Hunjan U. G, Reddy K. J. Psychoneuroimmunological Perspective of Animal-Assisted Therapy. Biomed Pharmacol J 2024;17(3).
Manuscript received on :21-11-2022
Manuscript accepted on :28-03-2023
Published online on: 22-08-2024
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Second Review by: Dr. Asim Faraz
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Unnati G Hunjan1* and K. Jayasankara Reddy2

Department of Psychology, Christ University, Bangalore, India.

Corresponding Author Email: unnatihunjan5@gmail.com

DOI : https://dx.doi.org/10.13005/bpj/2988

Abstract

Animal-assisted therapy is a new and upcoming form of therapy that has shown multifarious benefits to participants. It is a goal-oriented therapeutic process with the incorporation of a qualified therapy animal in the therapeutic activities and conversations. This paper explores these benefits from a psychoneuroimmunological lens, wherein the interplay of and impact on an individual's psychological, neurological and immune systems are discussed. Positive physical interaction with therapy animals reduces undesirable symptoms and ailments such as stress, anxiety, depressive symptoms, aggressive tendencies, harmful behaviours, cardiovascular issues and unhealthy tendencies amongst others. It further promotes a healthier lifestyle, promoting quality of life, better heart health, cognitive functioning and overall well-being. The biological basis of these benefits is discussed.

Keywords

Animal-assisted therapy; Health; Immunity; Psychoneuroimmunology; Therapy Dog

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Introduction

Animals have been a part of human lives from time immemorial. We see their presence in ancient carvings, idols, scriptures and even as holy figures, deities and gods in many cultures. They have been an integral part, be it for protection, hunting, status symbols, by-products or more recently for companionship, guidance and healing. Scientific research about their effectiveness in therapy had not begun until the 1960s1but over time more researchers have taken an interest in the benefits that interactions with animals can bring about. Today, our bond with animals has gotten stronger than ever, with many considering them as family and some even preferring to get a pet over birthing a child.

The inclusion of a therapy animal in a therapeutic process from diagnosis, treatment, maintenance, guidance and/or rehabilitation is known as animal-assisted therapy (AAT). It is a goal-oriented process that entails activities that the animal is a part of and the progress is measured for the specified goals and objectives for the individual or group. In AAT, the animal must meet specific criteria in terms of its health, behaviour, temperament and training that qualify it as a therapy animal.2 The mere presence of an animal in a therapy setting is known to bring about more positive outcomes, so one can imagine how effective structured interventions with them can be. This paper will explore the psychoneurological impact of animal-assisted therapy. Psychoneuroimmunology was first coined by George F. Solomon3 and it refers to the interaction between an individual’s immune system and their psychological and neurological functioning.

Neurotransmitter and Biochemical Regulation

Animal-assisted activities of just fifteen minutes impact neurochemicals such as dopamine, endorphins, prolactin, oxytocin and beta phenylethylamine.4 Endorphins act as a hormone as well as a neurotransmitter. It impacts the immune system, has analgesic properties, and relieves pain and stress5 and through the release of transmitters, it helps regulate respiration and muscles of the intestine.6 Pleasurable states such as laughter, copulation, and enjoying food are related to the release of endorphins.7

Stress is caused due to high levels of norepinephrine and very low levels contribute to depressive symptoms. Interaction with therapy animals helps regulate this chemical. It plays a crucial role in regulating blood pressure, heart rate, body fat breakdown and sugar levels. It also impacts attention, focus, memory and sleep-wake cycles.8 The limbic system is impacted by its release leading to an enhanced sense of well-being, happiness, contentment, and improved psychomotor functioning.8

The HPA (hypothalamus – pituitary gland – adrenal gland) axis- releases cortisol, high levels of which negatively impact the functioning of the immune system.9,10 It also impairs memory, and cognition,11 and depressive symptoms,12 and regulates the behaviour and mood of individuals.4 AAT helps reduce cortisol levels relieving stress, depressive symptoms and anxiety,13,14,15 preventing further damage.

Skin is the largest organ of our body and positive physical interactions with therapy animals help release oxytocin in humans and animals.16 It improves the participants’ social interactions by improving their empathy, memory, self-perception, eye contact, and social skills and lowers depression.17,18 It helps maintain eye contact for longer and improves attachment,19 learning, maternal care and bonding while reducing aggression and stress.20 Its release also impacts the immune system, increasing the threshold for pain, and providing an anti-inflammatory and anxiolytic effect.21 Furthermore, the parasympathetic nervous system functioning is improved as well as the endocrine system wherein the gastrointestinal tract and digestive function are benefitted leading to growth and restoration.22 It is distributed throughout the nervous system, impacting gastrointestinal, socio-sexual and cardiovascular health.4

Post AAT a significant increase in the levels of prolactin has been observed23 which further impacts oxytocin, progesterone, oestrogen, insulin and growth hormone.24 It reduces pain,25 impacts sleep-wake, the growth and development of mammary glands and other tissues, metabolises carbohydrates and fat24 and modules psychoneuroendocrine responses.25 The immune system functioning is improved as seen through the rise in salivary immunoglobulin.13,26

Cardiovascular and Physiological Implications of AAT

Therapy in the presence of a therapy dog, even without physical interactions with it, has been shown to positively impact participant blood pressure and heart rate.27 The dog’s presence improved morale and motivated individuals to seek therapy and make efforts towards achieving healthier conditions. It caused a long-term impact, which is a key predictor for motivation and higher levels of good health.2 It is amazing to note that positive outcomes have been reported not just through long-term physical contact with therapy animals, but also with shorter visits, observations or virtual encounters.28

Stressors such as psychosocial, childhood trauma, separation, depression or anxiety compromise the competency of the immune system to fight infections, cancer or other diseases. Stress also directly and negatively impacts cardiovascular functioning29 and causes

irregular sleep, dysregulation of the bowels, headaches and other symptoms.30 Interactions with therapy animals in such situations act as a distraction, entertaining the participants, and relieving their stress while giving them a chance to bond and build companionship. It improves self-esteem and psychosocial functioning.31

Systolic and diastolic blood pressure is impacted during interactions with a therapy animal, and reduced blood pressure32 and heart rate33 are observed. Individuals with coronary heart disease and other cardiovascular diseases have reported positive outcomes, with health improvement.33 They had lower levels of cholesterol and triglycerides.34 A brief exposure to therapy animals, as reported by Odendaal (1999) shows reduced mean arterial blood pressure and an increase in phenylethylamine, which further alleviates fatigue and elevates mood. Present in the limbic system, it performs as a regulator of emotions. An increase in plasma dopamine level was also indicated, which has a crucial role to play in the kidneys. This includes species-specific behaviours, complex movements, emotional responses,6behavioural activation and reward perceptions.35

Health, Lifestyle and Psychological Benefits

After AAT sessions, individuals have reported better overall life satisfaction, improved competence with social situations, personal cleanliness, psychosocial functioning, and self-concept36 and improved interactions in social situations, leading to a reduction in underlying symptoms.37,38,39 It helps to increase tolerance towards stress by changing the individual’s perception towards stressors and improving overall health and well-being.40 There are many long-term benefits as well, individuals have reported that post-sessions they have better overall health and reduced visits to the doctor20,41, and reduced consumption of medication.41 They felt more motivated to stay healthy, engaged in more fitness-related activities, slept better, exercised more, had reduced absenteeism from work42 and initiated fewer visits to the doctor.42,43

These long-term positive changes were observed not just for physical health but mental health too.44 They had better emotion regulation, a better sense of empathy and responsibility, adopted healthier attitudes45 and more positive behaviours.46 This resulted in fewer negative behaviours, self-harm,16 and aggressive tendencies,47 with an overall better state of mind.48 Reduced number of seizures,49 improved gait, mobility, walking50 and hearing51 have also been reported.

Along with the cognitive and behavioural benefits discussed above, positive interactions with therapy animals caused improved attention, sensory sensitivity and motivation while reducing sedentary behaviours and distractions.52 Improvements in spatial orientation, memory and attention, language, temporal orientation and overall cognitive functioning were observed.53,54 Interactions with pets reduce the pressure and stress of conversations and can be largely non-verbal. It makes speaking and expressing oneself easier and passively starts improving their mental and physical health without the discomfort of having to discuss it, especially in the case of traumatic events wherein it has led to neurobiological benefits.54

After animal-assisted therapy sessions, individuals took more interest in day-to-day activities and felt more participative, and engaged with their lives,55 and a better quality of life and overall well-being.56 They reported better habits related to the consumption of food, wherein they were eating healthier and more nutritious foods.57 Improved self-awareness and reduced distress, as well as outbursts, were experienced.55 Individuals with various diseases and disorders have observed improvements with AAT, including anxiety, depression, mood disorders, Alzheimer’s, autism, psychotic ailments, heart conditions, dementia and oncological difficulties amongst others.2

Conclusion

Animal-assisted therapy is a relatively new type of therapy and has a lot of scope for future research. Positive interactions with therapy animals in a structured manner play an integral role in psychoneuroimmunology. It impacts the psychological, behavioural, neurological, and immune systems; and regulates various neurotransmitters and biochemicals that interact with these systems. The short and long-term benefits include reduced negative symptoms while reporting improved cardiovascular functioning, overall health, well-being, quality of life, cognitive functioning, healthier behaviours and better immunity.

Acknowledgements

The author would like to thank, (Insert university name and Dept. name) for their guidance and support to complete this article.

Conflict of Interest

There are no conflicts of interest to disclose.

Funding Sources

There are no funding sources to be disclosed.

References

  1. Hooker, S. D., Holbrook Freeman, L., & Stewart, P., Pet Therapy Research: A Historical Review, Holistic Nursing Practice, 2002, 17(1), 17–23.
    CrossRef
  2. Fine, A. H., Handbook on Animal-Assisted Therapy: Foundations and Guidelines for Animal-Assisted Interventions, Elsevier Academic Press, 2015.
  3. Kiecolt-Glaser, J. K., McGuire, L., Robles, T. F., & Glaser, R., Psychoneuroimmunology: Psychological Influences on Immune Function and Health, Journal of Consulting and Clinical Psychology, 2002, 70(3), 537–547.
    CrossRef
  4. Odendaal, J. S. J., Animal-Assisted Therapy—Magic or Medicine? Journal of Psychosomatic Research, 2000, 49(4), 275–280.
    CrossRef
  5. Chaudhry, S. R., & Gossman, W., Biochemistry, Endorphin, StatPearls, 2021.
  6. Odendaal, J. S., A Physiological Basis for Animal-Facilitated Psychotherapy, University of Pretoria, Pretoria, South Africa, 1999.
  7. Fischer, E. G., & Falke, N. E., β-Endorphin Modulates Immune Functions, Psychotherapy and Psychosomatics, 1984, 42(1–4), 195–204.
    CrossRef
  8. O’Donnell, J., Zeppenfeld, D., McConnell, E., Pena, S., & Nedergaard, M., Norepinephrine: A Neuromodulator That Boosts the Function of Multiple Cell Types to Optimize CNS Performance, Neurochemical Research, 2012, 37(11), 2496–2512.
    CrossRef
  9. Cortisol | Endocrine Society, 2018. https://www.hormone.org/your-health-and-hormones/glands-and-hormones-a-to-z/hor mones/cortisol
  10. Arranz, L., Guayerbas, N., & De la Fuente, M., Impairment of Several Immune Functions in Anxious Women, Journal of Psychosomatic Research, 2007, 62(1), 1–8.
    CrossRef
  11. Brunner, R., Schaefer, D., Hess, K., Parzer, P., Resch, F., & Schwab, S., Effect of High-Dose Cortisol on Memory Functions, Annals of the New York Academy of Sciences, 2006, 1071(1), 434–437.
    CrossRef
  12. Sindi, S., Juster, R.-P., Wan, N., Nair, N. P. V., Kin, N. Y., & Lupien, S. J., Depressive Symptoms, Cortisol, and Cognition During Human Aging: The Role of Negative Aging Perceptions, Stress, 2012, 15(2), 130–137.
    CrossRef
  13. Barker, S. B., Knisely, J. S., McCain, N. L., & Best, A. M., Measuring Stress and Immune Response in Healthcare Professionals Following Interaction with a Therapy Dog: A Pilot Study, Psychological Reports, 2016, 96(3), 713–729.
    CrossRef
  14. Odendaal, J. S. J., & Meintjes, R. A., Neurophysiological Correlates of Affiliative Behaviour Between Humans and Dogs, The Veterinary Journal, 2003, 165(3), 296–301.
    CrossRef
  15. Viau, R., Arsenault-Lapierre, G., Fecteau, S., Champagne, N., Walker, C.-D., & Lupien, S., Effect of Service Dogs on Salivary Cortisol Secretion in Autistic Children, Psychoneuroendocrinology, 2010, 35(8), 1187–1193.
    CrossRef
  16. Chandler, C. K., Animal Assisted Therapy in Counseling, Routledge, 2012.
    CrossRef
  17. Cardoso, C., Ellenbogen, M. A., & Linnen, A.-M., Acute Intranasal Oxytocin Improves Positive Self-Perceptions of Personality, Psychopharmacology, 2012, 220(4), 741–749.
    CrossRef
  18. Jonas, W., Nissen, E., Ransjö-Arvidson, A. B., Matthiesen, A. S., & Uvnäs-Moberg, K., Influence of Oxytocin or Epidural Analgesia on Personality Profile in Breastfeeding Women: A Comparative Study, Archives of Women’s Mental Health, 2008, 11(5), 335–345.
    CrossRef
  19. Nagasawa, M., Kikusui, T., Onaka, T., & Ohta, M., Dog’s Gaze at its Owner Increases Owner’s Urinary Oxytocin During Social Interaction, Hormones and Behavior, 2009, 55(3), 434–441.
    CrossRef
  20. Beetz, A., Uvnäs-Moberg, K., Julius, H., & Kotrschal, K., Psychosocial and Psychophysiological Effects of Human-Animal Interactions: The Possible Role of Oxytocin, Frontiers in Psychology, 2012, 3.
    CrossRef
  21. Uvnäs-Moberg, K., Ahlenius, S., Hillegaart, V., & Alster, P., High doses of oxytocin cause sedation and low doses cause an anxiolytic-like effect in male rats, Pharmacology Biochemistry and Behavior, 1994, 49(1), 101–106.
    CrossRef
  22. Widström, A.-M., Winberg, J., Werner, S., Svensson, K., Posloncec, B., & Uvnäs-Moberg, K., Breastfeeding-induced effects on plasma gastrin and somatostatin levels and their correlation with milk yield in lactating females, Early Human Development, 1988, 16(2), 293–301.
    CrossRef
  23. Serpell, J., Beneficial Effects of Pet Ownership on Some Aspects of Human Health and Behaviour, Journal of the Royal Society of Medicine, 1991, 84(12), 717–720.
    CrossRef
  24. Freeman, M. E., Kanyicska, B., Lerant, A., & Nagy, G., Prolactin: Structure, function, and regulation of secretion, Physiological Reviews, 2000, 80(4), 1523–1631.
    CrossRef
  25. Braun, C., Stangler, T., Narveson, J., & Pettingell, S., Animal-assisted therapy as a pain relief intervention for children, Complementary Therapies in Clinical Practice, 2009, 15(2), 105–109.
    CrossRef
  26. Charnetski, C. J., Riggers, S., & Brennan, F. X., Effect of Petting a Dog on Immune System Function, Psychological Reports, 2016, 95(3f), 1087–1091.
    CrossRef
  27. Allen, K. M., Blascovich, J., Tomaka, J., & Kelsey, R. M., Presence of human friends and pet dogs as moderators of autonomic responses to stress in women, Journal of Personality and Social Psychology, 1991, 61(4), 582.
    CrossRef
  28. Johnson, R. A., Odendaal, J. S. J., & Meadows, R. L., Animal-Assisted Interventions Research: Issues and Answers, Western Journal of Nursing Research, 2016.
  29. Riley, V., Psychoneuroendocrine influences on immunocompetence and neoplasia, Science, 1981, 212(4499), 1100–1109.
    CrossRef
  30. Reddy, J., & Hunjan, U. G., A Neurobiological Perspective on Psychological Stress, European Journal of Medical and Health Sciences, 2019, 1(2), Article 2.
  31. Arkow, P., Chapter 5 – Animal Therapy on the Community Level: The Impact of Pets on Social Capital, in Handbook on Animal-Assisted Therapy (Fourth Edition), Academic Press, 2015, pp. 43–51. https://doi.org/10.1016/B978-0-12-801292-5.00005-5
    CrossRef
  32. Baun, M. M., Bergstrom, N., Langston, N. F., & Thoma, L., Physiological effects of human/companion animal bonding, Nursing Research, 1984, 33(3), 126–129.
    CrossRef
  33. Friedmann, E., Locker, B. Z., & Lockwood, R., Perception of Animals and Cardiovascular Responses During Verbalization With an Animal Present, Anthrozoös, 1993, 6(2), 115–134.
    CrossRef
  34. Anderson, W. P., Reid, C. M., & Jennings, G. L., Pet ownership and risk factors for cardiovascular disease, Medical Journal of Australia, 1992, 157(5), 298-301.
    CrossRef
  35. Reddy, K. J., Menon, K. R., & Hunjan, U. G., Neurobiological Aspects Of Violent And Criminal Behaviour: Deficits In Frontal Lobe Function And Neurotransmitters, 2018.
  36. Francis, G., Turner, J. T., & Johnson, S. B., Domestic animal visitation as therapy with adult home residents, International Journal of Nursing Studies, 1985, 22(3), 201–206.
    CrossRef
  37. Fick, K. M., The Influence of an Animal on Social Interactions of Nursing Home Residents in a Group Setting, American Journal of Occupational Therapy, 1993, 47(6), 529–534.
    CrossRef
  38. Winkler, A., Fairnie, H., Gericevich, F., & Long, M., The Impact of a Resident Dog on an Institution for the Elderly: Effects on Perceptions and Social Interactions, The Gerontologist, 1989, 29(2), 216–223.
    CrossRef
  39. Taylor, E., Maser, S., Yee, J., & Gonzalez, S. M., Effect of Animals on Eye Contact and Vocalizations of Elderly Residents in a Long Term Care Facility, Physical & Occupational Therapy In Geriatrics, 1994, 11(4), 61–71.
    CrossRef
  40. Friedmann, E., & Son, H., The Human–Companion Animal Bond: How Humans Benefit, Veterinary Clinics of North America: Small Animal Practice, 2009, 39(2), 293–326.
    CrossRef
  41. Headey, B., Health Benefits and Health Cost Savings Due to Pets: Preliminary Estimates from an Australian National Survey, Social Indicators Research, 1999, 47(2), 233–243.
    CrossRef
  42. Headey, B., Na, F., & Zheng, R., Pet Dogs Benefit Owners’ Health: A ‘Natural Experiment’ in China, Social Indicators Research, 2008, 87(3), 481–493.
    CrossRef
  43. Siegel, J. M., Angulo, F. J., Detels, R., Wesch, J., & Mullen, A., AIDS diagnosis and depression in the Multicenter AIDS Cohort Study: The ameliorating impact of pet ownership, AIDS Care, 1999, 11(2), 157–170.
    CrossRef
  44. Na, F., & Richang, Z., Influences of pets on the empty nester family, Chinese Mental Health Journal, 2003, 17, 569–571.
  45. Anderson, K. L., & Olson, M. R., The value of a dog in a classroom of children with severe emotional disorders, Anthrozoös, 2006, 19(1), 35–49.
    CrossRef
  46. Esteves, S. W., & Stokes, T., Social Effects of a Dog’s Presence on Children with Disabilities, Anthrozoös, 2008, 21(1), 5–15.
    CrossRef
  47. Tissen, I., Hergovich, A., & Spiel, C., School-Based Social Training with and without Dogs: Evaluation of Their Effectiveness, Anthrozoös, 2007, 20(4), 365–373.
    CrossRef
  48. Prothmann, A., Bienert, M., & Ettrich, C., Dogs in child psychotherapy: Effects on state of mind, Anthrozoös, 2006, 19(3), 265–277.
    CrossRef
  49. Strong, V., Brown, S., Huyton, M., & Coyle, H., Effect of trained Seizure Alert Dogs® on frequency of tonic–clonic seizures, Seizure, 2002, 11(6), 402–405.
    CrossRef
  50. Whitmarsh, L., The Benefits of Guide Dog Ownership, Visual Impairment Research, 2005, 7(1), 27–42.
    CrossRef
  51. Guest, C. M., Collis, G. M., & McNicholas, J., Hearing Dogs: A Longitudinal Study of Social and Psychological Effects on Deaf and Hard-of-Hearing Recipients, The Journal of Deaf Studies and Deaf Education, 2006, 11(2), 252–261.
    CrossRef
  52. Bass, M. M., Duchowny, C. A., & Llabre, M. M., The Effect of Therapeutic Horseback Riding on Social Functioning in Children with Autism, Journal of Autism and Developmental Disorders, 2009, 39(9), 1261–1267. https://doi.org/10.1007/s10803-009-0734-3
    CrossRef
  53. Menna, L. F., Santaniello, A., Gerardi, F., Maggio, A. D., & Milan, G., Evaluation of the efficacy of animal-assisted therapy based on the reality orientation therapy protocol in Alzheimer’s disease patients: A pilot study, Psychogeriatrics, 2016, 16(4), 240–246.
    CrossRef
  54. Nathanson, D. E., Castro, D. de, Friend, H., & McMahon, M., Effectiveness of Short-Term Dolphin-Assisted Therapy for Children with Severe Disabilities, Anthrozoös, 1997, 10(2–3), 90–100.
    CrossRef
  55. Fine, A. H., Handbook on Animal-Assisted Therapy: Theoretical Foundations and Guidelines for Practice, Elsevier, 2011.
  56. Davis, E., Davies, B., Wolfe, R., Raadsveld, R., Heine, B., Thomason, P., Dobson, F., & Graham, H. K., A randomized controlled trial of the impact of therapeutic horse riding on the quality of life, health, and function of children with cerebral palsy, Developmental Medicine & Child Neurology, 2009, 51(2), 111–119.
    CrossRef
  57. Edwards, N. E., & Beck, A. M., Animal-Assisted Therapy and Nutrition in Alzheimer’s Disease, Western Journal of Nursing Research, 2002, 24(6), 697–712.
    CrossRef
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