 1, with up to 3% annual increases after that. On the top of these costs, discretionary funds are to be budgeted starting in Year 2. Total costs in Year 2 for discretionary funds cannot exceed 11% of the total budget of the entire application in Year 1, and can increase up to 3% annually in Years 3-5. In principle, the discretionary funds should remain unallocated (i.e., listed as Other Expenses in the budgetary requests). However, if necessary and justified, applicants may budget up to 50% of the discretionary funds to supplement specific regular coordination activities.

6. Other Submission Requirements

Modifications to PHS398 Instructions for Application Preparation

Table of Contents (PHS 398 Form Page 3): Modify Form Page 3 of the PHS 398 to replace standard Items 2-5 of the PHS 398 Research Plan with the following new sections:

Section N1. Overall Objectives, Significance, and Specific Aims
Section N2. Team Leadership and Coordinating Center
Section N3. Proposed Models and Previous Model Applications
Section N4. Proposed Model Extensions, Applications and Comparative Modeling

Budget (PHS 398 Form Pages 4 and 5): Follow the current PHS 398 instructions to provide a detailed budget (direct costs) for the entire application for the first 12-month period (Form page 4) and the entire proposed project period (Form page 5). Include appropriate budget pages for any subcontractual arrangements proposed.

Use additional Form Pages 4 and 5 to provide detailed separate budget information (first year and cumulative budgets for the entire project period) for the following individual application components:

Separately for each proposed modeling group; and
Separately for the Coordination Center (include discretionary funds allowable for years 2-5)

RESEARCH PLAN: The standard PHS398 Research Plan (Items 2-5 as per Revision 11/07 of the PHS 398 Table of Contents) is altered as follows:

Standard Items 2-5 of the PHS 398 Research Plan are replaced by the new Sections N1-N4 (specified below)
The PHS 398 standard page limit for Items 2-5 is replaced by a new limit of 55 pages to encompass the combination of the new Sections N1-N4.

Note: Within the stated overall page limit, numbers of pages suggested in the text below for individual sections are provided solely as a nonbinding guidance for applicants. Applicants are encouraged to use the minimum number of pages necessary to describe the research plan clearly and succinctly.

Other items of the PHS398 Research Plan remain unmodified.

Section N1. Overall Objectives, Significance, and Specific Aims

Briefly sketch the background leading to the present application, critically evaluate existing knowledge, and specifically identify the gaps that the project is intended to fill. State concisely the importance and health relevance of the research described in this application by relating the specific aims to the broad, long-term objectives. If the aims of the application are achieved, state how scientific knowledge, public health guidelines or clinical practice will be advanced. Describe the effect of these studies on the concepts, methods, technologies, treatments, services or preventative interventions for this specific cancer site.

List the broad, long-term objectives and the goal of the specific research proposed. The goals should be stated in both in terms of the modeling work that needs to be done, but also in terms of the broader objective of the modeling exercise. There can be general aims, with sub-aims if that structure is useful

This section is suggested to comprise approximately two to four pages.

Section N2. Team Leadership and Coordinating Center

This section should describe how the activities across the modeling groups will be integrated and coordinated. It will describe not only the activities of the coordinating center, but also how some of the coordination activities will be shared across the modeling groups. The processes for decision making should be described, all well as plans and processes for spending of discretionary funds should be outlined. Even though some of the discretionary funds should remain unallocated, it is appropriate to assign (in the budget request) the remaining balance of these funds to specific, regular coordination activities that are anticipated.

This section should be approximately 2-4 pages.

Section N3. Proposed Models and Previous Model Applications

This section should give an overview of each model, the accomplishments of each modeling group, and if the group or subgroups have worked together previously, the joint accomplishments. A summary of underling model structures and assumptions must be clearly stated in the application. This section should also give a synthesis of why these models complement each other in terms of providing implementations of different modeling perspectives, or different ways of synthesizing available evidence. Additional pages can be devoted to cross model summaries. It may be useful to consecutively place all the model descriptions together, followed by all the model applications. Each of these subsections (i.e., model description and model applications) should be concluded with summary comments on the breadth and depth of prior work. A table summarizing key modeling differences and similarities, and another table summarizing areas of model applications could be useful in providing a summary at a glance.

The length of this section will vary with the number of modeling groups included in the application.

Section N4. Proposed Model Extensions, Applications and Comparative Modeling

This section is meant to describe models extensions, additional model calibration, or validation, and combining of models (if applicable). It is also meant to describe model applications, development of user interfaces, web sites, and plans to disseminate and effectively communicate the results of modeling to planners and policy makers. To summarize the efforts and demonstrate coverage, applicants are encouraged to provide a table with the rows indicating projects, and the columns including items such as the project title, areas of coverage (e.g., prevention/screening/ treatment and/or which of the nine special target areas it represents), modeling groups included, timeline, coordinator, etc. The applicant group will need to jointly decide which areas are important and central enough to warrant full bases cases, i.e., collaborative modeling exercises among the entire group, which areas warrant mini-base cases, among a subset of the models, and which areas it will be sufficient for a single group to cover. Collaborations with outside groups for specific applications should be described.

Other Budgetary Requirements

Applicants must plan to participate in two consortium meetings per year, including: (1) an annual meeting (approximately 3 days) in which awardees focused on all four cancer sites will meet together; and (2) a mid-year meeting (approximately 2 days) when awardees focused on each cancer site meet separately. For purposes of budgeting, funds should be requested for up to three persons per modeling group to travel to each of these two meetings.

Appendix Materials

All paper PHS 398 applications must provide appendix material on CD only, and include five identical CDs in the same package with the application (see http://grants.nih.gov/grants/guide/notice-files/NOT-OD-08-031.html).

Do not use the Appendix to circumvent the page limitations of the Research Plan component. An application that does not observe the required page limitations may be delayed in the review process.

Resource Sharing Plan(s)

NIH considers the sharing of unique research resources developed through NIH-sponsored research an important means to enhance the value of, and advance research. When resources have been developed with NIH funds and the associated research findings published or provided to NIH, it is important that they be made readily available for research purposes to qualified individuals within the scientific community. If the final data/resources are not amenable to sharing, this must be explained in Resource Sharing section of the application (see http://grants.nih.gov/grants/policy/data_sharing/data_sharing_faqs.htm).

(a) Data Sharing Plan: Regardless of the amount requested, investigators are expected to include a brief 1-paragraph description of how final research data will be shared, or explain why data-sharing is not possible. Applicants are encouraged to discuss data-sharing plans with their NIH program contact (see Data-Sharing Policy or http://grants.nih.gov/grants/guide/notice-files/NOT-OD-03-032.html).

(b) Sharing Model Organisms: Regardless of the amount requested, all applications where the development of model organisms is anticipated are expected to include a description of a specific plan for sharing and distributing unique model organisms and related resources, or state appropriate reasons why such sharing is restricted or not possible (see Sharing Model Organisms Policy, and NIH Guide NOT-OD-04-042).

(c) Genome-Wide Association Studies (GWAS): Regardless of the amount requested, applicants seeking funding for a genome-wide association study are expected to provide a plan for submission of GWAS data to the NIH-designated GWAS data repository, or provide an appropriate explanation why submission to the repository is not possible. A genome-wide association study is defined as any study of genetic variation across the entire genome that is designed to identify genetic associations with observable traits (such as blood pressure or weight) or the presence or absence of a disease or condition. For further information, see Policy for Sharing of Data Obtained in NIH Supported or Conducted Genome-Wide Association Studies, NIH Guide NOT-OD-07-088, and http://grants.nih.gov/grants/gwas/.

Additional Resource Sharing Requirements

In addition to the stated NIH wide requirements, applicants responding to this FOA are expected to work consistently towards achieving the programmatic goals of CISNET. The NCI is committed to the transparency of models, and dissemination of modeling results, model runs and software whenever possible to the scientific community. It is recognized, however, that there are no standards for the release of complex microsimulation models, but that the development of policies, methods and standards for model sharing are critically important for CISNET.

All applicants should provide a plan for the dissemination of models and modeling results. This plan should address the following four components: (1) enhancing understanding of model structure by keeping up to date versions of documentation on the Model Profiler; (2) active solicitation of inquiries from those outside of CISNET to pose questions or scenarios (possibly based on national or regional issues of interest) amenable to modeling; (3) enhancing the ability of others to run the models directly by developing public versions of executable programs of model or model subcomponents when feasible; and (4) enhancing access to source code by releasing code in the context of collaborations or other specified scenarios. Component (3) above could be addressed in a number of different ways, including development of interactive decision making tools (see area of emphasis #9 in Section I.1 Research Objectives Specific Objectives, Research Scope, and Requirements), possibly with access to a limited set of parameters or a set of pre-determined set of runs for which the results have already been assembled. Applicants should describe how each of these components would be achieved, and could add other components as well. For some aspects of this plan, it is reasonable to assume that interested users may need to provide funding. Applicants should indicate that they will work toward achieving caBIG compatibility (https://cabig.nci.nih.gov/).

Applicants should also indicate their willingness to abide by any additional software and model release policies developed by the CISNET steering committee.

Specific Instructions for Foreign Applications

All foreign applicants must complete and submit budget requests using the Research & Related Budget component found in the application package for this FOA (see NOT-OD-06-096, August 23, 2006).

Section V. Application Review Information

1. Criteria

Only the review criteria described below will be considered in the review process.

2. Review and Selection Process

Applications that are complete and responsive to the FOA will be evaluated for scientific and technical merit by an appropriate peer review group convened by the National Cancer Institute and in accordance with NIH peer review procedures (http://grants1.nih.gov/grants/peer/), using the review criteria stated below.

As part of the scientific peer review, all applications will:

Undergo a selection process in which only those applications deemed to have the highest scientific and technical merit, generally the top half of applications under review, will be discussed and assigned a priority score;
Receive a written critique; and
Receive a second level of review by National Cancer Advisory Board.

The following will be considered in making funding decisions:

Scientific and technical merit of the proposed project as determined by peer review;
Availability of funds;
Coverage across the six cancer sites included in this FOA with priority to the sites with high incidence and mortality;
Relevance of the proposed project to program priorities;
Compliance with resource sharing requirements.

The mission of the NIH is to support science in pursuit of knowledge about the biology and behavior of living systems and to apply that knowledge to extend healthy life and reduce the burdens of illness and disability. As part of this mission, applications submitted to the NIH for grants or cooperative agreements to support biomedical and behavioral research are evaluated for scientific and technical merit through the NIH peer review system.

Overall Impact. Reviewers will provide an overall impact score to reflect their assessment of the likelihood for the project to exert a sustained, powerful influence on the research field(s) involved, in consideration of the following five core review criteria, and additional review criteria (as applicable for the project proposed).

Core Review Criteria. Reviewers will consider each of the five review criteria below in the determination of scientific and technical merit, and give a separate score for each. An application does not need to be strong in all categories to be judged likely to have major scientific impact. For example, a project that by its nature is not innovative may be essential to advance a field.

Significance. Does the project address an important problem or a critical barrier to progress in the field? If the aims of the project are achieved, how will scientific knowledge, technical capability, and/or clinical practice be improved? How will successful completion of the aims change the concepts, methods, technologies, treatments, services, or preventative interventions that drive this field?