Abstract
Considering the wide variety of behaviors in which the midbrain PAG is involved and the lack of clearly defined cytoarchitectural organization (Beitz, 1985), it is not surprising to note the lack of a clear understanding of its unified function, if such exists. Various functions ascribed to the PAG include defense reactions (Bandler and Carrive, 1988; Bandler and Depaulis, this volume), anti-nociception (Amit and Galina, 1986; Hosobuchi, 1981; Besson et al., this volume), reproductive behaviors (Ogawa et al., this volume) and vocalization (Jürgens and Pratt, 1979; Larson and Kistler, 1984; 1986; Jürgens, this volume). It is also possible that the PAG may be involved in the integration of various components of complex behaviors into functional entities.
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References
Adametz, J. and O’Leary, J.L., Experimental mutism resulting from periaqueductal lesions in cats, Neurol., 9 (1959) 636–642.
Amit, Z. and Galina, Z. H., Stress-induced analgesia: Adaptive pain suppression, Physiol.Rev., 66 (1986) 1091–1120.
Bandler, R. and Carrive, P., Integrated defence reaction elicited by excitatory amino acid microinjection in the midbrain periaqueductal grey region of the unrestrained cat, Brain Res., 439 (1988) 95–106.
Beitz, A. J., The Organization of Afferent Projections to the Midbrain Periaqueductal Gray of the Rat., Neuroscience, 7 (1982) 133–159.
Beitz, A. J., The Midbrain Periaqueductal Gray in the Rat. I. Nuclear Volume, Cell Number, Density, Orientation, and Regional Subdivisions, J. Comp. Neurol., 237 (1985) 445–459.
Beitz, A.J. and Shepard, R.D., The midbrain periaqueductal gray in the rat. II. A Golgi analysis, J. Comp. Neurol., 237 (1985) 460–475.
DeRosier, E.A., Ortega, J.D., Park, S. and Larson, C.R., Effects of PAG stimulation on laryngeal EMG and vocalization in the awake monkey, Neurosci Abst., 17 (1987) 855.
Fetz, E.E. and Cheney, P.D., Postspike facilitation of forelimb muscle activity by primate corticomotoneuronal cells, J. Neurophysiol., 44 (1980) 751–772.
Gioia, M., Bianchi R. and Tredici, G., Cytoarchitecture of the periaqueductal gray matter in the cat: A quantitative nissl study, Acta anat., 119 (1984) 113–117.
Grimm, R. J., Catalogue of Sounds of the Pigtailed Macaque (Macaca nemestrina), J. Zool. Lond., 152 (1967) 361–373.
Hardy, S.G.P. and Leichnetz, G.R., Cortical projections to the periaqueductal gray in the monkey: A retrograde and orthograde horseradish peroxidase study, Neurosci. Lett., 22 (1981) 97–101.
Hirano, M., Vennard, W. and Ohala, J., Regulation of register, pitch and intensity of voice, Folia phoniat., 22 (1970) 1–20.
Hixon, T. J., Respiratory function in speech, In: Normal Aspects of Speech, Hearing and Language, Minifie F. D., Hixon T. J. and Williams F. (Eds.), Prentice-Hall, Englewood Cliffs, 1973, pp. 73–125.
Hoffman, D. S. and Luschei, E. S., Responses of monkey precentral cortical cells during a controlled jaw bite task, J. Neurophysiol., 44 (1980) 333–348.
Holstege, G., An anatomical study on the final common pathway for vocalization in the cat, J. Comp. Neurol, 284 (1989) 242–252.
Holstege, G., Cowie, R.J. and Gerrits, P.O., Nucleus prepositus hypoglossi projects to the dorsolateral periaqueductal gray (PAG): A link between visuomotor and limbic systems, Neurosci. Abst., 16 (1990) 729.
Hosobuchi, Y., Periaqueductal gray stimulation in humans produces analgesia accompanied by elevation of β-endorphin and ACTH in ventricular CSF, Mod. Probl. Pharmacopsychiat., 17 (1981) 109–122.
Jürgens, U. and Ploog, D., Cerebral representation of vocalization in the Squirrel monkey, Exp. Brain Res., 10 (1970) 532–554.
Jürgens, U., Amygdalar Vocalization Pathways in the Squirrel Monkey, Brain Res., 241 (1982) 189–196.
Jürgens, U., The Squirrel monkey as an experimental model in the study of cerebral organization of emotional vocal utterances, Eur. Arch. Psychiatr. Neurol. Sci., 236 (1986) 40–43.
Jürgens, U. and Pratt, R., Role of the periaqueductal grey in vocal expression of emotion, Brain Res., 167 (1979) 367–378.
Jürgens, U. and Richter, K., Glutamate-Induced vocalization in the Squirrel monkey, Brain Res., 373 (1986) 349–358.
Lamandella, J. T., The limbic system in human communication, In: Studies in Neurolinguistics, Whitaker J. and Whitaker H. A. (Eds.), Academic Press, New York, 1977, pp. 157–222.
Larson, C. R. and Kistler M. K., Periaqueductal gray neuronal activity associated with laryngeal EMG and vocalization in the awake monkey, Neurosci. Lett., 46 (1984) 261–266.
Larson, C. R. and Kistler, M. K., The relationship of periaqueductal gray neurons to vocalization and laryngeal EMG in the behaving monkey, Exp. Brain Res., 63 (1986) 596–606.
Larson, C.R., On the relation of PAG neurons to laryngeal and respiratory muscles during vocalization in the monkey (Submitted).
Luschei, E. S., Garthwaite, C. R. and Armstrong, M. E., Relationship of firing patterns of units in face area of monkey precentral cortex to conditioned jaw movements, J. Neurophysiol., 34 (1971) 552–561.
Magoun, H. W., Atlas, D., Ingersoll, E. H. and Ranson, S. W., Associated facial, vocal and respiratory components of emotional expression: An experimental study, J. Neurol. Psychopath., 17 (1937) 241–255.
Mantyh, P. W., Forebrain Projections to the Periaqueductal Gray in the Monkey, with Observations in the Cat and Rat., J. Comp. Neurol., 206 (1982) 146–158.
Müller-Preuss, P. and Jürgens, U., Projections from the cingular vocalization area in the squirrel monkey, Brain Res., 103 (1976) 29–34.
Ni., H., Zhang, J. and Harper, R.M., Respiratory-related discharge of periaqueductal gray neurons during sleep-waking states, Brain Res., 511 (1990) 319–325.
Robinson, B. W., Vocalization evoked from forebrain in Macaca mulatta., Psychol. Behav., 2 (1967) 345–354.
Sapir, S., Campbell, C. and Larson, C., Effect of geniohyoid, cricothyroid and sternothyroid muscle stimulation on voice fundamental frequency of electrically elicited phonation in rhesus macaque, Laryng., 91 (1981) 457–468.
Sutton, D., Larson, C., Taylor, E. M. and Lindeman, R. C., Vocalization in Rhesus monkeys: Conditionability, Brain Res., 52 (1973) 225–231.
Sutton, D., Larson, C. and Lindeman, R. C., Neocortical and limbic lesion effects on primate phonation, Brain Res., 71 (1974) 61–75.
Thorns, G. and Jürgens, U., Common input of the cranial motor nuclei involved in phonation in Squirrel monkey, Exp. Neurol., 95 (1987) 85–99.
Tredici, G., Bianchi, R. and Gioia, M., Short Intrinsic Circuit in the Periaqueductal Gray Matter of the Cat, Neurosci. Lett., 39 (1983) 131–136.
West, R. and Larson, C.R., Measurements of the variability in EMGs of laryngeal and respiratory muscles during vocalization in the monkey. (Submitted).
Yoshida, Y, Mitsumasu, T., Hirano, M. and Kanaseki, T., Afferent connections to the nucleus ambiguus in the brain stem of the cat: an HRP study Presented at the 4th Int. Conf. on Vocal Fold Physiology, Yale Univ., New Haven, CT (1985).
Zealear, D. L. and Larson, C. R., A microelectrode study of laryngeal motoneurons in the nucleus ambiguus of the awake vocalizing monkey, In: Vocal Physiology: Voice Production, Mechanisms and Functions, Fujimura O. (Ed.), Raven Press, New York, 1988, pp. 29–37.
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Larson, C.R. (1991). Activity of PAG Neurons During Conditioned Vocalization in the Macaque Monkey. In: Depaulis, A., Bandler, R. (eds) The Midbrain Periaqueductal Gray Matter. NATO ASI Series, vol 213. Springer, Boston, MA. https://doi.org/10.1007/978-1-4615-3302-3_3
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