Development of an Acquisition Instrumentation Program

L. Amelia Dempere, Director, Research Services Centers, Herbert Wertheim College of Engineering, University of Florida

Dr. Dempere first suggested that it is helpful to seek participation on a panel evaluating grant proposals to any of the major funding agencies. This can be done by communicating with the Program Manager of a program in an agency that you are interested in learning more about. Secondly, she advises to propose something unique because it is not sufficiently persuasive to just request the replacement of an old instrument for one newer. A good path is to use a combination of techniques in an instrument that will enable research approaches that the PIs and your institution want to become known for. Be sure to clearly state who will benefit from the new instrument: will it be only internal users and collaborators or will users from other institutions benefit. Third, Dr. Dempere reminds us that having suitable space for the instruments and a strong broader impact plan are important in the proposal. Use your 15 pages wisely by showing strategic figures and visuals that reduce lengthy descriptions and explanations.

Acquisition of a Microscope for In Situ Studies of Hard and Soft Matter

James M. LeBeau, Associate Director, Analytical Instrumentation Facility, North Carolina State University

Dr. LeBeau started by telling us that we should have a broad range of capabilities that our institution is interested in covering with the instrument we are requesting money for and that we need to be sure to explain each in detail in our proposal. Make a statement about the proposed new capabilities versus the old ones. It is best if you can be unique in your area for capabilities. One secret that he shared is that the instrument that you request does not have to be state-of-the-art, it simply needs to cover your requirements. Dr. LeBeau recommends a primary focus on three to five key ideas with a core group of researchers. Be sure to include the grant numbers that the instrument will impact. Preliminary data is another big item that you want to be sure to add to your proposal where possible. Further suggestions are: plan your submission early so that you can include your researchers and their data; determine if your institution has an internal competition that you must participate in before actual submission to the granting agency; and make a plan to integrate the requested instrument into the Core Facility on your campus.

A New Field Emission Scanning Electron Microscopy Facility with STEM and EDS Capabilities for Interdisciplinary Research and Education at Towson University Vonnie D. Shields, Associate Dean and Professor of Biology, Towson University

Dr. Shields spoke to the audience about five interdisciplinary female faculty members from Towson University who were awarded an NSF MRI award. Among her recommendations were: know your institution's classification and its limits for applications so you can choose the NSF Division that best suits the needs of your researchers as well as your institution. It is important to negotiate the cost sharing upfront with your administration so that your proposal meets this requirement. She recommends doing homework on which instrument will best suit your needs by creating a rapport with the vendors, discussing your needs, visiting sites for demonstrations, and sending samples to obtain a data set for your projects to show what is possible if you receive the award. Their proposal discussed the research of each member and included letters of support from other colleges and collaborators to show a broader impact for the instrument. Also discussed were the teaching and outreach activities that would be impacted by the instrument. Be sure to include all the people and groups who will benefit from the instrument.

A Guide to Submitting a Successful NIH S10 Shared Instrumentation Grant Application

Frank P. Macaluso, Director, Electron Microscopy Analytical Imaging Facility, Albert Einstein College of Medicine

Mr. Macaluso provided listeners with many good tips on writing a successful instrumentation grant, drawing on knowledge from several successful awards. Always follow the details and directions for the program that you are applying to. Plan your proposal early so that all of the participants and components are ready to go before the deadline. He recommends that you choose your PIs with purpose; select major users whose grant-funded research can be impacted by the instrument. Demos will help you and your researchers obtain preliminary data to show this impact. The directors from his Core wrote the majority of the proposal with assistance from the PIs who wrote several pages about their research. The directors were sure to include information on the technical expertise of their staff who will enable the best utilization of the instrument. You should state the business model for your Core to help the proposal reviewers understand how the instrument will be used at your institution. All of this is your justification to demonstrate your institution's need for this instrument. Mr. Macaluso suggested that we obtain technical specifications from the vendors of like instruments, compare them, and indicate which would best serve the needs of the institution. Don't forget that a letter of support and approval for your proposal submission from your institution along with a financial commitment are very important.

Opportunities for Instrumentation Funding

Robert Kokoska, Program Manager for Microbiology, Life Sciences Division, US Army Research Office (https://www.onr.navy.mil/Science-Technology/Directorates/office-research-discovery-invention/Sponsored-Research/University-Research-Initiatives/DURIP.aspx)

Dr. Kokoska, from US Army Research Office (ARO), described the Defense University Research Instrumentation Program (DURIP) as a source for instrumentation funding that can provide new capabilities in support of Army-relevant high-risk, high-payoff basic research at universities. There are a number of important elements that go into a successful DURIP proposal. These include a detailed description of the supporting research and how it supports the Army mission; details about the impact that the instrumentation will have on the described research and that of others at the same institution as a shared resource; and the educational opportunities that the instrument will provide. A discussion with the ARO program manager whose program aligns with an investigator's research area of interest is highly recommended to ensure that a proposal is competitive and meets the goals of ARO. This program funded 40–50 proposals in 2017 at an average of $150,000. The most up-to-date information on the DURIP program can be found in the Army Research Office Broad Agency Announcement. The DURIP announcements are usually posted every year in the March/April timeframe.

The Major Instrumentation Program at the National Science Foundation

Guebre X. Tessema, Program Director, Division of Materials Research, National Science Foundation (https://www.nsf.gov/funding/pgm_summ.jsp?pims_id=6672) NSF18-513

Dr. Tessema spoke to the audience about the NSF Major Instrumentation Program. There are two tracks for different amounts of money: Track 1 for $100,00–$1,000,000 and Track 2 for $1,000,000–$4,000,000. This competitive program received 850 proposals in 2017 across all fields supported by NSF and funded about 134 (17%). The proposals are reviewed January to May each year. He describes this program as one designed to support proposals to purchase or develop instruments for broad, interdisciplinary research. You should include a management plan for the instrument, the IT required, the staff, the cost structure, the space for the instrument, the number of expected users, and the plan for instrument access. For PhD granting institutions, there should be a 30% cost-sharing in the plan from your institution, using funds from non-federal sources, and you need to show a track record of support by the institution as well as good stewardship of previous MRI awards. For instrument development, your proposal should push the state-of-the-art beyond what is currently commercially available. In describing the intellectual merit (the science) in an NSF supported field, be sure to address the “So What?” factor to explain the impact of the instrument that you would like to acquire, purchase, or develop. The NSF MRI program review criteria include a broader impact component. This includes the broader scientific and technical impact as well as the impact on education and training of a diverse, broad workforce. How will the instrument support or enhance programs for local and regional school-age students and minorities, either existing or to be implemented? This program does not support infrastructure, facility construction, or medical research.

NIH's Shared Instrumentation Program: The More I Know, the Better My Chances

Malgorzata Klosek, Scientific Review Officer, Office of Research Infrastructure Programs, National Institutes of Health

Shared Instrumentation Grant Programs:

(https://grants.nih.gov/grants/guide/pa-files/PAR-18-600.html) (https://grants.nih.gov/grants/guide/pa-files/par-18-599.html)

Dr. Klosek described for us the NIH S10 Instrumentation grants. This program receives an average of 400 proposals every year with 100 awards given out. The awards range from $50,000–$2,000,000 and need to be used for state-of-the-art commercial instrumentation. Supplies and service contracts cannot be purchased as part of the award. At the end of the award period, the instrument needs to be installed and functional. Reviewers rely on input from the study section for funding of these awards. She advises that your proposal should describe how your shared resource is going to impact three NIH-funded investigators and 10–15 users. Your financial plan does not need to include cost sharing, but instrument users, space, and long-term operational costs should all be described in detail. Program managers like to see these grants given to institutions where the instrument will go into a Core Facility. It is useful to have an advisory committee to oversee use of the instrument.