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Polyvagal theory, neurodevelopment and psychiatric disorders

Published online by Cambridge University Press:  06 December 2017

M. O. Huttunen*
Affiliation:
Department of Mental Health and Alcohol Research, National Institute for Health and Welfare, Helsinki, Finland
S. A. Mednick
Affiliation:
Cheltenham Road, Toledo, OH, USA
*
*Address for correspondence: M. O. Huttunen, MD, PhD, Department of Mental Health and Alcohol Research, National Institute for Health and Welfare, Helsinki, Finland. (Email: matti.huttunen@konsmoh.inet.fi)
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Abstract

Neurodevelopment is an area of psychiatry which has attracted huge interest in the last few decades. There is substantial evidence that perinatal events can contribute to later development of mental disorder. In the current perspective article we propose a novel polyvagal theory which attempts to link prenatal events with neurodevelopment and the later onset of psychiatric disorder.

Type
Editorials
Copyright
© College of Psychiatrists of Ireland 2017 

Prenatal infections and stress have been shown to increase the incidence of schizophrenia, affective disorders and autism (Huttunen & Niskanen, Reference Huttunen and Niskanen1978; Mednick et al. Reference Mednick, Machón, Huttunen and Bonnet1988; Machón et al. Reference Machón, Mednick and Huttunen1997; Cannon et al. Reference Cannon, Clarke and Cotter2014). All of these disorders are known be associated with impairments in social relations. We would like to propose a novel mechanism linking the prenatal response to stress and inflammation with the later development of psychiatric disorder.

According to the polyvagal theory (Porges, Reference Porges2007) the autonomic system consists of three parts – the phylogenetically oldest dorsal parasympathetic or vagal system, the sympathetic system and phylogenetically newest ventral vagal system. These three parts of the autonomic nervous system of mammals play different roles in the evolutionary stress responses in mammals. The myelinated neurons of the ventral vagal system function as a ‘brake’ for the ‘fight-flight’ activity of sympathetic nervous system. The unmyelinated dorsal vagal activity takes control if the ‘fight/flight’ behavior fails to protect the individual, resulting in defensive immobilization – the ‘freeze’ response.

The efferent pathways of the ventral vagal neurons in the nucleus ambiguus (situated in the medullary reticular formation) are known to innervate muscles of the face, eyelids, larynx, pharynx and middle ear. These regions regulate facial expression, vocal prosody and listening, all of which promote social engagement. Functionally, the ventral vagal system lowers the heart rate, dampens the hypothalamic–pituitary axis, promotes self-soothing behaviors and thus enables the individual to engage with other individuals (Mednick et al. Reference Mednick, Machón, Huttunen and Bonnet1988). In this way the extent of social engagement is dependent on the vagal brake provided by the efferent neurons of nucleus ambiguus.

Developmentally, the number of myelinated vagal fibers increases from 23 to 28 weeks of gestation until birth, when the number of fibers is comparable to those observed in adolescence (Sachis et al. Reference Sachis, Armstrong, Becker and Bryan1982).

Putting these lines of research together, it is proposed that prenatal infections and stress affect the development of myelinated neurons of the ventral vagal system and, by this mechanism, increase the sensitivity of children for traumatic experiences and their risk for major psychiatric disorder. This theory merits research as it could have significant public health implications, and would highlight the critical importance of ensuring adequate medical and psychosocial supports during the perinatal phase.

Acknowledgments

This perspective piece has been adapted from a previous Finnish publication authored by Professor Matti Huttunen (Respektiä ja rakkautta, ISBN 978-952-5718-76-8). PROMETHEUS kustannus Oy (ltd) have kindly agreed to grant the right to publish this adapted translation of the book. This piece has been published in honor of Sarnoff Mednick, with whom this idea was developed and discussed a few months before his sad death in April 2015.

Conflicts of Interest

M.H. has no conflicts of interest to disclose. S.M. has no conflicts of interest to disclose.

Ethical Standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committee on human experimentation with the Helsinki Declaration of 1975, as revised in 2008.

Financial Supports

This paper received no specific grant from any funding agency, commercial or not-for-profit sectors.

Footnotes

Passed away April, 2015

References

Huttunen, MO, Niskanen, P (1978). Prenatal loss of father and psychiatric disorders. Archives of General Psychiatry 35, 429431.CrossRefGoogle ScholarPubMed
Mednick, SM, Machón, RA, Huttunen, MO, Bonnet, D (1988). Adult schizophrenia following prenatal exposure to an influenza epidemic. Archives of General Psychiatry 45, 189192.Google Scholar
Machón, RA, Mednick, SA, Huttunen, MO (1997). Adult major affective disorder after prenatal exposure to an influenza epidemic. Archives of General Psychiatry 54, 322328.Google Scholar
Cannon, M, Clarke, MC, Cotter, DR (2014). Priming the brain for psychosis: maternal inflammation during fetal development and the risk of later psychiatric disorder. American Journal of Psychiatry 171, 901905.Google Scholar
Porges, SW (2007). The polyvagal perspective. Biological Psychology 74, 118143.Google Scholar
Sachis, PN, Armstrong, DL, Becker, LE, Bryan, AC (1982). Myelination of the human vagus nerve from 24 weeks postconceptual age to adolescence. Neuropathology and Experimental Neurology 41, 466472.Google Scholar