209. The Collected Works of D. W. Winnicott, 183–88. 210. R. Montirosso, F. Arrigoni, E. Casini, A. Nordio, P. De Carli, F. Di Salle, S. Moriconi, M. Re, G. Reni end R. Borgatti, Greater Brain Response to Emotional Expressions of Their Own Children in Mothers of Preterm Infants: An fMRI Study, Journal of Perinatology 37, № 6 (June 2017): 716–22, https://­doi.org/­10.1038/­jp.2017.2. 211. Ellen Leibenluft, M. Ida Gobbini, Tara Harrison and James V. Haxby, Mothers’ Neural Activation in Response to Pictures of Their Children and Other Children, Biological Psychiatry 56, № 4 (August 15, 2004): 225–32, https://­doi.org/­10.1016/­j.biopsych.2004.05.017; Paola Venuti, Andrea Caria, Gianluca Esposito, Nicola De Pisapia, Marc H. Bornstein and Simona de Falco, Differential Brain Responses to Cries of Infants with Autistic Disorder and Typical Development: An fMRI Study, Research in Developmental Disabilities 33, № 6 (November 13, 2012): 2255–64, https://­doi.org/­10.1016/­j.ridd.2012.06.011. 212. Karel O’Brien, Kate Robson, Marianne Bracht, Melinda Cruz, Kei Lui, Ruben Alvaro, Orlando da Silva et al., Effectiveness of Family Integrated Care in Neonatal Intensive Care Units on Infant and Parent Outcomes: A Multicentre, Multinational, Cluster-Randomised Controlled Trial, Lancet: Child & Adolescent Health 2, № 4 (April 2018): 245–54, https://­doi.org/­10.1016/­S2352-4642(18)30039-7. 213. Peter Sterling and Joseph Eyer, Allostasis: A New Paradigm to Explain Arousal Pathology, in Handbook of Life Stress, Cognition and Health, eds. Shirley Fisher and James Reason (New York: John Wiley and Sons, 1988): 629–49; Jay Schulkin and Peter Sterling, Allostasis: A Brain-Centered, Predictive Mode of Physiological Regulation, Trends in Neurosciences 42, № 10 (October 2019): 740–52, https://­doi.org/­10.1016/­j.tins.2019.07.010. 214. Peter Sterling, What Is Health? Allostasis and the Evolution of Human Design (Cambridge, MA: MIT Press, 2020). 215. Peter Sterling, Allostasis: A Model of Predictive Regulation, in Allostasis and Allostatic Load, eds. Bruce McEwen and Achim Peters, special issue, Physiology & Behavior 106, № 1 (April 12, 2012): 5–15, https://­doi.org/­10.1016/­j.physbeh.2011.06.004. 216. Bruce S. McEwen and John C. Wingfield, What Is in a Name? Integrating Homeostasis, Allostasis and Stress, Hormones and Behavior 57, № 2 (February 2010): 105–11, https://­doi.org/­10.1016/­j.yhbeh.2009.09.011. 217. Bruce S. McEwen and John C. Wingfield, The Concept of Allostasis in Biology and Biomedicine, Hormones and Behavior 43, № 1 (January 2003): 2–15, https://­doi.org/­10.1016/­s0018-506x(02)00024-7. 218. Sterling, Allostasis: A Model of Predictive Regulation, https://­doi.org/­10.1016/­j.physbeh.2011.06.004. 219. Feldman Barrett, Seven and a Half Lessons, 8–10. 220. Lisa Feldman Barrett and W. Kyle Simmons, Interoceptive Predictions in the Brain, Nature Reviews Neuroscience 16, № 7 (July 2015): 419–29, https://­doi.org/­10.1038/­nrn3950; Karen S. Quigley, Scott Kanoski, Warren M. Grill, Lisa Feldman Barrett and Manos Tsakiris, Functions of Interoception: From Energy Regulation to Experience of the Self, in The Neuroscience of Interoception, special issue, Trends in Neurosciences 44, № 1 (January 1, 2021): 29–38, https://­doi.org/­10.1016/­j.tins.2020.09.008. 221. A. D. Craig, How Do You Feel? Interoception: The Sense of the Physiological Condition of the Body, Nature Reviews Neuroscience 3, № 8 (August 2002): 655–66, https://­doi.org/­10.1038/­nrn894. 222. Ian R. Kleckner, Jiahe Zhang, Alexandra Touroutoglou, Lorena Chanes, Chenjie Xia, W. Kyle Simmons, Karen S. Quigley, Bradford C. Dickerson and Lisa Feldman Barrett, Evidence for a Large-Scale Brain System Supporting Allostasis and Interoception in Humans, Nature Human Behaviour 1, № 5 (April 24, 2017): 1–14, https://­doi.org/­10.1038/­s41562-017-0069. 223. Debra A. Gusnard, Erbil Akbudak, Gordon L. Shulman and Marcus E. Raichle, Medial Prefrontal Cortex and Self-Referential Mental Activity: Relation to a Default Mode of Brain Function, Proceedings of the National Academy of Sciences 98, № 7 (March 27, 2001): 4259–64, https://­doi.org/­10.1073/­pnas.071043098; Randy L. Buckner, Jessica R. Andrews-Hanna and Daniel L. Schacter, The Brain’s Default Network: Anatomy, Function, and Relevance to Disease, Annals of the New York Academy of Sciences 1124, № 1 (March 2008): 1–38, https://­doi.org/­10.1196/­annals.1440.011. 224. Точные анатомические параметры сети пассивного режима работы головного мозга, к сожалению, еще не выявлены, однако ее роль в качестве масштабной системы, важной для осуществления социальной функции, понятна в большей степени. Подробнее об этом: Felicity Callard and Daniel S. Margulies, What We Talk about When We Talk about the Default Mode Network, Frontiers in Human Neuroscience 8 (August 25, 2014), https://­doi.org/­10.3389/­fnhum.2014.00619; Chunliang Feng, Simon B. Eickhoff, Ting Li, Li Wang, Benjamin Becker, Julia A. Camilleri, Sébastien Hétu and Yi Luo, Common Brain Networks Underlying Human Social Interactions: Evidence from Large-Scale Neuroimaging Meta-Analysis, Neuroscience & Biobehavioral Reviews 126 (July 2021): 289–303, https://­doi.org/­10.1016/­j.neubiorev.2021.03.025. 225. Michael D. Greicius, Ben Krasnow, Allan L. Reiss and Vinod Menon, Functional Connectivity in the Resting Brain: A Network Analysis of the Default Mode Hypothesis, Proceedings of the National Academy of Sciences 100, № 1 (January 7, 2003): 253–58, https://­doi.org/­10.1073/­pnas.0135058100; Buckner, Andrews-Hanna and Schacter, Brain’s Default Network, https://­doi.org/­10.1196/­annals.1440.011. 226. Buckner, Andrews-Hanna and Schacter, Brain’s Default Network, https://­doi.org/­10.1196/­annals.1440.011. 227. Jin-Xia Zheng, Lili Ge, Huiyou Chen, Xindao Yin, Yu-Chen Chen and Wei-Wei Tang, Disruption within Brain Default Mode Network in Postpartum Women without Depression, Medicine 99, № 18 (May 2020), https://­doi.org/­10.1097/­MD.0000000000020045; Alison E. Hipwell, Chaohui Guo, Mary L. Phillips, James E. Swain and Eydie L. Moses-Kolko, Right Frontoinsular Cortex and Subcortical Activity to Infant Cry Is Associated with Maternal Mental State Talk, Journal of Neuroscience 35, № 37 (September 16, 2015): 12725–32, https://­doi.org/­10.1523/­JNEUROSCI.1286-15.2015; Paola Rigo, Gianluca Esposito, Marc H. Bornstein, Nicola De Pasapia, Corinna Manzardo and Paola Venuti, Brain Processes in Mothers and Nulliparous Women in Response to Cry in Different Situational Contexts: A Default Mode Network Study, Parenting 19, № 1–2 (February 1, 2019): 69–85, https://­doi.org/­10.1080/­15295192.2019.1555430. 228. Amanda J. Nguyen, Elisabeth Hoyer, Purva Rajhans, Lane Strathearn and Sohye Kim, A Tumultuous Transition to Motherhood: Altered Brain and Hormonal Responses in Mothers with Postpartum Depression, in Papers from the Parental Brain 2018 Meeting, Toronto, Canada, July 2018, eds. Jodi L. Pawluski, Frances A. Champagne and Oliver J. Bosch, special issue, Journal of Neuroendocrinology 31, № 9 (September 2019): e12794, https://­doi.org/­10.1111/­jne.12794; Henry W. Chase, Eydie L. Moses-Kolko, Carlos Zevallos, Katherine L. Wisner and Mary L. Phillips, Disrupted Posterior Cingulate-Amygdala Connectivity in Postpartum Depressed Women as Measured with Resting BOLD fMRI, Social Cognitive and Affective Neuroscience 9, № 8 (August 2014): 1069–75, https://­doi.org/­10.1093/­scan/­nst083. 229. Hoekzema et al., Pregnancy Leads to Long-Lasting Changes, https://­doi.org/­10.1038/­nn.4458, 287–96; Magdalena Martínez-García, María Paternina-Die, Erika Barba-Müller, Daniel Martín de Blas, Laura Beumala, Romina Cortizo, Cristina Pozzobon et al., Do Pregnancy-Induced Brain Changes Reverse? The Brain of a Mother Six Years after Parturition, Brain Sciences 11, № 2 (January 28, 2021), https://­doi.org/­10.3390/­brainsci11020168. 230. Eyal Abraham and Ruth Feldman, The Neurobiology of Human Allomaternal Care; Implications for Fathering, Coparenting, and Children’s Social Development, in Evolutionary Perspectives on Non-Maternal Care in Mammals: Physiology, Behavior, and Developmental Effects, eds. Stacy Rosenbaum and Lee T. Gettler, special issue, Physiology & Behavior 193, part A (September 1, 2018): 25–34, https://­doi.org/­10.1016/­j.physbeh.2017.12.034. 231. Jennifer S. Mascaro, Patrick D. Hackett and James K. Rilling, Differential Neural Responses to Child and Sexual Stimuli in Human Fathers and Non-Fathers and Their Hormonal Correlates, Psychoneuroendocrinology 46 (August 2014): 153–63, https://­doi.org/­10.1016/­j.psyneuen.2014.04.014. 232. Disha Sasan, Phillip G. D. Ward, Meredith Nash, Edwina R. Orchard, Michael J. Farrell, Jakob Hohwy and Sharna D. Jamadar, “Phantom Kicks”: Women’s Subjective Experience of Fetal Kicks after the Postpartum Period, Journal of Women’s Health 30, № 1 (January 2021): 36–44, https://­doi.org/­10.1089/­jwh.2019.8191. 233. Kiarash Khosrotehrani, Kirby L. Johnson, Joseph Lau, Alain Dupuy, Dong Hyun Cha and Diana W. Bianchi, The Influence of Fetal Loss on the Presence of Fetal Cell Microchimerism: A Systematic Review, Arthritis & Rheumatology 48, № 11 (November 2003): 3237–41, https://­doi.org/­10.1002/­art.11324; Amy M. Boddy, Angelo Fortunato, Melissa Wilson Sayres and Athena Aktipis, Fetal Microchimerism and Maternal Health: A Review and Evolutionary Analysis of Cooperation and Conflict beyond the Womb, BioEssays 37, № 10 (October 2015): 1106–18, https://­doi.org/­10.1002/­bies.201500059. 234. Diane Goldenberg, Narcis Marshall, Sofia Cardenas and Darby Saxbe, The Development of the Social Brain within a Family Context, in The Social Brain: A Developmental Perspective, ed. Jean Decety (Cambridge, MA: MIT Press, 2020): 107–24. 235. Shir Atzil, Wei Gao, Isaac Fradkin and Lisa Feldman Barrett, Growing a Social Brain, Nature Human Behaviour 2, № 9 (September 2018): 624–36, https://­doi.org/­10.1038/­s41562-018-0384-6. 236. Michael Numan and Larry J. Young, Neural Mechanisms of Mother-Infant Bonding and Pair Bonding: Similarities, Differences, and Broader Implications, in Parental Care, eds. Alison S. Fleming, Frederic Lévy and Joe S. Lonstein, special issue, Hormones and Behavior 77 (January 2016): 98–112, https://­doi.org/­10.1016/­j.yhbeh.2015.05.015. 237. Ruth Feldman, Bio-Behavioral Synchrony: A Model for Integrating Biological and Microsocial Behavioral Processes in the Study of Parenting, Parenting 12, № 2–3 (June 14, 2012): 154–64, https://­doi.org/­10.1080/­15295192.2012.683342. 238. Ortal Shimon-Raz, Roy Salomon, Miki Bloch, Gabi Aisenberg Romano, Yaara Yeshurun, Adi Ulmer Yaniv, Orna Zagoory-Sharon and Ruth Feldman, Mother Brain Is Wired for Social Moments, eLife 10 (2021), e59436, https://­doi.org/­10.7554/­eLife.59436. 239. Ruth Feldman, The Neurobiology of Human Attachments, Trends in Cognitive Sciences 21, № 2 (February 2017): 80–99, https://­doi.org/­10.1016/­j.tics.2016.11.007. 240. Ruth Feldman, The Adaptive Human Parental Brain: Implications for Children’s Social Development, Trends in Neurosciences 38, № 6 (June 2015): 387–99, https://­doi.org/­10.1016/­j.tins.2015.04.004. 241. Atzil et al., Growing a Social Brain, https://­doi.org/­10.1038/­s41562-018-0384-6. 242. Shir Atzil, Alexandra Touroutoglou, Tali Rudy, Stephanie Salcedo, Ruth Feldman, Jacob M. Hooker, Bradford C. Dickerson, Ciprian Catana and Lisa Feldman Barrett, Dopamine in the Medial Amygdala Network Mediates Human Bonding, Proceedings of the National Academy of Sciences 114, № 9 (February 28, 2017): 2361–66, https://­doi.org/­10.1073/­pnas.1612233114. 243. Daniel S. Quintana, Jaroslav Rokicki, Dennis van der Meer, Dag Alnæs, Tobias Kaufmann, Aldo Córdova-Palomera, Ingrid Dieset, Ole A. Andreassen and Lars T. Westlye, Oxytocin Pathway Gene Networks in the Human Brain, Nature Communications 10, № 1 (February 8, 2019): 668, https://­doi.org/­10.1038/­s41467-019-08503-8; Benjamin Jurek and Inga D. Neumann, The Oxytocin Receptor: From Intracellular Signaling to Behavior, Physiological Reviews 98, № 3 (July 2018): 1805–908, https://­doi.org/­10.1152/­physrev.00031.2017; M. L. Boccia, P. Petrusz, K. Suzuki, L. Marson and C. A. Pedersen, Immunohistochemical Localization of Oxytocin Receptors in Human Brain, Neuroscience 253 (December 3, 2013): 155–64, https://­doi.org/­10.1016/­j.neuroscience.2013.08.048.