Perspective

The NIH Budget and the Future of Biomedical Research

Joseph Loscalzo, M.D., Ph.D.

N Engl J Med 2006; 354:1665-1667April 20, 2006

Article

Federal funding for biomedical research in the United States has fueled discoveries that have advanced our understanding of human disease, led to novel and effective diagnostic tools and therapies, and made our research enterprise an international paragon. Although it was not the original intent, this investment, through the National Institutes of Health (NIH), has also become an essential source of support for academic medical centers, providing funds for faculty and staff salaries, operational expenses, and even capital improvements related to research that can no longer be supported by clinical income. Until approximately 20 years ago, clinical income often subsidized research, but managed care, increased scrutiny and efficiency in the management of clinical expenses, and reductions in federal support for teaching hospitals have rendered clinical margins insufficient to support the research mission. Although some may see institution building as an inappropriate use of NIH funds, a consistent, productive biomedical research enterprise requires a solid infrastructure.

Ensuring durable federal support for such research has not, however, been without tribulations. As with all line items in the federal budget, NIH funding is subject to the vicissitudes of the political process, and intermittent periods of growth have been followed by periods of decline (see graphAnnualized Growth of the NIH Budget, 1971 to 2005.). Some argue that funding cycles refresh the research enterprise, eliminating through competition investigators whose work is not of the highest quality. Though not as sanguine about their purposes or consequences, the academic medical community has accepted these cycles and works to find ways to dampen the effects of downturns on research programs and institutional stability.

We have recently entered another period of stagnant funding for the NIH. Having doubled between 1998 and 2003, the NIH budget is expected to be $28.6 billion for fiscal year 2007, a 0.1 percent decrease from last year,1 or a 3.8 percent decrease after adjustment for inflation — the first true budgeted reduction in NIH support since 1970. Whereas national defense spending has reached approximately $1,600 per capita, federal spending for biomedical research now amounts to about $97 per capita — a rather modest investment in “advancing the health, safety, and well-being of our people.”1 This downturn is more severe than any we have faced previously, since it comes on the heels of the doubling of the budget and threatens to erode the benefits of that investment. It takes many years for institutions to develop investigators skilled in modern research techniques and to build the costly, complicated infrastructure necessary for biomedical research. Rebuilding the investigator pool and the infrastructure after a downturn is expensive and time-consuming and weakens the benefits of prior funding. This situation is unlikely to improve anytime soon: the resources required for the war in Iraq and for hurricane relief, along with the erosion of the tax base by the current administration's fiscal policies, are expected to have long-term, far-reaching effects.

Most institutes within the NIH have quickly adopted policy changes to minimize the adverse consequences, including reducing the maximum grant term from five years to four years, eliminating cost-of-living increases, and capping the amounts of awards. These changes have important effects on currently funded research and the infrastructure that it requires. Moreover, the future of biomedical research is also affected: NIH training grants represent a major source of support for postdoctoral and clinical fellows during their research experiences, and budget limitations affect not only available training slots but also the training climate. As it becomes increasingly difficult for established investigators to renew their grants, their frustration is transmitted to trainees, who increasingly opt for alternative career paths, shrinking the pipeline of future investigators.

Meanwhile, for more than 10 years, the pharmaceutical industry has been investing larger amounts in research and development than the federal government — $51.3 billion in fiscal year 2005,2 for instance, or 78 percent more than NIH funding that year. Fiscal conservatives may view this industry investment as an appropriate, market-driven solution that should suffice and that does not justify additional government funding for biomedical research. However, the lion's share of industry funds is applied to drug development, especially clinical trials, rather than to fundamental research and is targeted to applications that are first and foremost of value to the industry. Federal funding has traditionally targeted a broad range of investigator-initiated research, from studies of molecular mechanisms of disease to population-based studies of disease prevalence, promoting an unrestricted environment of biomedical discovery that serves as the basis for industry-driven development. These approaches are complementary, and both have served society well.

How, then, can we ensure that funding for biomedical research is maintained at adequate levels for the foreseeable future? Korn and colleagues have argued that stability and quality can be ensured by maintaining overall funding at an annual growth rate of 8 to 9 percent (unadjusted for inflation).3 They base their conclusion on the costs associated with six basic goals, which I endorse: preserving the integrity of the merit and peer-review process, which requires that funding levels not fall below the 30th percentile success rate; maintaining a stable pool of new investigators; sustaining commitments to continuing awards; preserving the capacity of institutions that receive grants by minimizing cost-sharing with the federal government (e.g., for lease costs or animal care); recognizing the continuous growth of new research technologies; and maintaining a robust intramural NIH research program. I would, however, modify the annual required growth rate to 5 to 6 percent real growth plus inflation: the annual growth rate over the past 30 years has been approximately 10 percent, which reflects an annual average real growth rate of 5.2 percent and an average inflation rate of 4.8 percent (ranging from 1.1 to 13.3 percent).

Unfortunately, the federal government probably cannot accommodate this growth rate under its current fiscal constraints. So maintaining, by statute, a stable base level of funding equivalent to the fiscal year 2006 budget, with annual inflationary adjustments, seems to me a reasonable starting point. Congress may then choose to allocate additional resources annually, subject to availability, aiming for an annual real growth rate of 5 to 6 percent. Alternatively, to avoid politicization of the flow of funds and their targets, a dedicated tax could be imposed on consumer products that threaten human health — such as fast foods, tobacco, and alcohol — and used to maintain the biomedical research infrastructure by a formulaic allocation, much as the gasoline tax is used to maintain the federal highway infrastructure.

The NIH can optimize the use of these funds by limiting the size and duration of awards as well as the number of awards per investigator. It might also consider shifting the target of grants. Whereas other countries often provide funding as an award for work accomplished before the application, the NIH theoretically funds proposed work — though in reality, the peer-review process effectively requires that a hypothesis virtually be proved correct before funding is approved. Within the NIH intramural research program, funding levels for individual laboratories are often decided on the basis of accomplishments during the previous cycle, so there is already a precedent that can be applied to the extramural program. Of course, new investigators would need to be reviewed differently to ensure appropriate allocation of funds to these promising members of the research community who have no or limited previous research accomplishments.

Even with such changes, however, it would be preferable for academic medical centers to cease relying so heavily on the NIH for research funding. In addition to having investigators seek funding from not-for-profit organizations and from industry, I believe that centers should encourage major nongovernmental funding organizations to consolidate their resources into a durable pool of support for the best research proposals in the life sciences. In addition, individual centers should encourage generous donors to support unrestricted research endowments designed to fund translational and clinical research programs within the medical center or to contribute to a national pool linked with support from industry to establish a national endowment for funding translational research and drug or device development within academic medical centers. Such promotion of later-phase research within academic medical centers could enhance the value of the intellectual property derived from it, financial benefits from which could, in turn, be used to establish research endowments within the medical centers.

The federal government might also consider alternative ways to fund the NIH budget that are independent of allocations from the tax base. One approach might include seeking support from industries whose products contribute to the burden of disease, providing tax credits as an incentive for their contribution. These resources could be used to establish an independently managed national fund, which could be used to ensure adequate support for biomedical research without the funding gaps or oscillations that currently plague the process. In this scenario, unused money from any fiscal year would be retained in the fund, with the goal of achieving self-sustained growth.

Whatever mechanisms are ultimately chosen, it seems clear that new methods of support must be developed if biomedical research is to continue to thrive in the United States. The goal of a durable, steady stream of support for research in the life sciences has never been more pressing, since the research derived from that support has never promised greater benefits. The fate of life-sciences research should not be consigned to the political winds of Washington.

Source Information

Dr. Loscalzo is the physician-in-chief and chair of medicine at Brigham and Women's Hospital and a professor of medicine at Harvard Medical School — both in Boston.

References

References

1. 1

   Office of Budget. FY 2007 budget in brief: advancing the health, safety, and well-being of our people. Washington, D.C.: Department of Health and Human Services, 2006.
   

2. 2

   Press release of the Pharmaceutical Research and Manufacturers of America, February 13, 2006. (Accessed March 30, 2006, at http://www.phrma.org/news_room/press_releases/r%26d_investments_by_america%92s_pharmaceutical_research_companies_nears_record_%2440_billion_in_2005/.)
   

3. 3

   Korn D, Rich RR, Garrison HH, et al. The NIH budget in the “postdoubling” era. Science 2002;296:1401-1402
   CrossRef | Web of Science | Medline

Citing Articles (24)

Citing Articles

1. 1

   Richard S Blumberg, Bonnie Dittel, David Hafler, Matthias von Herrath, Frank O Nestle. (2012) Unraveling the autoimmune translational research process layer by layer. Nature Medicine 18:1, 35-41
   CrossRef

2. 2

   Jeffrey Peppercorn, Thomas G. Roberts, Tim G. Hammond. 2010. History of Clinical Trial Development and the Pharmaceutical Industry. .
   CrossRef

3. 3

   Peter J. Pronovost, Marlene R. Miller, Robert M. Wachter, Gregg S. Meyer. (2009) Perspective: Physician Leadership in Quality. Academic Medicine 84:12, 1651-1656
   CrossRef

4. 4

   Kathleen M. Quinlan, Mary Kane, William M. K. Trochim. (2009) Evaluation of large research initiatives: Outcomes, challenges, and methodological considerations. New Directions for Evaluation 2008:118, 61-72
   CrossRef

5. 5

   Dan Weiss, Prasad Naik, Ram Weiss. (2009) The 'big pharma' dilemma: develop new drugs or promote existing ones?. Nature Reviews Drug Discovery 8:7, 533-534
   CrossRef

6. 6

   Aaron S. Kesselheim, Jerry Avorn. (2009) Using Patent Data to Assess the Value of Pharmaceutical Innovation. The Journal of Law, Medicine & Ethics 37:2, 176-183
   CrossRef

7. 7

   Steinbrook, Robert, . (2009) The NIH Stimulus — The Recovery Act and Biomedical Research. New England Journal of Medicine 360:15, 1479-1481
   Full Text

8. 8

   Lars M. Ellison, Carl A. Olsson. (2009) The Sad and Bleak Future for Urology Funding at the National Institutes of Health. Urologic Clinics of North America 36:1, 85-93
   CrossRef

9. 9

   Sten H. Vermund, Quarraisha Abdool Karim. 2009. Governmental Support of Research. , 219-236.
   CrossRef

10. 10

    David H. Bradshaw, Court Empy, Phillip Davis, David Lipschitz, Yoshio Nakamura, C. Richard Chapman. (2008) Trends in Funding for Research on Pain: A Report on the National Institutes of Health Grant Awards Over the Years 2003 to 2007. The Journal of Pain 9:12, 1077-1087.e8
    CrossRef

11. 11

    M.M. Boggiano, S.A. Cavigelli, J.R. Dorsey, C.E.P. Kelley, C.M. Ragan, P.C. Chandler-Laney. (2008) Effect of a cage divider permitting social stimuli on stress and food intake in rats. Physiology & Behavior 95:1-2, 222-228
    CrossRef

12. 12

    Jeffrey S. Barrett. (2008) The Role of Quantitative Pharmacology in an Academic Translational Research Environment. The AAPS Journal 10:1, 9-14
    CrossRef

13. 13

    Keith A. Joiner, Sarah Hiteman, Steven Wormsley, Patricia St. Germain. (2007) Timing of Revenue Streams from Newly Recruited Faculty: Implications for Faculty Retention. Academic Medicine 82:12, 1228-1238
    CrossRef

14. 14

    Brian C. Martinson. (2007) Universities and the money fix. Nature 449:7159, 141-142
    CrossRef

15. 15

    Heinig, Stephen J., Krakower, Jack Y., Dickler, Howard B., Korn, David, . (2007) Sustaining the Engine of U.S. Biomedical Discovery. New England Journal of Medicine 357:10, 1042-1047
    Full Text

16. 16

    Giorgio A. Ascoli. (2007) Biomedical research funding: when the game gets tough, winners start to play. BioEssays 29:9, 933-936
    CrossRef

17. 17

    David G. Nathan. (2007) Acceptance of the 2006 Kober Medal. Journal of Clinical Investigation 117:4, 1107-1113
    CrossRef

18. 18

    Sean P. Collins. (2007) On “Getting the Right Message”. Annals of Emergency Medicine 49:3, 383-384
    CrossRef

19. 19

    M V Relling, J M Hoffman. (2007) Should Pharmacogenomic Studies be Required for New Drug Approval?. Clinical Pharmacology & Therapeutics 81:3, 425-428
    CrossRef

20. 20

    Pedro Cuatrecasas. (2006) Drug discovery in jeopardy. Journal of Clinical Investigation 116:11, 2837-2842
    CrossRef

21. 21

    Jeffrey Laurence. (2006) Translating translational research. Translational Research 148:1, 1-3
    CrossRef

22. 22

    T. Jake Liang. (2006) Supporting the NIH before it is too late. Hepatology 44:1, 1-2
    CrossRef

23. 23

    (2006) What's in a name?. Nature Reviews Drug Discovery 5:6, 441-441
    CrossRef

24. 24

    W. L. Lanier. (2006) Editor's Note: Industry Support of Articles Published in Mayo Clinic Proceedings. Mayo Clinic Proceedings 81:6, 851-852
    CrossRef