Invited commentaries on: Obstetric complications and schizophrenia/affective psychoses{dagger}

T.J. Crow, POWIC

University Department of Psychiatry, Warneford Hospital, Oxford OX3 7JX

{dagger} See pp.516-526, this issue. Back


   DO OBSTETRIC COMPLICATIONS REALLY CAUSE PSYCHOSIS? WHY IT MATTERS
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Kendell et al's study (2000, this issue) is unusual in the psychiatric literature in that it addresses a hypothesis that the authors have previously espoused, generates new data which conflict with those of an earlier investigation, re-investigates the foundation of the previous conclusion and finds it wanting, and reaches a negative conclusion with respect to the original hypothesis. The findings are presented with exemplary clarity and honesty. The authors report that they are convinced that the results of their 1996 study were seriously misleading, and that the data they now present are accurate and dependable and fail to yield "any substantial evidence that the incidence of obstetric complications in people who subsequently develop schizophrenia is raised".

Previous literature
There were already grounds for suspecting this conclusion. In their meta-analysis Geddes & Lawrie (1995) noted significant heterogeneity of findings with respect to study design. The literature as a whole suggested an odds ratio of two for exposure to ‘obstetric complications’ on subsequent development of schizophrenia, but this depended upon the preponderance of studies that had used a retrospective case-control design. In the words of an early proponent (Lewis, 1989) of the birth complications hypothesis:

"Paradoxically the main similarity between the studies is their collective weakness: the use of retrospective assessment of obstetric histories even if assessed blindly".

The possibility that the mother of a child who has developed psychosis will be biased with respect to the events of the pregnancy when asked to recall them, or even before this, is a real one. In addition, Geddes & Lawrie (1995) noted evidence (in a funnel plot) of a publication bias in favour of positive findings. The two cohort studies (Done et al, 1991; Buka et al, 1993) that avoided the recall bias gave an odds ratio of one, with the implication that obstetric complications and the development of schizophrenia are simply unrelated.

Meta-analysis is no defence against such biases. Geddes et al (1999) re-analysed the data from 12 studies, seven of which depended upon maternal recall, and five of which, including the original study of Kendell et al (1996), relied upon retrieval of obstetric records, but omitted the cohort studies. This time the pooled odds ratio was 1.4. The estimate reflects not only an aggregated bias (the ‘Lewis effect’) across maternal recall studies but, as Kendell et al (2000, this issue) now make clear, problems in the selection of the controls in retrospective comparisons of obstetric records.

The British Perinatal Mortality Survey recorded systematic data on the antenatal courses and births of 16980 individuals born in the week 3-9 March 1958.

Those who had developed schizophrenia by either broad or narrow criteria by the age of 28 years were not more likely than the cohort as a whole to have experienced events predicting mortality in the perinatal period (Done et al, 1991). Nor were those 945 mothers who were recorded as suffering from influenza in the second trimester in the autumn of 1957 more likely to have children who later developed schizophrenia (Crow & Done, 1992; Crow, 1997b,c). A subsequent analysis of the many variables recorded in this cohort (Sacker et al, 1995) suggested that those indices that distinguished patients from controls related more to the characteristics of the mother (for example she more often had psychosocial problems, more often weighed less than 51 kg, and had fewer antenatal attendances) than to complications of the birth itself. Low birth weight (<2500 g) was more frequent in the patient group, as it was also in the recent cohort study of Jones et al (1998) who, as noted by Kendell et al (2000, this issue), concluded that the differences they found "appeared to be due largely to the characteristics of the child, not the delivery".

Core problem of aetiology
The cohort studies, consistent with the conclusions of Kendell et al (1996), thus give no support to the hypothesis that obstetric complications in general or any complication in particular is a cause of later schizophrenic illness. The importance of this conclusion is that it raises the question of whether there are any environmental contributions to the aetiology of schizophrenia. Only two — birth complications and prenatal exposure to influenza — have been seriously considered in the recent literature and both are now cast in considerable doubt.

This clears the air and brings the essential peculiarity of psychotic illness into focus — we are confronted with a phenomenon that is intrinsic, and therefore one might suppose ‘genetic’ in origin, and apparently universal in human populations (Jablensky et al, 1992) but that yet is associated with a substantial biological (fecundity) disadvantage. In what sense is this a disease? What sort of genes are these? Why are they not rapidly selected out of the population?

A clue to the answer lies in the nature of the brain changes. The three best established — an increase in ventricular size, a modest reduction in cortical mass and diminution or reversal of the asymmetrical torque across the antero-posterior axis (Bilder et al, 1994; DeLisi et al, 1997) — do not identify sub-populations, and must clearly be related. They cannot be attributed to birth injury or other environmental insult. They are present early in illness course, are ‘developmental’ in origin and reflect the nature of the genetic variation. Whereas it is often argued, particularly in the light of the apparent failure of the genetic linkage approach (DeLisi & Crow, 1999), that psychosis is the outcome of many genes of small effect, the morphology of the brain, as yet ill understood, suggests otherwise.

The brain changes and their independence of environmental influence, along with universal incidence and persistence against a biological disadvantage (the ‘central paradox’), indicate a homogeneity to the phenomena of psychosis that is close to the core characteristics of the species. The genetic variation therefore may differ from that associated with other ‘disease-related’ genes, for example, cystic fibrosis and Huntington's disease. One can ask is variation (apparently relevant to survival) that persists across populations independent of the environment the same as that which results from random mutation and inheritance within families according to Mendelian rules? This provokes the parallel question of whether variation within a species is of the same nature as that which separates species, a question that relates to the nature of species transitions.

Perhaps only when we are free from the concept of ‘schizophrenia’ as a categorical disease entity with multiple environmental causes yet to be discovered can we appreciate the true significance of psychosis as a component of the variation that identifies the species (Crow, 1998a). Such an insight helps us to understand the nature of the symptoms. The answer that I have given to the question first raised by Huxley et al (1964) of what the genetic advantage that balances the disadvantage associated with schizophrenia is is language. The capacity for language defines the species (Bickerton, 1995), it arose some time between 100 000 and 150 000 years ago, and was the result of a relatively discrete genetic change that occurred in a population in east Africa (Stringer & McKie, 1996). This event, perhaps because it introduced a differentiation of function of the hemispheres, allowed language to evolve.

Schizophrenia, according to this view, is the price that Homo sapiens pays for language (Crow, 1997a). It follows that schizophrenic symptoms can be understood as disorders of language, and more fundamentally as the key to the cerebral organisation of language. Nuclear symptoms can be understood as anomalies of the transition from thought to speech, and as an indication that a mechanism of ‘indexicality’ that distinguishes between what is self- and other-generated is a necessary component of the bihemispheric organisation of language (Crow, 1998b). Delusions can be understood as disorders of the transition from speech to meaning, that is as semantic deviations. The fact that nuclear symptoms and other types of delusion are so frequently associated, and that both these classes of psychotic phenomena are sometimes associated with ‘thought disorder’, indicates that the neural bases of syntax and semantics are not independent.

The reason why the disadvantageous ‘genotypes’ associated with psychotic symptoms are not selected out must be that the variation is inherent in the genetic mechanism, the characteristics of which reflect an origin in the transition (through a ‘speciation event’) from a precursor hominid to modern Homo sapiens (Crow, 1998c,d). It has been suggested that epigenetic modification (e.g. methylation) is particularly associated with species transitions (Vrana et al, 1998). Therefore, an alternative to the view that the inherited variation is polygenic and Mendelian is that it is speciation-related and ‘epigenetic’. A recent twin study can be interpreted as consistent with this concept (Crow, 1999).

Why it matters
Why I think a resolution of the question of obstetric complications is important is that so long as it is believed that there are significant environmental causes of schizophrenic illness the central problem posed by the phenomena of psychosis is obscured. The singularity of the intrinsic variation and its wider significance for an understanding of language and the nature of speciation events is unappreciated. If as Kendell et al conclude "the evidence that schizophrenia is associated with a raised incidence of obstetric complications is weaker than has been assumed", some undergrowth that stands in the way of an understanding of the nature of the problem has been cleared away. As Darwin remarked: "False facts are highly injurious to the progress of science for they often endure long; but false views... do little harm, as everyone takes a salutary pleasure in proving their falseness, and when this is done, one path toward error is closed and the road to truth is often at the same time opened" (Darwin, 1871).


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Bickerton, D. (1995) Language and Human Behavior. Seattle, WA: University of Washington.

Bilder, R. M., Wu, H., Degreef, G., et al (1994) Yakovlevian torque is absent in first-episode schizophrenia. American Journal of Psychiatry, 151, 1437-1447.[Abstract]

Buka, S. L., Tsuang, M. T. & Lipsitt, L. P. (1993) Pregnancy/delivery complications and psychiatric diagnosis. Archives of General Psychiatry, 50, 151-156.[Abstract]

Crow, T.J. (1997a) Is schizophrenia the price that Homo sapiens pays for language? Schizophrenia Research, 28, 127-141.[CrossRef][Medline]

Crow, T.J. (1997b) Influenza and schizophrenia (letter). British Journal of Psychiatry, 169, 790-791.[Medline]

Crow, T.J. (1997c) Influenza and schizophrenia (letter). British Journal of Psychiatry, 170, 578.[Medline]

Crow, T.J. (1998a) From Kraepelin to Kretschmer leavened by K. Schneider: the transition from categories of psychosis to dimensions of variation intrinsic to Homo sapiens. Archives of General Psychiatry, 55, 502-504.[Free Full Text]

Crow, T.J. (1998b) Nuclear schizophrenic symptoms as a window on the relationship between thought and speech. British Journal of Psychiatry, 173, 303-309.[Abstract]

Crow, T.J. (1998c) Sexual selection, timing and the descent of man: a genetic theory of the evolution of language. Current Psychology of Cognition, 17, 1079-1114.

Crow, T.J. (1998d) Why cerebral asymmetry is the key to the origin of Homo sapiens: how to find the gene or eliminate the theory. Current Psychology of Cognition, 17, 1237-1277.

Crow, T.J. (1999) Twin studies of psychosis and the genetics of cerebral asymmetry. British Journal of Psychiatry, 175, 399-401.[Medline]

Crow, T.J. & Done, D.J. (1992) Prenatal exposure to influenza does not cause schizophrenia. British Journal of Psychiatry, 161, 390-393.[Abstract]

Darwin, C. (1871) The Descent of Man, and Selection in Relation to Sex, ch. XXI. London: J. Murray.

DeLisi, L.E., Sakuma, M., Kushner, M., et al (1997) Anomalous cerebral asymmetry and language processing in schizophrenia. Schizophrenia Bulletin, 23, 255-271.[Medline]

DeLisi, L.E. & Crow, T.J. (1999) Chromosome Workshops 1998: Current state of psychiatric linkage. American Journal of Medical Genetics, 88, 215-218.[CrossRef][Medline]

Done, D.J., Johnstone, E.C., Frith, C.D., et al (1991) Complications of pregnancy and delivery in relation to psychosis in adult life: data from the British perinatal mortality survey sample. British Medical Journal, 302, 1576-1580.[Medline]

Geddes, J.R. & Lawrie, S.M. (1995) Obstetric complications and schizophrenia: a meta-analysis. British Journal of Psychiatry, 167, 786-793.[Abstract]

Geddes, J.R., Verdoux, H., Takei, N., et al (1999) Schizophrenia and complications of pregnancy and labor. Schizophrenia Bulletin, 25, 413-423.[Medline]

Huxley, J., Mayr, E., Osmond, H., et al (1964) Schizophrenia as a genetic morphism. Nature, 204, 220-221.

Jablensky, A., Sartorius, N., Ernberg, G., et al (1992) Schizophrenia: manifestations, incidence and course in different cultures. A World Health Organization Ten-Country Study. Psychological Medicine, suppl. 20, 1-97.

Jones, P.B., Rantakallio, P. & Hartikainen, A. (1998) Schizophrenia as a long-term outcome of pregnancy, delivery and perinatal complications: a 28-year follow up of the 1966 North Finland general population birth cohort. American Journal of Psychiatry, 155, 355-364.[Abstract/Free Full Text]

Kendell, R.E., Juszczak, E. & Cole, S.K. (1996) Obstetric complications and schizophrenia: a case control study based upon standardised obstetric records. British Journal of Psychiatry, 168, 556-561.[Abstract]

Kendell, R.E., McInneny, K., Juszczak, E., et al (2000) Obstetric complications and schizophrenia. Two case-control studies based on structured obstetric records. British Journal of Psychiatry, 176, 516-522.[Abstract/Free Full Text]

Lewis, S.W. (1989) Congenital risk factors for schizophrenia. Psychological Medicine, 19, 5-13.[Medline]

Sacker, A., Done, D.J., Crow, T.J., et al (1995) Antecedents of schizophrenia and affective illness. Obstetric complications. British Journal of Psychiatry, 166, 734-741.[Abstract]

Stringer, C. & McKie, R. (1996) African Exodus: The Origins of Modern Humanity. London: Jonathan Cape.

Vrana, P.B., Guan, X.-J. & Tilghman, S.M. (1998) Genomic imprinting is disrupted in interspecific hybrids. Nature Genetics, 20, 362-365.[CrossRef][Medline]


Related articles in BJP:

Obstetric complications and schizophrenia: Two case-control studies based on structured obstetric records
R. E. KENDELL, K. McINNENY, E. JUSZCZAK, and M. BAIN
BJP 2000 176: 516-522. [Abstract] [Full Text]