Blinded experiment

(Redirected from Double-blind trials)

In a blind or blinded experiment, information which may influence the participants of the experiment is withheld until after the experiment is complete. Good blinding can reduce or eliminate experimental biases that arise from a participants' expectations, observer's effect on the participants, observer bias, confirmation bias, and other sources. A blind can be imposed on any participant of an experiment, including subjects, researchers, technicians, data analysts, and evaluators. In some cases, while blinding would be useful, it is impossible or unethical. For example, it is not possible to blind a patient to their treatment in a physical therapy intervention. A good clinical protocol ensures that blinding is as effective as possible within ethical and practical constraints.

During the course of an experiment, a participant becomes unblinded if they deduce or otherwise obtain information that has been masked to them. For example, a patient who experiences a side effect may correctly guess their treatment, becoming unblinded. Unblinding is common in blinded experiments, particularly in pharmacological trials. In particular, trials on pain medication and antidepressants are poorly blinded. Unblinding that occurs before the conclusion of a study is a source of experimental error, as the bias that was eliminated by blinding is re-introduced. The CONSORT reporting guidelines recommend that all studies assess and report unblinding. In practice, very few studies do so.[1]

Blinding is an important tool of the scientific method, and is used in many fields of research. In some fields, such as medicine, it is considered essential.[2] In clinical research, a trial that is not a blinded trial is called an open trial.

History

edit

The first known blind experiment was conducted by the French Royal Commission on Animal Magnetism in 1784 to investigate the claims of mesmerism as proposed by Charles d'Eslon, a former associate of Franz Mesmer. In the investigations, the researchers (physically) blindfolded mesmerists and asked them to identify objects that the experimenters had previously filled with "vital fluid". The subjects were unable to do so.[citation needed]

In 1817, the first blind experiment recorded to have occurred outside of a scientific setting compared the musical quality of a Stradivarius violin to one with a guitar-like design. A violinist played each instrument while a committee of scientists and musicians listened from another room so as to avoid prejudice.[3][4]

An early example of a double-blind protocol was the Nuremberg salt test of 1835 performed by Friedrich Wilhelm von Hoven, Nuremberg's highest-ranking public health official,[5] as well as a close friend of Friedrich Schiller.[6] This trial contested the effectiveness of homeopathic dilution.[5]

In 1865, Claude Bernard published his Introduction to the Study of Experimental Medicine, which advocated for the blinding of researchers.[7] Bernard's recommendation that an experiment's observer should not know the hypothesis being tested contrasted starkly with the prevalent Enlightenment-era attitude that scientific observation can only be objectively valid when undertaken by a well-educated, informed scientist.[8] The first study recorded to have a blinded researcher was conducted in 1907 by W. H. R. Rivers and H. N. Webber to investigate the effects of caffeine.[9] The need to blind researchers became widely recognized in the mid-20th century.[10]

Background

edit

Bias

edit

A number of biases are present when a study is insufficiently blinded. Patient-reported outcomes can be different if the patient is not blinded to their treatment.[11] Likewise, failure to blind researchers results in observer bias.[12] Unblinded data analysts may favor an analysis that supports their existing beliefs (confirmation bias). These biases are typically the result of subconscious influences, and are present even when study participants believe they are not influenced by them.[13]

Terminology

edit

In medical research, the terms single-blind, double-blind and triple-blind are commonly used to describe blinding. These terms describe experiments in which (respectively) one, two, or three parties are blinded to some information. Most often, single-blind studies blind patients to their treatment allocation, double-blind studies blind both patients and researchers to treatment allocations, and triple-blinded studies blind patients, researcher, and some other third party (such as a monitoring committee) to treatment allocations. However, the meaning of these terms can vary from study to study.[14]

CONSORT guidelines state that these terms should no longer be used because they are ambiguous. For instance, "double-blind" could mean that the data analysts and patients were blinded; or the patients and outcome assessors were blinded; or the patients and people offering the intervention were blinded, etc. The terms also fail to convey the information that was masked and the amount of unblinding that occurred. It is not sufficient to specify the number of parties that have been blinded. To describe an experiment's blinding, it is necessary to report who has been blinded to what information, and how well each blind succeeded.[15]

Unblinding

edit

"Unblinding" occurs in a blinded experiment when information becomes available to one from whom it has been masked. In clinical studies, unblinding may occur unintentionally when a patient deduces their treatment group. Unblinding that occurs before the conclusion of an experiment is a source of bias. Some degree of premature unblinding is common in blinded experiments.[16] When a blind is imperfect, its success is judged on a spectrum with no blind (or complete failure of blinding) on one end, perfect blinding on the other, and poor or good blinding between. Thus, the common view of studies as blinded or unblinded is an example of a false dichotomy.[17]

Success of blinding is assessed by questioning study participants about information that has been masked to them (e.g. did the participant receive the drug or placebo?). In a perfectly blinded experiment, the responses should be consistent with no knowledge of the masked information. However, if unblinding has occurred, the responses will indicate the degree of unblinding. Since unblinding cannot be measured directly, but must be inferred from participants' responses, its measured value will depend on the nature of the questions asked. As a result, it is not possible to measure unblinding in a way that is completely objective. Nonetheless, it is still possible to make informed judgments about the quality of a blind. Poorly blinded studies rank above unblinded studies and below well-blinded studies in the hierarchy of evidence.[18]

Post-study unblinding

edit

Post-study unblinding is the release of masked data upon completion of a study. In clinical studies, post-study unblinding serves to inform subjects of their treatment allocation. Removing a blind upon completion of a study is never mandatory, but is typically performed as a courtesy to study participants. Unblinding that occurs after the conclusion of a study is not a source of bias, because data collection and analysis are both complete at this time.[19]

Premature unblinding

edit

Premature unblinding is any unblinding that occurs before the conclusion of a study. In contrast with post-study unblinding, premature unblinding is a source of bias. A code-break procedure dictates when a subject should be unblinded prematurely. A code-break procedure should only allow for unblinding in cases of emergency. Unblinding that occurs in compliance with code-break procedure is strictly documented and reported.[20]

Premature unblinding may also occur when a participant infers from experimental conditions information that has been masked to them. A common cause for unblinding is the presence of side effects (or effects) in the treatment group. In pharmacological trials, premature unblinding can be reduced with the use of an active placebo, which conceals treatment allocation by ensuring the presence of side effects in both groups.[21] However, side effects are not the only cause of unblinding; any perceptible difference between the treatment and control groups can contribute to premature unblinding.[citation needed]

A problem arises in the assessment of blinding because asking subjects to guess masked information may prompt them to try to infer that information. Researchers speculate that this may contribute to premature unblinding.[22] Furthermore, it has been reported that some subjects of clinical trials attempt to determine if they have received an active treatment by gathering information on social media and message boards. While researchers counsel patients not to use social media to discuss clinical trials, their accounts are not monitored. This behavior is believed to be a source of unblinding.[23] CONSORT standards and good clinical practice guidelines recommend the reporting of all premature unblinding.[24][25] In practice, unintentional unblinding is rarely reported.[1]

Significance

edit

Bias due to poor blinding tends to favor the experimental group, resulting in inflated effect size and risk of false positives.[24] Success or failure of blinding is rarely reported or measured; it is implicitly assumed that experiments reported as "blind" are truly blind.[1] Critics have pointed out that without assessment and reporting, there is no way to know if a blind succeeded. This shortcoming is especially concerning given that even a small error in blinding can produce a statistically significant result in the absence of any real difference between test groups when a study is sufficiently powered (i.e. statistical significance is not robust to bias). As such, many statistically significant results in randomized controlled trials may be caused by error in blinding.[26] Some researchers have called for the mandatory assessment of blinding efficacy in clinical trials.[18]

Applications

edit

In medicine

edit

Blinding is considered essential in medicine,[27] but is often difficult to achieve. For example, it is difficult to compare surgical and non-surgical interventions in blind trials. In some cases, sham surgery may be necessary for the blinding process. A good clinical protocol ensures that blinding is as effective as possible within ethical and practical constrains.

Studies of blinded pharmacological trials across widely varying domains find evidence of high levels of unblinding. Unblinding has been shown to affect both patients and clinicians. This evidence challenges the common assumption that blinding is highly effective in pharmacological trials. Unblinding has also been documented in clinical trials outside of pharmacology.[28]

Pain

edit

A 2018 meta-analysis found that assessment of blinding was reported in only 23 out of 408 randomized controlled trials for chronic pain (5.6%). The study concluded upon analysis of pooled data that the overall quality of the blinding was poor, and the blinding was "not successful." Additionally, both pharmaceutical sponsorship and the presence of side effects were associated with lower rates of reporting assessment of blinding.[29]

Depression

edit

Studies have found evidence of extensive unblinding in antidepressant trials: at least three-quarters of patients were able to correctly guess their treatment assignment.[30] Unblinding also occurs in clinicians.[31] Better blinding of patients and clinicians reduces effect size. Researchers concluded that unblinding inflates effect size in antidepressant trials.[32][33][34] Some researchers believe that antidepressants are not effective for the treatment of depression and only outperform placebos due to systematic error. These researchers argue that antidepressants are just active placebos.[35][36]

Acupuncture

edit

While the possibility of blinded trials on acupuncture is controversial, a 2003 review of 47 randomized controlled trials found no fewer than four methods of blinding patients to acupuncture treatment: 1) superficial needling of true acupuncture points, 2) use of acupuncture points which are not indicated for the condition being treated, 3) insertion of needles outside of true acupuncture points, and 4) the use of placebo needles which are designed not to penetrate the skin. The authors concluded that there was "no clear association between type of sham intervention used and the results of the trials."[37]

A 2018 study on acupuncture which used needles that did not penetrate the skin as a sham treatment found that 68% of patients and 83% of acupuncturists correctly identified their group allocation. The authors concluded that the blinding had failed, but that more advanced placebos may someday offer the possibility of well-blinded studies in acupuncture.[38]

In physics

edit

It is standard practice in physics to perform blinded data analysis. After data analysis is complete, one is allowed to unblind the data. A prior agreement to publish the data regardless of the results of the analysis may be made to prevent publication bias.[13]

In social sciences

edit

Social science research is particularly prone to observer bias, so it is important in these fields to properly blind the researchers. In some cases, while blind experiments would be useful, they are impractical or unethical. Blinded data analysis can reduce bias, but is rarely used in social science research.[39]

In forensics

edit

In a police photo lineup, an officer shows a group of photos to a witness and asks the witness to identify the individual who committed the crime. Since the officer is typically aware of who the suspect is, they may (subconsciously or consciously) influence the witness to choose the individual that they believe committed the crime. There is a growing movement in law enforcement to move to a blind procedure in which the officer who shows the photos to the witness does not know who the suspect is.[40][41]

In music

edit

Auditions for symphony orchestras take place behind a curtain so that the judges cannot see the performer. Blinding the judges to the gender of the performers has been shown to increase the hiring of women.[42] Blind tests can also be used to compare the quality of musical instruments.[43][44]

See also

edit

References

edit
  1. ^ a b c Bello, Segun; Moustgaard, Helene; Hróbjartsson, Asbjørn (October 2014). "The risk of unblinding was infrequently and incompletely reported in 300 randomized clinical trial publications". Journal of Clinical Epidemiology. 67 (10): 1059–1069. doi:10.1016/j.jclinepi.2014.05.007. ISSN 1878-5921. PMID 24973822.
  2. ^ "Oxford Centre for Evidence-based Medicine - Levels of Evidence (March 2009) - CEBM". cebm.net. 11 June 2009. Archived from the original on 26 October 2017. Retrieved 2 May 2018.
  3. ^ Fétis FJ (1868). Biographie Universelle des Musiciens et Bibliographie Générale de la Musique, Tome 1 (Second ed.). Paris: Firmin Didot Frères, Fils, et Cie. p. 249. Retrieved 2011-07-21.
  4. ^ Dubourg G (1852). The Violin: Some Account of That Leading Instrument and its Most Eminent Professors... (Fourth ed.). London: Robert Cocks and Co. pp. 356–357. Retrieved 2011-07-21.
  5. ^ a b Stolberg, M. (December 2006). "Inventing the randomized double-blind trial: the Nuremberg salt test of 1835". Journal of the Royal Society of Medicine. 99 (12): 642–643. doi:10.1177/014107680609901216. PMC 1676327. PMID 17139070.
  6. ^ Biographie Des Doctor Friedrich Wilhelm Von Hoven (1840), ISBN 1104040891
  7. ^ Bernard, Claude; Dagognet, François (2008). Introduction à l'étude de la médecine expérimentale. Champs. Paris: Flammarion. ISBN 978-2-08-121793-5.
  8. ^ Daston L (2005). "Scientific Error and the Ethos of Belief". Social Research. 72 (1): 18. doi:10.1353/sor.2005.0016. S2CID 141036212.
  9. ^ Rivers WH, Webber HN (August 1907). "The action of caffeine on the capacity for muscular work". The Journal of Physiology. 36 (1): 33–47. doi:10.1113/jphysiol.1907.sp001215. PMC 1533733. PMID 16992882.
  10. ^ Alder K (2006). Kramer LS, Maza SC (eds.). A Companion to Western Historical Thought. Blackwell Companions to History. Wiley-Blackwell. p. 307. ISBN 978-1-4051-4961-7. Retrieved 2012-02-11. Shortly after the start of the Cold War [...] double-blind reviews became the norm for conducting scientific medical research, as well as the means by which peers evaluated scholarship, both in science and in history. {{cite book}}: |work= ignored (help)
  11. ^ Hróbjartsson, A; Emanuelsson, F; Skou Thomsen, AS; Hilden, J; Brorson, S (August 2014). "Bias due to lack of patient blinding in clinical trials. A systematic review of trials randomizing patients to blind and nonblind sub-studies". International Journal of Epidemiology. 43 (4): 1272–83. doi:10.1093/ije/dyu115. PMC 4258786. PMID 24881045.
  12. ^ Bello, S; Krogsbøll, LT; Gruber, J; Zhao, ZJ; Fischer, D; Hróbjartsson, A (September 2014). "Lack of blinding of outcome assessors in animal model experiments implies risk of observer bias". Journal of Clinical Epidemiology. 67 (9): 973–83. doi:10.1016/j.jclinepi.2014.04.008. PMID 24972762.
  13. ^ a b MacCoun, Robert; Perlmutter, Saul (7 October 2015). "Blind analysis: Hide results to seek the truth". Nature. 526 (7572): 187–189. Bibcode:2015Natur.526..187M. doi:10.1038/526187a. PMID 26450040.
  14. ^ Schulz KF, Chalmers I, Altman DG (February 2002). "The landscape and lexicon of blinding in randomized trials". Annals of Internal Medicine. 136 (3): 254–9. doi:10.7326/0003-4819-136-3-200202050-00022. PMID 11827510. S2CID 34932997.
  15. ^ Moher, David; Hopewell, Sally; Schulz, Kenneth F.; Montori, Victor; Gøtzsche, Peter C.; Devereaux, P. J.; Elbourne, Diana; Egger, Matthias; Altman, Douglas G. (23 March 2010). "CONSORT 2010 explanation and elaboration: updated guidelines for reporting parallel group randomised trials". BMJ (Clinical Research Ed.). 340: c869. doi:10.1136/bmj.c869. ISSN 1756-1833. PMC 2844943. PMID 20332511.
  16. ^ Bello, Segun; Moustgaard, Helene; Hróbjartsson, Asbjørn (2017). "Unreported formal assessment of unblinding occurred in 4 of 10 randomized clinical trials, unreported loss of blinding in 1 of 10 trials". Journal of Clinical Epidemiology. 81: 42–50. doi:10.1016/j.jclinepi.2016.08.002. ISSN 1878-5921. PMID 27555081.
  17. ^ Schulz, Kenneth F.; Grimes, David A. (23 February 2002). "Blinding in randomised trials: hiding who got what". Lancet. 359 (9307): 696–700. doi:10.1016/S0140-6736(02)07816-9. ISSN 0140-6736. PMID 11879884. S2CID 11578262.
  18. ^ a b Kolahi, J; Bang, H; Park, J (December 2009). "Towards a proposal for assessment of blinding success in clinical trials: up-to-date review". Community Dentistry and Oral Epidemiology. 37 (6): 477–84. doi:10.1111/j.1600-0528.2009.00494.x. ISSN 1600-0528. PMC 3044082. PMID 19758415.
  19. ^ Dinnett EM, Mungall MM, Kent JA, Ronald ES, McIntyre KE, Anderson E, Gaw A (2005). "Unblinding of trial participants to their treatment allocation: lessons from the Prospective Study of Pravastatin in the Elderly at Risk (PROSPER)". Clin Trials. 2 (3): 254–259. doi:10.1191/1740774505cn089oa. PMID 16279148. S2CID 36252366.
  20. ^ Quittell, Lynne M. (3 October 2018). "The Scientific and Social Implications of Unblinding a Study Subject". The American Journal of Bioethics. 18 (10): 71–73. doi:10.1080/15265161.2018.1513589. ISSN 1526-5161. PMID 30339067. S2CID 53014880.
  21. ^ Double, D. B. (19 October 1996). "Placebo mania. Placebo controlled trials are needed to provide data on effectiveness of active treatment". BMJ: British Medical Journal. 313 (7063): 1008–9. doi:10.1136/bmj.313.7063.1008b. ISSN 0959-8138. PMC 2352320. PMID 8892442.
  22. ^ Rees, Judy R.; Wade, Timothy J.; Levy, Deborah A.; Colford, John M.; Hilton, Joan F. (February 2005). "Changes in beliefs identify unblinding in randomized controlled trials: a method to meet CONSORT guidelines". Contemporary Clinical Trials. 26 (1): 25–37. doi:10.1016/j.cct.2004.11.020. PMID 15837450.
  23. ^ Ledford, Heidi. "A question of Control" (PDF). Nature Magazine. Retrieved 24 April 2019.
  24. ^ a b Moher, David; Altman, Douglas G.; Schulz, Kenneth F. (24 March 2010). "CONSORT 2010 Statement: updated guidelines for reporting parallel group randomised trials". BMJ. 340: c332. doi:10.1136/bmj.c332. ISSN 0959-8138. PMC 2844940. PMID 20332509.
  25. ^ "E6(R2) Good Clinical Practice: Integrated Addendum to ICH E6(R1) Guidance for Industry" (PDF). fda.gov. 2019-04-05. Retrieved 21 April 2019.
  26. ^ Siegfried, Tom (2010). "Odds are, it's wrong: Science fails to face the shortcomings of statistics". Science News. 177 (7): 26–29. doi:10.1002/scin.5591770721. ISSN 1943-0930.
  27. ^ "Oxford Centre for Evidence-based Medicine - Levels of Evidence (March 2009) - CEBM". cebm.net. 11 June 2009. Archived from the original on 26 October 2017. Retrieved 2 May 2018.
  28. ^ JUL 2009, The Pharmaceutical Journal31 (31 July 2009). "An example of problems that arise from clinical trials and how to avoid them". Pharmaceutical Journal. 283: 129–130. Retrieved 24 April 2019.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  29. ^ Colagiuri, Ben; Sharpe, Louise; Scott, Amelia (September 2018). "The Blind Leading the Not-So-Blind: A Meta-Analysis of Blinding in Pharmacological Trials for Chronic Pain". The Journal of Pain. 20 (5): 489–500. doi:10.1016/j.jpain.2018.09.002. ISSN 1526-5900. PMID 30248448. S2CID 52813251. Retrieved 22 April 2019.
  30. ^ Perlis, Roy H.; Ostacher, Michael; Fava, Maurizio; Nierenberg, Andrew A.; Sachs, Gary S.; Rosenbaum, Jerrold F. (2010). "Assuring that double-blind is blind". The American Journal of Psychiatry. 167 (3): 250–252. doi:10.1176/appi.ajp.2009.09060820. ISSN 1535-7228. PMID 20194487. S2CID 207628021.
  31. ^ White, K.; Kando, J.; Park, T.; Waternaux, C.; Brown, W. A. (December 1992). "Side effects and the "blindability" of clinical drug trials". The American Journal of Psychiatry. 149 (12): 1730–1731. doi:10.1176/ajp.149.12.1730. ISSN 0002-953X. PMID 1443253.
  32. ^ Moncrieff, Joanna; Wessely, Simon; Hardy, Rebecca (2 January 2018). "Meta-analysis of trials comparing antidepressants with active placebos". British Journal of Psychiatry. 172 (3): 227–231. doi:10.1192/bjp.172.3.227. ISSN 0007-1250. PMID 9614471. S2CID 4975797.
  33. ^ Greenberg, RP; Bornstein, RF; Greenberg, MD; Fisher, S (October 1992). "A meta-analysis of antidepressant outcome under "blinder" conditions". Journal of Consulting and Clinical Psychology. 60 (5): 664–9, discussion 670–7. doi:10.1037/0022-006X.60.5.664. ISSN 0022-006X. PMID 1401382.
  34. ^ Moncrieff, J; Wessely, S; Hardy, R (2004). "Active placebos versus antidepressants for depression". The Cochrane Database of Systematic Reviews. 2012 (1): CD003012. doi:10.1002/14651858.CD003012.pub2. ISSN 1469-493X. PMC 8407353. PMID 14974002.
  35. ^ Ioannidis, JP (27 May 2008). "Effectiveness of antidepressants: an evidence myth constructed from a thousand randomized trials?". Philosophy, Ethics, and Humanities in Medicine. 3: 14. doi:10.1186/1747-5341-3-14. ISSN 1747-5341. PMC 2412901. PMID 18505564.
  36. ^ Kirsch, Irving (2014). "Antidepressants and the Placebo Effect". Zeitschrift für Psychologie. 222 (3): 128–134. doi:10.1027/2151-2604/a000176. ISSN 2190-8370. PMC 4172306. PMID 25279271.
  37. ^ Dincer, F; Linde, K. (December 2003). "Sham interventions in randomized clinical trials of acupuncture—a review". Complementary Therapies in Medicine. 11 (4): 235–242. doi:10.1016/S0965-2299(03)00124-9. PMID 15022656.
  38. ^ Vase, L; Baram, S; Takakura, N; Takayama, M; Yajima, H; Kawase, A; Schuster, L; Kaptchuk, TJ; Schou, S; Jensen, TS; Zachariae, R; Svensson, P (2015). "Can acupuncture treatment be double-blinded? An evaluation of double-blind acupuncture treatment of postoperative pain". PLOS ONE. 10 (3): e0119612. Bibcode:2015PLoSO..1019612V. doi:10.1371/journal.pone.0119612. ISSN 1932-6203. PMC 4352029. PMID 25747157.
  39. ^ Sanders, Robert (2015-10-08). "'Blind analysis' could reduce bias in social science research". Berkeley News. Retrieved 2019-08-29.
  40. ^ Dittmann M (July–August 2004). "Accuracy and the accused: Psychologists work with law enforcement on research-based improvements to crime-suspect identification". Monitor on Psychology. 35 (7). American Psychological Association: 74.
  41. ^ Koerner BI (July–August 2002). "Under the Microscope". Legal Affairs. Retrieved 2 May 2018.
  42. ^ Miller CC (25 February 2016). "Is Blind Hiring the Best Hiring?". The New York Times. Retrieved 26 April 2019.
  43. ^ "Violinists can't tell the difference between Stradivarius violins and new ones" by Ed Yong, Discover, 2 January 2012.
  44. ^ Fritz, C. (2012). "Player preferences among new and old violins". Proceedings of the National Academy of Sciences. 109 (3): 760–63. Bibcode:2012PNAS..109..760F. doi:10.1073/pnas.1114999109. PMC 3271912. PMID 22215592.