Биология добра и зла. Как наука объясняет наши поступки

248

E. Mikics et al., “Genomic and Non-genomic Effects of Glucocorticoids on Aggressive Behavior in Male Rats,” PNE 29 (2004): 618; D. Hayden-Hixson and C. Ferris, “Steroid-Specific Regulation of Agonistic Responding in the Anterior Hypothalamus of Male Hamsters,” Physiology & Behav 50 (1991): 793; A. Poole and P. Brain, “Effects of Adrenalectomy and Treatments with ACTH and Glucocorticoids on Isolation-Induced Aggressive Behavior in Male Albino Mice,” Prog Brain Res 41 (1974): 465; E. Mikics et al., “The Effect of Glucocorticoids on Aggressiveness in Established Colonies of Rats,” PNE 32 (2007): 160; R. Böhnke et al., “Exogenous Cortisol Enhances Aggressive Behavior in Females, but Not in Males,” PNE 35 (2010): 1034; K. Bertsch et al., “Exogenous Cortisol Facilitates Responses to Social Threat Under High Provocation,” Horm Behav 59 (2011): 428.

249

S. Levine et al., “The PNE of Stress: A Psychobiological Perspective,” in Psychoneuroendocrinology, ed. S. Levine and R. Brush (New York: Academic Press, 1988), p. 181; R. Sapolsky and J. Ray, “Styles of Dominance and Their Physiological Correlates Among Wild Baboons,” Am J Primat l8 (1989): l; J. C. Ray and R. Sapolsky, “Styles of Male Social Behavior and Their Endocrine Correlates Among High-Ranking Baboons,” Am J Primat 28 (1992): 231; C. E. Virgin and R. Sapolsky, “Styles of Male Social Behavior and Their Endocrine Correlates Among Low-Ranking Baboons,” Am J Primat 42 (1997): 25.

250

D. Card and G. Dahl, “Family Violence and Football: The Effect of Unexpected Emotional Cues on Violent Behavior,” Quarterly J Economics 126 (2011): 103.

251

К сноске: пример исследования, показывающего с точки зрения нейробиологии, что в стрессовом состоянии труднее поддерживать привычки здорового образа жизни: C. Cifani et al., “Medial Prefrontal Cortex Neuronal Activation and Synaptic Alterations After Stress-Induced Reinstatement of Palatable Food Seeking: A Study Using c-fos-GFP Transgenic Female Rats,” J Nsci 32 (2012): 8480.

252

K. Starcke et al., “Does Everyday Stress Alter Moral Decision-Making?” PNE 36 (2011): 210; F. Youssef et al., “Stress Alters Personal Moral Decision Making,” PNE 37 (2012): 491.

253

D. Langford et al., “Social Modulation of Pain as Evidence for Empathy in Mice,” Sci 312 (2006): 1967.

254

S. Taylor et al., “Biobehavioral Responses to Stress in Females: Tend-and-Befriend, Not Fight-or-Flight,” Psych Rev 107 (2000): 411.

255

B. Bushman, “Human Aggression While Under the Influence of Alcohol and Other Drugs: An Integrative Research Review,” Curr Dir Psych Sci 2 (1993): 148; L. Zhang et al., “The Nexus Between Alcohol and Violent Crime,” Alcoholism: Clin and Exp Res 21 (1997): 1264; K. Graham and P. West, “Alcohol and Crime: Examining the linke,” in International Handbook of Alcohol Dependence and Problems, ed. N. Heather, T. J. Peters, and T. Stockwell (New York: John Wiley & Sons, 2001); I. Quadros et al., “Individual Vulnerability to Escalated Aggressive Behavior by a Low Dose of Alcohol: Decreased Serotonin Receptor mRNA in the Prefrontal Cortex of Male Mice,” Genes, Brain and Behav 9 (2010): 110; A. Johansson et al., “Alcohol and Aggressive Behavior in Men: Moderating Effects of Oxytocin Receptor Gene (OXTR) Polymorphisms,” Genes, Brain and Behav 11 (2012): 214.

256

D. O. Hebb, The Organization of Behaviour (Hoboken, NJ: John Wiley & Sons, 1949).

257

Общий обзор: R. Nicoll and K. Roche, “Long-Term Potentiation: Peeling the Onion,” Neuropharmacology 74 (2013): 18; J. MacDonald et al., “Hippocampal Long-Term Synaptic Plasticity and Signal Amplification of NMDA Receptors,” Critical Rev in Neurobiol 18 (2006): 71.

258

T. Sigurdsson et al., “Long-Term Potentiation in the Amygdala: A Cellular Mechanism of Fear Learning and Memory,” Neuropharmacology 52 (2007): 215; J. Kim and M. Jung, “Neural Circuits and Mechanisms Involved in Pavlovian Fear Conditioning: A Critical Review,” Nsci Biobehav Rev 30 (2006): 188; M. Wolf, “LTP May Trigger Addiction,” Mol Interventions 3 (2003): 248; M. Wolf et al., “Psychomotor Stimulants and Neuronal Plasticity,” Neuropharmacology 47, supp. 1 (2004): 61.

259

M. Foy et al., “17beta-estradiol Enhances NMDA Receptor-Mediated EPSPs and Long-Term Potentiation,” J Neurophysiology 81 (1999): 925; Y. Lin et al., “Oxytocin Promotes Long-Term Potentiation by Enhancing Epidermal Growth Factor Receptor-Mediated Local Translation of Protein Kinase Mζ,” J Nsci 32 (2012): 15476; K. Tomizawa et al., “Oxytocin Improves Long-Lasting Spatial Memory During Motherhood Through MAP Kinase Cascade,” Nat Nsci 6 (2003): 384; V. Skucas et al., “Testosterone Depletion in Adult Male Rats Increases Mossy Fiber Transmission, LTP, and Sprouting in Area CA3 of Hippocampus,” J Nsci 33 (2013): 2338; W. Timmermans et al., “Stress and Excitatory Synapses: From Health to Disease,” Nsci 248 (2013): 626.

260

S. Rodrigues et al., “The Influence of Stress Hormones on Fear Circuitry,” Ann Rev Nsci 32 (2009): 289; X. Xu and Z. Zhang, “Effects of Estradiol Benzoate on Learning-Memory Behavior and Synaptic Structure in Ovariectomized Mice,” Life Sci 79 (2006): 1553; C. Rocher et al., “Acute Stress-Induced Changes in Hippocampal/Prefrontal Circuits in Rats: Effects of Antidepressants,” Cerebral Cortex 14 (2004): 224.

261

A. Holtmaat and K. Svoboda, “Experience-Dependent Structural Synaptic Plasticity in the Mammalian Brain,” Nat Rev Nsci 10 (2009): 647; C. Woolley et al., “Naturally Occurring Fluctuation in Dendritic Spine Density on Adult Hippocampal Pyramidal Neurons,” J Nsci 10 (1990): 4035; W. Kelsch et al., “Watching Synaptogenesis in the Adult Brain,” Ann Rev of Nsci 33 (2010): 131.

262

B. Leuner and T. Shors, “Stress, Anxiety, and Dendritic Spines: What Are the Connections?” Nsci 251 (2013): 108; Y. Chen et al., “Correlated Memory Defects and Hippocampal Dendritic Spine Loss After Acute Stress Involve Corticotropin-Releasing Hormone Signaling,” PNAS 107 (2010): 13123.

263

J. Cerqueira et al., “Morphological Correlates of Corticosteroid-Induced Changes in Prefrontal Cortex