Translational research explained

Translational research should not be confused with Translation studies.

Translational research (also called translation research, translational science, or, when the context is clear, simply translation)[1] [2] is research aimed at translating (converting) results in basic research into results that directly benefit humans. The term is used in science and technology, especially in biology and medical science. As such, translational research forms a subset of applied research.

The term has been used most commonly in life sciences and biotechnology, but applies across the spectrum of science and humanities. In the context of biomedicine, translational research is also known as bench to bedside.[3] In the field of education, it is defined as research which translates concepts to classroom practice.

Critics of translational medical research (to the exclusion of more basic research) point to examples of important drugs that arose from fortuitous discoveries in the course of basic research such as penicillin and benzodiazepines. Other problems have stemmed from the widespread irreproducibility thought to exist in translational research literature.

Although translational research is relatively new, there are now several major research centers focused on it. In the U.S., the National Institutes of Health has implemented a major national initiative to leverage existing academic health center infrastructure through the Clinical and Translational Science Awards. Furthermore, some universities acknowledge translational research as its own field in which to study for a PhD or graduate certificate.

Definitions

Translational research is aimed at solving particular problems; the term has been used most commonly in life sciences and biotechnology, but applies across the spectrum of science and humanities.

In the field of education, it is defined for school-based education by the Education Futures Collaboration (www.meshguides.org) as research which translates concepts to classroom practice.[4] Examples of translational research are commonly found in education subject association journals and in the MESHGuides which have been designed for this purpose.[5]

In bioscience, translational research is a term often used interchangeably with translational medicine or translational science or bench to bedside. The adjective "translational" refers to the "translation" (the term derives from the Latin for "carrying over") of basic scientific findings in a laboratory setting into potential treatments for disease.[6] [7] [8] [9]

Biomedical translational research adopts a scientific investigation/enquiry into a given problem facing medical/health practices:[10] it aims to "translate" findings in fundamental research into practice. In the field of biomedicine, it is often called "translational medicine", defined by the European Society for Translational Medicine (EUSTM) as "an interdisciplinary branch of the biomedical field supported by three main pillars: benchside, bedside and community",[11] from laboratory experiments through clinical trials, to therapies,[12] to point-of-care patient applications.[13] The end point of translational research in medicine is the production of a promising new treatment that can be used clinically. Translational research is conceived due to the elongated time often taken to bring to bear discovered medical idea in practical terms in a health system. It is for these reasons that translational research is more effective in dedicated university science departments or isolated, dedicated research centers.[14] Since 2009, the field has had specialized journals, the American Journal of Translational Research and Translational Research dedicated to translational research and its findings.

Translational research in biomedicine is broken down into different stages. In a two-stage model, T1 research, refers to the "bench-to-bedside" enterprise of translating knowledge from the basic sciences into the development of new treatments and T2 research refers to translating the findings from clinical trials into everyday practice, although this model is actually referring to the 2 "roadblocks" T1 and T2. Waldman et al.[15] propose a scheme going from T0 to T5. T0 is laboratory (before human) research. In T1-translation, new laboratory discoveries are first translated to human application, which includes phase I & II clinical trials. In T2-translation, candidate health applications progress through clinical development to engender the evidence base for integration into clinical practice guidelines. This includes phase III clinical trials. In T3-translation, dissemination into community practices happens. T4-translation seeks to (1) advance scientific knowledge to paradigms of disease prevention, and (2) move health practices established in T3 into population health impact. Finally, T5-translation focuses on improving the wellness of populations by reforming suboptimal social structures

Comparison to basic research or applied research

Basic research is the systematic study directed toward greater knowledge or understanding of the fundamental aspects of phenomena and is performed without thought of practical ends. It results in general knowledge and understanding of nature and its laws.[16] For instance, basic biomedical research focuses on studies of disease processes using, for example, cell cultures or animal models without consideration of the potential utility of that information.

Applied research is a form of systematic inquiry involving the practical application of science. It accesses and uses the research communities' accumulated theories, knowledge, methods, and techniques, for a specific, often state, business, or client-driven purpose.[17] Translational research forms a subset of applied research. In life-sciences, this was evidenced by a citation pattern between the applied and basic sides in cancer research that appeared around 2000.[18]

Challenges and criticisms

Critics of translational medical research (to the exclusion of more basic research) point to examples of important drugs that arose from fortuitous discoveries in the course of basic research such as penicillin and benzodiazepines,[19] and the importance of basic research in improving our understanding of basic biological facts (e.g. the function and structure of DNA) that go on to transform applied medical research.[20] Examples of failed translational research in the pharmaceutical industry include the failure of anti-aβ therapeutics in Alzheimer's disease.[21] Other problems have stemmed from the widespread irreproducibility thought to exist in translational research literature.[22]

Translational research-facilities in life-sciences

In U.S., the National Institutes of Health has implemented a major national initiative to leverage existing academic health center infrastructure through the Clinical and Translational Science Awards.The National Center for Advancing Translational Sciences (NCATS) was established on December 23, 2011.[23]

Although translational research is relatively new, it is being recognized and embraced globally. Some major centers for translational research include:

Additionally, translational research is now acknowledged by some universities as a dedicated field to study a PhD or graduate certificate in, in a medical context. These institutes currently include Monash University in Victoria, Australia,[33] the University of Queensland, Diamantina Institute in Brisbane, Australia,[34] at Duke University in Durham, North Carolina, America,[35] at Creighton University in Omaha, Nebraska[36] at Emory University in Atlanta, Georgia,[37] and at [38] The George Washington University in Washington, D.C.The industry and academic interactions to promote translational science initiatives has been carried out by various global centers such as European Commission, GlaxoSmithKline and Novartis Institute for Biomedical Research.[39]

See also

External links

Notes and References

  1. Web site: 2020-02-24. Translation Research NIOSH CDC. 2021-11-05. www.cdc.gov. en-us.
  2. Web site: What is Translational Research? UAMS Translational Research Institute. 2021-11-05. tri.uams.edu. en-US.
  3. Chawla. Bhavna. 2018-08-03. Bench to Bedside: Translational Research Demystified. The Official Scientific Journal of Delhi Ophthalmological Society. 29. 1. 4–5. 10.7869/djo.367. 81524567 . free.
  4. Burden. Kevin. Younie. Sarah. Leask. Marilyn . vanc . Translational research principles applied to education: the mapping educational specialist knowhow (MESH) initiative. Journal of Education for Teaching. October 2013. 39. 4. 459–463. 10.1080/02607476.2013.801216. 145145150.
  5. Book: Younie S . 2016 . Mapping Educational Specialist knowHow (MESH) . International Teacher Education Knowledge Mobilisation Summit: a framework for UNESCO SDG4 2030 . Whitehall . London .
  6. Woolf SH. January 2008. The meaning of translational research and why it matters. JAMA. 299. 2. 211–3. 10.1001/jama.2007.26. 18182604.
  7. Reis SE, Berglund L, Bernard GR, Califf RM, Fitzgerald GA, Johnson PC. March 2010. Reengineering the national clinical and translational research enterprise: the strategic plan of the National Clinical and Translational Science Awards Consortium. Academic Medicine. 85. 3. 463–9. 10.1097/acm.0b013e3181ccc877. 2829722. 20182119.
  8. News: Science Careers Staff. 2011. Careers in Clinical and Translational Research. en. Science. March 24, 2018.
  9. Web site: Agency for Healthcare Research and Quality. 2017. Translating Research Into Practice. March 25, 2018. www.ahrq.gov. en-us.
  10. Akarowhe K (2018) Translational Research: Definitions and Relevance. J Biol Med Res Vol.2 No.2:13
  11. Cohrs. Randall J.. Martin. Tyler. Ghahramani. Parviz. Bidaut. Luc. Higgins. Paul J.. Shahzad. Aamir. vanc. 2014. Translational Medicine definition by the European Society for Translational Medicine. New Horizons in Translational Medicine. 2. 3. 86–88. 10.1016/j.nhtm.2014.12.002. 2024-03-28 . free.
  12. Mahla RS. 2016. Stem Cells Applications in Regenerative Medicine and Disease Therapeutics. International Journal of Cell Biology. 2016. 7. 19. 10.1155/2016/6940283. 4969512. 27516776. free.
  13. What is Translational Science. JAMA. 9 January 2008. 299. 2. 211–213. Tufts Clinical and Translational Science Institute. 10.1001/jama.2007.26. 9 June 2015. Woolf. Steven H.. 18182604.
  14. Pober JS, Neuhauser CS, Pober JM . Obstacles facing translational research in academic medical centers . FASEB Journal . 15 . 13 . 2303–13 . November 2001 . 11689456 . 10.1096/fj.01-0540lsf . free . 32503545 .
  15. Waldman. Scott A.. Terzic. Andre. 2010-10-01. Clinical and Translational Science: From Bench-Bedside to Global Village. Clinical and Translational Science. en. 3. 5. 254–257. 10.1111/j.1752-8062.2010.00227.x. 20973923. 1752-8062. 5439613.
  16. "What is basic research?" (PDF). National Science Foundation. Retrieved 2014-05-31.
  17. Roll-Hansen. Nils . vanc . Why the distinction between basic (theoretical) and applied (practical) research is important in the politics of science. April 2009. November 30, 2013. The London School of Economics and Political Science.
  18. Cambrosio A, Keating P, Mercier S, Lewison G, Mogoutov A . Mapping the emergence and development of translational cancer research . European Journal of Cancer . 42 . 18 . 3140–8 . December 2006 . 17079135 . 10.1016/j.ejca.2006.07.020 .
  19. Book: Tone, Andrea. The Age of Anxiety: the History of America's Love Affairs with Tranquilizers. 2009.
  20. Web site: The perils of translational research. November 26, 2012. Ashutosh Jogalekar. Scientific American Blog Network.
  21. Golde TE, Schneider LS, Koo EH . Anti-aβ therapeutics in Alzheimer's disease: the need for a paradigm shift . Neuron . 69 . 2 . 203–13 . January 2011 . 21262461 . 3058906 . 10.1016/j.neuron.2011.01.002 .
  22. Prinz F, Schlange T, Asadullah K . Believe it or not: how much can we rely on published data on potential drug targets? . Nature Reviews. Drug Discovery . 10 . 9 . 712 . August 2011 . 21892149 . 10.1038/nrd3439-c1 . free .
  23. Web site: Новости Мюнхена и Германии . CTSA Web.
  24. Web site: Clinical and Translational Science Awards Program Hubs. www.ncats.nih.gov. 13 March 2015. National Institutes for Health. 31 March 2016.
  25. http://energy.gov/articles/world-s-largest-medical-center-now-among-most-energy-efficient The World's Largest Medical Center is Now Among the Most Energy Efficient | Department of Energy
  26. Web site: University of Rochester Clinical and Translational Science Institute . The University of Rochester.
  27. Web site: Maine Medical Center Research Institute attracts top scientists, licenses discoveries. www.mainebiz.biz. Mainebiz. 17 June 2015.
  28. Web site: Translational Research Institute. www.scripps.edu . The Scripps Research Institute. 17 June 2015.
  29. Web site: UC Davis Clinical and Translational Science Center: About Us. UC Davis Health System, Clinical and Translational Science Center.
  30. Web site: About Us | CTSI University of Pittsburgh.
  31. Web site: 11 May 2023 . Weill Cornell Clinical and Translational Science Center . 11 May 2023 . Weill Cornell Medicine.
  32. Web site: 10 May 2024 . Clinical & Translational Research Core . 10 May 2024 . Wyss Institute at Harvard University.
  33. Web site: Translational Research – PhD and Graduate Certificate. www.med.monash.edu.au . Monash University. 17 June 2015.
  34. Web site: MPhil in Translational Research. www.di.uq.edu.au. University of Queensland Diamantina Institute. 17 June 2015.
  35. Web site: Clinical and Translational Research. medschool.duke.edu. Duke University. 17 June 2015.
  36. Web site: Center for Clinical and Translational Science. medschool.creighton.edu. Creighton University. 14 July 2015.
  37. Web site: Certificate Program in Translational. Emory University. 4 Jan 2018.
  38. Web site: PhD in Translational Health Sciences. smhs.gwu.edu. The George Washington University. 9 June 2019.
  39. Web site: Novartis. World Pharma News.