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Exposure to genocide and the risk of schizophrenia: a population-based study

Published online by Cambridge University Press:  01 December 2015

S. Z. Levine ,
I. Levav ,
Y. Goldberg ,
I. Pugachova ,
Y. Becher  and
R. Yoffe
S. Z. Levine*
Affiliation:
Department of Community Mental Health, Faculty of Social Welfare and Health Sciences, University of Haifa, Haifa, Israel
I. Levav
Affiliation:
Department of Community Mental Health, Faculty of Social Welfare and Health Sciences, University of Haifa, Haifa, Israel
Y. Goldberg
Affiliation:
Department of Statistics, Faculty of Social Sciences, University of Haifa, Haifa, Israel
I. Pugachova
Affiliation:
Department of Information and Evaluation, Ministry of Health, Jerusalem, Israel
Y. Becher
Affiliation:
Department of Information and Evaluation, Ministry of Health, Jerusalem, Israel
R. Yoffe
Affiliation:
Department of Information and Evaluation, Ministry of Health, Jerusalem, Israel
*
*Address for correspondence: S. Z. Levine, Ph.D., Department of Community Mental Health, Faculty of Social Welfare and Health Sciences, University of Haifa, Haifa 3498838, Israel. (Email: [email protected])
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Abstract

Background

No evidence exists on the association between genocide and the incidence of schizophrenia. This study aims to identify critical periods of exposure to genocide on the risk of schizophrenia.

Method

This population-based study comprised of all subjects born in European nations where the Holocaust occurred from 1928 to 1945, who immigrated to Israel by 1965 and were indexed in the Population Register (N = 113 932). Subjects were followed for schizophrenia disorder in the National Psychiatric Case Registry from 1950 to 2014. The population was disaggregated to compare groups that immigrated before (indirect exposure: n = 8886, 7.8%) or after (direct exposure: n = 105 046, 92.2%) the Nazi or fascist era of persecutions began. The latter group was further disaggregated to examine likely initial prenatal or postnatal genocide exposures. Cox regression modelling was computed to compare the risk of schizophrenia between the groups, adjusting for confounders.

Results

The likely direct group was at a statistically (p < 0.05) greater risk of schizophrenia (hazard ratio = 1.27, 95% confidence interval 1.06–1.51) than the indirect group. Also, the likely combined in utero and postnatal, and late postnatal (over age 2 years) exposure subgroups were statistically at greater risk of schizophrenia than the indirect group (p < 0.05). The likely in utero only and early postnatal (up to age 2 years) exposure subgroups compared with the indirect exposure group did not significantly differ. These results were replicated across three sensitivity analyses.

Conclusions

This study showed that genocide exposure elevated the risk of schizophrenia, and identified in utero and postnatal (combined) and late postnatal (age over 2 years) exposures as critical periods of risk.

Keywords

Fetal originsholocaustmalnutritionrefugeesschizophrenia
Type
Original Articles
Information
Psychological Medicine , Volume 46 , Issue 4 , March 2016 , pp. 855 - 863
Copyright
Copyright © Cambridge University Press 2015 

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References

Antonovsky, A, Maoz, B, Dowty, N, Wijsenbeek, H (1971). Twenty-five years later: a limited study of the sequelae of the concentration camp experience. Social Psychiatry 6, 186193.Google Scholar
Aragón, TJ, Enanoria, WT, Fay, M, Porco, T, Samuel, M (2007). Applied Epidemiology using R. MedEpi Publishing: San Francisco, CA.Google Scholar
Bachar, E, Canetti, L, Berry, EM (2005). Lack of long-lasting consequences of starvation on eating pathology in Jewish Holocaust survivors of Nazi concentration camps. Journal of Abnormal Psychology 114, 165169.Google Scholar
Barel, E, Van, IMH, Sagi-Schwartz, A, Bakermans-Kranenburg, MJ (2010). Surviving the Holocaust: a meta-analysis of the long-term sequelae of a genocide. Psychological Bulletin 136, 677698.Google Scholar
Bauer, J (1992). History of the Holocaust. Franklin Watts: New York.Google Scholar
Central Bureau of Statistics (1995). Demographic Characteristics of the Population in Localities and Statistical Areas. Central Bureau of Statistics: Jerusalem.Google Scholar
Cohen, Y (1988). War and social integration – the effects of the Israeli–Arab conflict on Jewish emigration from Israel. American Sociological Review 53, 908918.Google Scholar
Davidson, M, Reichenberg, A, Rabinowitz, J, Weiser, M, Kaplan, Z, Mark, M (1999). Behavioral and intellectual markers for schizophrenia in apparently healthy male adolescents. American Journal of Psychiatry 156, 13281335.Google Scholar
Dohrenwend, BP, Levav, I, Shrout, PE, Schwartz, S, Naveh, G, Link, BG, Skodol, AE, Stueve, A (1992). Socioeconomic status and psychiatric disorders: the causation–selection issue. Science 255, 946952.Google Scholar
Eitinger, L (1972). Concentration Camp Survivors in Norway and Israel. Martinus Nijhoff: The Hague.Google Scholar
Elmer, BM, Estes, ML, Barrow, SL, McAllister, AK (2013). MHCI requires MEF2 transcription factors to negatively regulate synapse density during development and in disease. Journal of Neuroscience 33, 1379113804.Google Scholar
Fenig, S, Levav, I (1991). Demoralization and social supports among Holocaust survivors. Journal of Nervous Mental Disease 179, 167172.Google Scholar
Harris, A, Seckl, J (2011). Glucocorticoids, prenatal stress and the programming of disease. Hormones and Behavior 59, 279289.Google Scholar
Helweg-Larsen, P, Hoffmeyer, H, Kieler, J, Hess Thaysen, E, Hess Thaysen, J, Thygesen, P, Hertel Wulff, M (1952). Famine disease in German concentration camps; complications and sequels, with special reference to tuberculosis, mental disorders and social consequences. Acta Psychiatrica et Neurologica Scandinavica Supplementum 83, 1460.Google Scholar
Jones, PB, Bebbington, P, Foerster, A, Lewis, SW, Murray, RM, Russell, A, Sham, PC, Toone, BK, Wilkins, S (1993). Premorbid social underachievement in schizophrenia. Results from the Camberwell Collaborative Psychosis Study. British Journal of Psychiatry 162, 6571.Google Scholar
Keinan-Boker, L, Vin-Raviv, N, Liphshitz, I, Linn, S, Barchana, M (2009). Cancer incidence in Israeli Jewish survivors of World War II. Journal of the National Cancer Institute 101, 14891500.Google Scholar
Kral, VA (1951). Psychiatric observations under severe chronic stress. American Journal of Psychiatry 108, 185192.Google Scholar
Lemkin, R (1944). Axis Rule in Occupied Europe: Laws of Occupation, Analysis of Government, Proposals for Redress. Carnegie Endowment of International Peace, Division of International Law: Washington, DC.Google Scholar
Levav, I (1998). Individuals under conditions of maximum adversity: The Holocaust. In Adversity, Stress, and Psychopathology (ed. Dohrenwend, B. P.), pp. 1333. Oxford University Press: New York.Google Scholar
Levav, I (2015). The aftermath of the European and Rwandan genocides. In Violence and Mental Health (ed. Lindert, J. and Levav, I.), pp. 303338. Springer: New York.Google Scholar
Levav, I, Grinshpoon, A (2004). Mental health services in Israel. International Psychiatry 4, 1014.Google Scholar
Levav, I, Lipshitz, I, Novikov, I, Pugachova, I, Kohn, R, Barchana, M, Ponizovsky, A, Werner, H (2007). Cancer risk among parents and siblings of patients with schizophrenia. British Journal of Psychiatry 190, 156161.Google Scholar
Levine, SZ, Levav, I, Yoffe, R, Pugachova, I (2014). The effects of pre-natal-, early-life- and indirectly-initiated exposures to maximum adversities on the course of schizophrenia. Schizophrenia Research 158, 236240.Google Scholar
Lumey, LH, Stein, AD, Susser, E (2011). Prenatal famine and adult health. Annual Review of Public Health 32, 237262.Google Scholar
Marenco, S, Weinberger, DR (2000). The neurodevelopmental hypothesis of schizophrenia: following a trail of evidence from cradle to grave. Development and Psychopathology 12, 501527.Google Scholar
Marques, AH, O'Connor, TG, Roth, C, Susser, E, Bjorke-Monsen, AL (2013). The influence of maternal prenatal and early childhood nutrition and maternal prenatal stress on offspring immune system development and neurodevelopmental disorders. Frontiers in Neuroscience 7, 120.Google Scholar
Ministry of Health (2009). Mental Health in Israel: Statistical Annual, 2008. Ministry of Health: Jerusalem.Google Scholar
Morgan, C, Fisher, H (2007). Environment and schizophrenia: environmental factors in schizophrenia: childhood trauma – a critical review. Schizophrenia Bulletin 33, 310.Google Scholar
Murray, RM, Lewis, SW (1987). Is schizophrenia a neurodevelopmental disorder? British Medical Journal 295, 681682.Google Scholar
Nakash, O, Liphshitz, I, Keinan-Boker, L, Levav, I (2013). The effect of cancer on suicide among elderly Holocaust survivors. Suicide and Life Threatening Behavior 43, 290295.Google Scholar
Pat-Horenczyk, R, Ziv, Y, Asulin-Peretz, L, Achituv, M, Cohen, S, Brom, D (2013). Relational trauma in times of political violence: continuous versus past traumatic stress. Peace and Conflict 19, 125137.Google Scholar
R Core Team (2014). R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing: Vienna.Google Scholar
Rabinowitz, J, Slyuzberg, M, Ritsner, M, Mark, M, Popper, M, Ginath, Y (1994). Changes in diagnosis in a 9-year national longitudinal sample. Comprehensive Psychiatry 35, 361365.Google Scholar
Sagi-Schwartz, A, Bakermans-Kranenburg, MJ, Linn, S, van Ijzendoorn, MH (2013). Against all odds: genocidal trauma is associated with longer life-expectancy of the survivors. PLOS ONE 8, e69179.Google Scholar
Selten, JP, Cantor-Graae, E (2007). Hypothesis: social defeat is a risk factor for schizophrenia? British Journal of Psychiatry Supplement 51, s9s12.Google Scholar
Selten, JP, Cantor-Graae, E, Nahon, D, Levav, I, Aleman, A, Kahn, RS (2003). No relationship between risk of schizophrenia and prenatal exposure to stress during the Six-Day War or Yom Kippur War in Israel. Schizophrenia Research 63, 131135.Google Scholar
Selten, JP, van der Ven, E, Rutten, BP, Cantor-Graae, E (2013). The social defeat hypothesis of schizophrenia: an update. Schizophrenia Bulletin 39, 11801186.Google Scholar
Sharon, A, Levav, I, Brodsky, J, Shemesh, AA, Kohn, R (2009). Psychiatric disorders and other health dimensions among Holocaust survivors 6 decades later. British Journal of Psychiatry 195, 331335.Google Scholar
Shonkoff, JP, Boyce, WT, McEwen, BS (2009). Neuroscience, molecular biology, and the childhood roots of health disparities: building a new framework for health promotion and disease prevention. Journal of the American Medical Association 301, 22522259.Google Scholar
Shuval, JT (1957). Some persistent effects of trauma: five years after the Nazi concentration camps. Social Problems 5, 230243.Google Scholar
Solomon, Z, Prager, E (1992). Elderly Israeli Holocaust survivors during the Persian Gulf War: a study of psychological distress. American Journal of Psychiatry 149, 17071710.Google Scholar
St Clair, D, Xu, M, Wang, P, Yu, Y, Fang, Y, Zhang, F, Zheng, X, Gu, N, Feng, G, Sham, P, He, L (2005). Rates of adult schizophrenia following prenatal exposure to the Chinese famine of 1959–1961. Journal of the American Medical Association 294, 557662.Google Scholar
Susser, E, Neugebauer, R, Hoek, HW, Brown, AS, Lin, S, Labovitz, D, Gorman, JM (1996). Schizophrenia after prenatal famine. Further evidence. Archives of General Psychiatry 53, 2531.Google Scholar
Susser, M, Stein, Z (1994). Timing in prenatal nutrition: a reprise of the Dutch Famine Study. Nutrition Reviews 52, 8494.Google Scholar
Therneau, TM (2000). Modeling Survival Data: Extending the Cox Model. Springer: New York.Google Scholar
Torrey, EF, Yolken, RH (2010). Psychiatric genocide: Nazi attempts to eradicate schizophrenia. Schizophrenia Bulletin 36, 2632.Google Scholar
Varese, F, Smeets, F, Drukker, M, Lieverse, R, Lataster, T, Viechtbauer, W, Read, J, van Os, J, Bentall, RP (2012). Childhood adversities increase the risk of psychosis: a meta-analysis of patient–control, prospective- and cross-sectional cohort studies. Schizophrenia Bulletin 38, 661671.Google Scholar
Weinberger, D (1986). The pathogenesis of schizophrenia: a neurodevelopmental theory. Handbook of Schizophrenia 1, 397406.Google Scholar
Weinberger, DR (1987). Implications of normal brain development for the pathogenesis of schizophrenia. Archives of General Psychiatry 44, 660669.CrossRefGoogle ScholarPubMed
Weiser, M, Kanyas, K, Malaspina, D, Harvey, PD, Glick, I, Goetz, D, Karni, O, Yakir, A, Turetsky, N, Fennig, S, Nahon, D, Lerer, B, Davidson, M (2005). Sensitivity of ICD-10 diagnosis of psychotic disorders in the Israeli National Hospitalization Registry compared with RDC diagnoses based on SADS-L. Comprehensive Psychiatry 46, 3842.Google Scholar
Weiser, M, Reichenberg, A, Rabinowitz, J, Kaplan, Z, Mark, M, Nahon, D, Davidson, M (2000). Gender differences in premorbid cognitive performance in a national cohort of schizophrenic patients. Schizophrenia Research 45, 185190.Google Scholar
Weiser, M, Werbeloff, N, Dohrenwend, BP, Levav, I, Yoffe, R, Davidson, M (2012). Do psychiatric registries include all persons with schizophrenia in the general population? A population-based longitudinal study. Schizophrenia Research 135, 187191.CrossRefGoogle ScholarPubMed
Xu, MQ, Sun, WS, Liu, BX, Feng, GY, Yu, L, Yang, L, He, G, Sham, P, Susser, E, St Clair, D, He, L (2009). Prenatal malnutrition and adult schizophrenia: further evidence from the 1959–1961 Chinese famine. Schizophrenia Bulletin 35, 568576.Google Scholar
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