Hazards of clinical trials

Hazards of clinical trials

876 We believe, first, that decisions about priorities for support in developing countries should be made by the countries themselves and not by offi...

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876

We believe, first, that decisions about priorities for support in developing countries should be made by the countries themselves and not by officers from agencies located in developed countries. In addition to assessment of research design, the role of such agencies should be evaluation of the project, which should clearly show that the work is a local priority. Second, research institutions in developing countries need to collaborate well and strengthen their activities. Third, training of professionals from developing countries should be implemented by local institutions, which would ensure that the focus of training is closer to these countries’ needs, and an easier return home for the trainee. Our centre is presently providing a one-year postgraduate training course on research methodology for physicians in Latin America, supported by IDRC and HRP/WHO. In this course skills in the epidemiological and analytical methods to assess priorities are developed. In 1993, we will initiate a training programme for statisticians. However, every year our centre has to interrupt its activities because funds are obtained through a few institutions that provide non-aligned grants and because support for the training programme has to be renewed yearly. This situation leads to our last recommendation-to promote the long-term institutional support from funding agencies to guarantee the continuity of activities. Centro Rosarino de Estudios Perinatales, Orono 500, 2000 Rosario, Argentina

JOSÉ M. BELIZAN

1. The Commission on Health Research for Development. Health research: essential link to equity in development. Oxford: Oxford University Press, 1990.

Proof of causation SIR,-Mr Meeran (March 14, p 671) states that the standard of proof in legal cases is far less stringent than the standard applied in science. He suggests that experts called to present scientific evidence in court do not unduly restrict themselves to the traditional 95 % confidence interval (CI). The fallacy in his reasoning is that the "balance of probabilities" standard used in civil actions the (" > 50% rule") should not be compared to the CI (or degree-ofcertainty figure) used by epidemiologists. If anything, the burden of proof in civil actions is more comparable with the relative risk (RR) or the aetiological fraction (EF), and several US courts have recognised this. The causation issues dealt with in civil actions and by medical scientists are not the same. In a civil action the causation issue is typically whether the plaintiffs injuries were caused by agent X. Population-based studies by medical experts cannot answer the question of individual causation; they merely show whether an individual is at an increased risk if he or she is a member of a certain group. Since increased risk of future disease is generally not recoverable in American courts (unless the likelihood is > 50%), the broader question of whether a substance causes a statistically significant increased risk of disease is usually not in issue. It has been suggestedl that the > 50% burden of proof in civil cases is met when the EF exceeds 0-5 (RR > 20) because more than half the cases of the disease of interest in an exposed group are caused by exposure to agent X. While this is a more accurate analogy than the comparison to CI, this comparison is also vulnerable. The late Sir Austin-Bradford Hill pointed out many years ago that a statistically significant association is not equivalent to causation. Nor does the RR answer the issue of individual causation at issue in a tort action. If half the cases of the disease of interest in the exposed group may have been caused by agent X, half were not; and the study gives the jury and the judge no clue about which group the plaintiff falls into. Meeran’s suggestion that expert witnesses should consider using relaxed CIs is invalid. Judicial institutions do not and should not proceed oblivious to the well-established practices of scientific institutions. American courts typically require that methods used by testifying experts be generally accepted in the scientific discipline from which the expert comes. In fact, some American courts have specifically held that the 95% CIs must be applied by witnesses before their opinion will be allowed before a jury (eg, Brock v

Merrell Dow Pharm Inc [

1989] and Ealy v Richardson-Merrell Inc

[1990]). Traditional notions of causation in epidemiology (ie, RR > 2.0at 95 % CI) are not at all incompatible with the burden of proof in civil tort actions.2 Moreover, there is no rational public policy which would support the adoption of "second-tier" science in our judicial institutions. Sidley and Austin, One First National Plaza, Chicago, Illinois 60603, USA

TIMOTHY E. KAPSHANDY

1. Muscat JE, Huncharek MS. Causation and disease: biomedical science in toxic ton litigation. J Occup Med 1989, 31: 997-1002. 2. Kaye DH. Apples and oranges: confidence coefficients and the burden of persuasion Cornell Law Rev 1987; 73: 54-77.

Hazards of clinical trials SIR,—Your editorial (Dec 14, p 1495) points out the influence of controlled clinical trials on patient psychology. The possible adverse effects inherent in a trial may be termed trial morbidity, which might have contributed to the difference in mortality between the trial group and control group (who received "usual health care") seen several years after stopping the treatments in the Finnish Study. Another classic setting in which such morbidity might arise is an early intervention trial in patients with acute myocardial infarction. These patients are subjected to the mentally taxing process of decision making about participation in a trial while they are in emotional, physical, and psychological distress during the acute stages of the disease, and recent reports have implicated in-hospital psychological stress as a predictor for long-term cardiac mortality and re-infarction after acute myocardial infarction.2 It would be difficult to estimate trial morbidity, unless the intervention or drug is administered without the knowledge of the patient, which would be unethical. Follow-up of large trials and analysis at varying periods after the completion of the trial (with a knowledge of baseline psychological characteristics of different groups) may help to quantify and trace the causes of trial morbidity. Department of Medicine, Medical College, Calicut, Kerala, India 1.

2.

P. DILEEP KUMAR

Strandberg TE, Salomaa VV, Naukkarinen VA, Vanhanen HT, Sarna SJ, Miettinen TA. Long term mortality after 5 years multifactorial primary prevention of cardiovascular disease in middle aged men. JAMA 1991; 266: 1225-29. Frasure-Smith N. In-hospital symptoms of psychological stress as predictors of long-term outcome after acute myocardial infarction in men. Am J Cardiol 1991; 67: 121-27.

Chorionic villus sampling and limb abnormalities SIR,-Following reports of an association between chorionic villus sampling (CVS) and limb abnormalities,!,2an investigation was made in seven European Registration of Congenital Anomalies and Twins (EUROCAT) registries surveying altogether more than 600 000 births (table). These registries cover geographically defined populations. Malformations were registered for live births, stillbirths, and terminations after the diagnosis of malformation, except in Switzerland, where case-registration was restricted to live births. CVS exposure was recorded on the routine case-report forms of malformed babies, except in Odense, where registry data were matched to a known cohort of exposed women for this study. Where possible, extra information on the timing of exposure was sought. Chromosomal syndromes are not included in this report, since a high rate of exposure to CVS would be expected for such cases. Exposed cases with monogenic syndromes for which CVS could be indicated were also excluded. The exposure rate among cases of limb reduction is compared with the exposure rate among other anomalies in the table. 336 cases of limb reduction were reviewed, of which 4 (1-2%) had CVS exposure. In 11 883 cases of other congenital anomalies, 78 (066%) had CVS exposure, giving an odds ratio of 1 -8 (95% CI 0.66-4.99).