The Anatomy of Violence

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by Adrian Raine


  88. Gatzke-Kopp, L. M. & Beauchaine, T. P. (2007). Direct and Passive Prenatal Nicotine Exposure and the Development of Externalizing Psychopathology. Child Psychiatry and Human Development 38, 255–69.

  89. Olds, D. (1997). Tobacco exposure and impaired development: A review of the evidence. Mental Retardation and Developmental Disabilities Research Reviews 3, 257–69.

  90. Jaddoe, V.W.V., Verburg, B. O., de Ridder, M.A.J., et al. (2007). Maternal smoking and fetal growth characteristics in different periods of pregnancy: The Generation R Study. American Journal of Epidemiology 165, 1207–15.

  91. Toro, R., Leonard, G., Lerner, J., et al. (2008). Prenatal exposure to maternal cigarette smoking and the adolescent cerebral cortex. Neuropsychopharmacology 33, 1019–27.

  92. Cornelius, M. D. & Day, N. L. (2009). Developmental consequences of prenatal tobacco exposure. Current Opinion in Neurology 22, 121–25.

  93. Batstra, L., Hadders-Algra, M. & Neeleman, J. (2003). Effect of antenatal exposure to maternal smoking on behavioural problems and academic achievement in childhood; prospective evidence from a Dutch birth cohort. Early Human Development 75, 21–33.

  94. Levin, E. D., Wilkerson, A., Jones, J. P., Christopher, N. C. & Briggs, S. J. (1996). Prenatal nicotine effects on memory in rats: Pharmacological and behavioral challenges. Developmental Brain Research 97, 207–15.

  95. Slotkin, T. A., Epps, T. A., Stenger, M. L., Sawyer, K. J. & Seidler, F. J. (1999). Cholinergic receptors in heart and brainstem of rats exposed to nicotine during development: Implications for hypoxia tolerance and perinatal mortality. Brain Research 113, 1–12.

  96. Huizink, A. C. & Mulder, E.J.H. (2006). Maternal smoking, drinking or cannabis use during pregnancy and neurobehavioral and cognitive functioning in human offspring. Neuroscience and Biobehavioral Reviews 30, 24–41.

  97. Wikipedia, http://en.wikipedia.org/wiki/Robert_Alton_Harris.

  98. California Department of Corrections and Rehabilitation, http://www.cdcr.ca.gov/Reports_Research/robertHarris.html.

  99. Jones, K. L. & Smith, D. W. (1973). Recognition of the fetal alcohol syndrome in early infancy. Lancet 2, 999–1012.

  100. Sampson, P. D., Streissguth, A. P., Bookstein, F. L., Little, R. E., Clarren, S. K., et al. (1997). Incidence of fetal alcohol syndrome and prevalence of alcohol-related neurodevelopmental disorder. Teratology 56, 317–26.

  101. Streissguth, A. P., Bookstein, F. L., Barr, H. M., Sampson, P. D., O’Malley, K. & Young, J. K. (2004). Risk factors for adverse life outcomes in fetal alcohol syndrome and fetal alcohol effects. Developmental and Behavioral Pediatrics 25, 228–38.

  102. Fast, D. K., Conry, J. & Loock, C. A. (1999). Identifying fetal alcohol syndrome among youth in the criminal justice system. Journal of Developmental & Behavioral Pediatrics 20, 370–72.

  103. Sowell, E. R., Johnson, A., Kan, E., Lu, L. H., Van Horn, J. D., et al. (2008). Mapping white matter integrity and neurobehavioral correlates in children with fetal alcohol spectrum disorders. Journal of Neuroscience 28, 1313–19.

  104. Connor, P. D., Sampson, P. D., Bookstein, F. L., Barr, H. M. & Streissguth, A. P. (2000). Direct and indirect effects of prenatal alcohol damage on executive function. Developmental Neuropsychology 18, 331–54.

  105. Batstra, L., et al., Effect of antenatal exposure to maternal smoking on behavioural problems and academic achievement in childhood.

  106. Riikonen, R., Salonen, I., Partanen, K. & Verho, S. (1999). Brain perfusion SPECT and MRI in foetal alcohol syndrome. Developmental Medicine & Child Neurology 41, 652–59.

  107. Sood, B., Delaney-Black, V., Covington, C., Nordstrom-Klee, B., Ager, J., et al. (2001). Prenatal alcohol exposure and childhood behavior at age 6 to 7 years, vol. I, Dose–response effect. Pediatrics 108. doi:10.1542/ peds.108.

  108. Qiang, M., Wang, M. W. & Elberger, A. J. (2002). Second trimester prenatal alcohol exposure alters development of rat corpus callosum. Neurotoxicology and Teratology 6, 719–32.

  7. A RECIPE FOR VIOLENCE

  1. Van der Zee, H. A. (1998). The Hunger Winter: Occupied Holland 1944–1945. Lincoln: University of Nebraska Press.

  2. Stein, Z. (1975). Famine and Human Development: The Dutch Hunger Winter of 1944–1945. New York: Oxford University Press.

  3. Dutch Famine of 1944: http://en.wikipedia.org/wiki/Dutch_famine_of_1944.

  4. The examining physicians diagnosed antisocial personality disorder using the sixth edition of the International Classification of Diseases, and these diagnoses would be very similar to those used today in the Diagnostic and Statistical Manual for Mental Disorders.

  5. Neugebauer, R., Hoek, H. W. & Susser, E. (1999). Prenatal exposure to wartime famine and development of antisocial personality disorder in early adulthood. Journal of the American Medical Association 4, 479–81.

  6. Wong, D. L. & Hess, C. S. (2000). Clinical Manual of Pediatric Nursing. St. Louis: Mosby.

  7. Subotzky, E. F., Heese, H. D., Sive, A. A., Dempster, W. S., Sacks, R., et al. (1992). Plasma zinc, copper, selenium, ferritin and whole blood manganese concentrations in children with kwashiorkor in the acute stage and during refeeding. Annals of Tropical Paediatrics 12, 13–22.

  8. Friedman, M. & Orraca-Tetteh, R. (1978). Hair as an index of protein malnutrition. Advances in Experimental Medicine and Biology 105, 131–54.

  9. Spencer, L. V. & Callen, J. P. (1987). Hair loss in systemic disease. Dermatologic Clinics 5, 565–70.

  10. Liu, J. H., Raine, A., Venables, P. H. & Mednick, S. A. (2004). Malnutrition at age 3 years and externalizing behavior problems at ages 8, 11 and 17 years. American Journal of Psychiatry 161, 2005–13.

  11. Shankar, N., Tandon, O. P., Bandhu, R., Madan, N. & Gomber, S. (2000). Brainstem auditory evoked potential responses in iron-deficient anemic children. Indian Journal of Physiology and Pharmacology 44, 297–303.

  12. Los Monteros, A. E., Korsak, R. A., Tran, T., Vu, D., de Vellis, J., et al. (2000). Dietary iron and the integrity of the developing rat brain: A study with the artificially-reared rat pup. Cellular and Molecular Biology 46, 501–15.

  13. Bruner, A. B., Joffe, A., Duggan, A. K., Casella, J. F. & Brandt, J. (1996). Randomised study of cognitive effects of iron supplementation in non-anaemic iron-deficient adolescent girls. Lancet 348, 992–96; van Stuijvenberg, M. E., Kvalsvig, J. D., Faber, M., Kruger, M., Kenoyer, D. G., et al. (1999). Effect of iron-, iodine-, and beta-carotene-fortified biscuits on the micronutrient status of primary school children: A randomized controlled trial. American Journal of Clinical Nutrition 69, 497–503.

  14. Fishman, S. M., Christian, P. & West, K. P. (2000). The role of vitamins in the prevention and control of anaemia. Public Health Nutrition 3, 125–50.

  15. Liu, J., Raine, A., Venables, P. H., Dalais, C. & Mednick, S. A. (2003). Malnutrition at age 3 years and lower cognitive ability at age 11: Independence from social adversity. Archives of Pediatric and Adolescent Medicine 157, 593–600.

  16. LaFree, G. (1999). A summary and review of cross-national comparative studies of homicide. In M. D. Smith & M. A. Zahn (eds.), Homicide: A Sourcebook of Social Research, pp. 125–45. Thousand Oaks, Calif.: Sage Publications.

  17. Hibbeln, J. R. (2001). Homicide mortality rates and seafood consumption: A cross-national analysis. World Review of Nutrition and Dietetics 88, 41–46. Due to space limitations the figure in the text provides data from twenty-one of the twenty-six countries that Hibbeln reported on, but it retains outliers to appropriately represent the relationship that Hibbeln documented.

  18. Hibbeln, J. R., Davis, J. M., Steer, C., Emmett, P., Rogers, I., et al. (2007). Maternal seafood consumption in pregnancy and neurodevelopmental outcomes in childhood (ALSPAC study): An observational cohort study. Lancet 369, 578–85.

  19. Iribarren, C., Markovitz, J. H., Jacobs, D. R., Schreiner, P. J., Daviglus, M., et al. (2004). Dietary intake of n-3, n-6 fatty acids and fish: Relationship with hostility in young adults—the CARDIA study. European Journal of Clinical Nutrition 58, 24–31.
r />   20. Stevens, L. J., Zentall, S. S., Abate, M. L., Kuczek, T. & Burgess, J. R. (1996). Omega-3 fatty acids in boys with behavior, learning, and health problems. Physiology and Behavior 59, 915–20.

  21. Buydens-Branchey, L., Branchey, M., McMakin, D. L. & Hibbeln, J. R. (2003). Polyunsaturated fatty acid status and aggression in cocaine addicts. Drug and Alcohol Dependence 71, 319–23.

  22. Re, S., Zanoletti, M. & Emanuele, E. (2007). Aggressive dogs are characterized by low omega-3 polyunsaturated fatty acid status. Veterinary Research Communications 32, 225–30.

  23. McNamara, R. K. & Carlson, S. E. (2006). Role of omega-3 fatty acids in brain development and function: Potential implications for the pathogenesis and prevention of psychopathology. Prostaglandins, Leukotrienes and Essential Fatty Acids 75, 329–49.

  24. Kitajka, K., Sinclair, A. J., Weisinger, R. S., Weisinger, H. S., Mathai, M., et al. (2004). Effects of dietary omega-3 polyunsaturated fatty acids on brain gene expression. Proceedings of the National Academy of Sciences of the United States of America 101 (10) 931–36.

  25. Das, U. N. (2003). Long-chain polyunsaturated fatty acids in the growth and development of the brain and memory. Nutrition 19, 62–65.

  26. Stevens, L., Zhang, W., Peck, L., Kuczek, T., Grevstad, N., et al. (2003). EFA supplementation in children with inattention, hyperactivity, and other disruptive behaviors. Lipids 38, 1007–21.

  27. Health Statistics: Obesity. http://www.nationmaster.com/graph/hea_obe-health-obesity.

  28. Protein deficiency is more of a problem in developing countries, but even in developed countries protein deficiency can be an issue in poor areas. Protein provides essential amino acids for the rapid growth of fetal tissue and plays an important role in the antioxidant system.

  29. World Health Organization (2001). Iron deficiency anaemia: Assessment, prevention and control. A Guide for Program Managers. Geneva: World Health Organization (WHO).

  30. Takeda, A., Tamano, H., Kan, F., Hanajima, T., Yamada, K., et al. (2008). Enhancement of social isolation-induced aggressive behavior of young mice by zinc deficiency. Life Sciences 82, 909–14.

  31. Halas, E. S., Reynolds, G. M. & Sandstead, H. H. (1977). Intra-uterine nutrition and its effects on aggression. Physiology & Behavior 19, 653–61.

  32. Walsh, W. J., Isaacson, R., Rehman, F. & Hall, A. (1997). Elevated blood copper/zinc ratios in assaultive young males. Physiology & Behavior 62, 327–29. In this study zinc levels were low and copper levels were high. Copper is elevated because when zinc is low, there is more bioavailability for copper.

  33. Tokdemir, M., Plota, S. A., Acik, Y., Gursu, F. & Cikim, G. (2003). Blood zinc and copper concentration in criminal and noncriminal schizophrenic men. Archives of Andrology 49, 365–68.

  34. Werbach, M. R. (1992). Nutritional influences on aggressive behavior. Journal of Orthomolecular Medicine 7, 45–51.

  35. Rosen, G. M., Deinard, A. S., Schwartz, S., Smith, C., Stephenson, B., et al. (1985): Iron deficiency among incarcerated juvenile delinquents. Journal of Adolescent Health Care 6, 419–23.

  36. Lozoff, B., Clark, K. M., Jing, Y., Armony-Sivan, R. & Jacobsen, S. W. (2008). Dose-response relationships between iron deficiency with or without anemia and infant social-emotional behavior. Journal of Pediatrics 152, 696–702.

  37. McBurnett, K., Raine, A., Stouthamer-Loeber, M., Loeber, R., Kumar, A. M., et al. (2005). Mood and hormone responses to psychological challenge in adolescent males with conduct problems. Biological Psychiatry 57, 1109–16.

  38. Bennis-Taleb, N., Remacle, C., Hoet, J. J. & Reusens, B. (1999). A low-protein isocaloric diet during gestation affects brain development and alters permanently cerebral cortex blood vessels in rat offspring. Journal of Nutrition 129, 1613–19.

  39. Takeda, A. (2000). Movement of zinc and its functional significance in the brain. Brain Research Reviews 34, 137–48.

  40. Newman, J. P. & Kosson, D. S. (1986). Passive avoidance learning in psychopathic and non-psychopathic offenders. Journal of Abnormal Psychology 95, 252–56.

  41. Pfeiffer, C. C. & Braverman, E. R. (1982). Zinc, the brain and behavior. Biological Psychiatry 17, 513–32.

  42. Arnold, L. E., Pinkham, S. M. & Votolato, N. (2000). Does zinc moderate essential fatty acid and amphetamine treatment of attention-deficit/hyperactivity disorder? Journal of Child and Adolescent Psychopharmacology 10, 111–17.

  43. King, J. C. (2000). Determinants of maternal zinc status during pregnancy. American Journal of Clinical Nutrition 71, 1334–43.

  44. Shea-Moore, M. M., Thomas, O. P. & Mench, J. A. (1996). Decreases in aggression in tryptophan-supplemented broiler breeder males are not due to increases in blood niacin levels. Poultry Science 75, 370–74.

  45. In many laboratories the 100-gram drink that depletes tryptophan contains a mix of fifteen amino acids, none of which are tryptophan. This increases protein synthesis in the liver, which reduces tryptophan in the plasma. In addition, these amino acids compete with tryptophan for transportation across the blood-brain barrier. Essentially, what tryptophan the participants have available to them is swamped out by the other amino acids. The placebo drink is exactly the same except that the drink is balanced with the appropriate amount of tryptophan.

  46. Bond, A. J., Wingrove, J. & Critchlow, D. G. (2001). Tryptophan depletion increases aggression in women during the premenstrual phase. Psychopharmacology 156, 477–80; Bjork, J. M., Dougherty, D. M., Moeller, F. G., Cherek, D. R. & Swann, A. C. (1999). The effects of tryptophan depletion and loading on laboratory aggression in men: Time course and a food-restricted control. Psychopharmacology 142, 24–30.

  47. Cherek, D. R., Lane, S. D., Pietras, C. J. & Steinberg, J. L. (2002). Effects of chronic paroxetine administration on measures of aggressive and impulsive responses of adult males with a history of conduct disorder. Psychopharmacologia 159, 266–74.

  48. Rubia, K., Lee, F., Cleare, A. J., Tunstall, N., Fu, C.H.Y., et al. (2005). Tryptophan depletion reduces right inferior prefrontal activation during response inhibition in fast, event-related fMRI. Psychopharmacology 179, 791–803.

  49. Ledbetter, L. (1979). San Francisco Tense as Violence Follows Murder Trial. New York Times, May 23, A1, A18.

  50. White Night Riots: http://en.wikipedia.org/wiki/White_Night_Riots.

  51. Turner, W. (1979). Ex-official guilty of manslaughter in slayings on coast; 3,000 protest. New York Times, May 22, A1, D17.

  52. White Night Riots: http://en.wikipedia.org/wiki/White_Night_Riots.

  53. Schoenthaler, S. J. (1982). The effect of sugar on the treatment and control of anti-social behavior: A double-blind study of an incarcerated juvenile population. International Journal of Biosocial Research 3, 1–9.

  54. Venables, P. H. & Raine, A. (1987). Biological theory. In B. McGurk, D. Thornton & M. Williams (eds.), Applying Psychology to Imprisonment: Theory and Practice, pp. 3–28. London: HMSO.

  55. Pelto, P. (1967). Psychological anthropology. In A. Beals & B. Stegel (eds.), Biennial Review of Anthropology, pp. 151–55. Stanford, Calif.: Stanford University Press.

  56. Bolton, R. (1973). Aggression and hypoglycemia among the Quolla: A study in psycho-biological anthropology. Ethology 12, 227–57.

  57. Bolton, R. (1979). Hostility in fantasy: A further test of the hypoglycaemia-aggression hypothesis. Aggressive Behavior 2, 257–74.

  58. For a review of these studies, see Venables & Raine, Biological theory.

  59. Virkkunen, M., Rissanen, A., Naukkarinen, H., Franssila-Kallunki, A., Linnoila, M., et al. (2007). Energy substrate metabolism among habitually violent alcoholic offenders having antisocial personality disorder. Psychiatry Research 150, 287–95.

  60. Virkkunen, M., Rissanen, A., Franssila-Kallunki, A. & Tiihonen, J. (2009). Low non-oxidative glucose metabolism and violent offending: An 8-year prospective follow-up study. Psychiatry Research 168, 26–31.

  61. McCrimmon, R. J., Ewing, F.M.E., Frier, B. M. & Deary, I. J. (1999). Anger state during acute insulin-induced hypoglycaemi
a. Physiology and Behavior 67, 35–39.

  62. Moore, S. C., Carter, L. M. & van Goozen, S.H.M. (2009). Confectionery consumption in childhood and adult violence. British Journal of Psychiatry 195, 366–67.

  63. Stewart, W. F., Schwartz, B. S., Davatzikos, C., et al. (2006). Past adult lead exposure is linked to neurodegeneration measured by brain MRI. Neurology 66, 1476–84.

  64. CDC safety level values for bone and lead levels are somewhat different. In this case we are dealing with bone lead, and CDC safety levels for bone are defined as <15. Consequently, the average person in this study was at the very top of that safety level. Put another way, about half of the sample exceeded CDC-defined safe bone-lead levels.

  65. Other affected structures included the cingulate and insula. Within the frontal lobe, the middle frontal gyrus was the area most reduced in volume.

  66. Cecil, K. M., Brubaker, C. J., Adler, C. M., Dietrich, K. N., Altaye, M., et al. (2008). Decreased brain volume in adults with childhood lead exposure. PLOS Medicine 5, 741–50.

  67. One caveat is that this sample was 90 percent African-American and these prospective brain-imaging findings could be usefully replicated on a Caucasian sample. One would expect the same findings in other ethnic groups, although it is conceivable that poorer neighborhood conditions could result in greater exposure to lead in this community sample, and possibly stronger brain-lead relationships. The ethnicity of the sample of lead workers was not reported in Cecil et al. (2008).

  68. For a detailed review see Needleman, H. L., Riess, J. A., Tobin, M. J., Biesecker, G. E. & Greenhouse, J. B. (1996). Bone lead levels and delinquent behavior. Journal of the American Medical Association 275, 363–69.

  69. Delville, Y. (1999). Exposure to lead during development alters aggressive behavior in golden hamsters. Neurotoxicology and Teratology 21, 445–49.

 

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