PSY707 Week 3 - Nervous System & Stress (PDF)

Summary

These lecture notes cover the nervous system, stress response systems (SAM and HPA axis), and the interaction with the endocrine system. The document includes diagrams and information on different structures and functions related to stress and health outcomes.

Full Transcript

PSY707
Week 3
Dr. AJ. Fiocco

1
 Week 3 Class objectives

Name and describe key components of the nervous system

Name and describe two key stress-sensitive systems

Describe immune system activity during acute and chronic stress

Describe stress and cellular aging (revisiting Selye)

2
The Nervous System

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Central Nervous System (CNS)

Image: https://www.pinterest.ca/pin/117726977736536966/

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Selective Overview of CNS
Structures of the Forebrain
Telencephalon: Cerebral cortex; Limbic system; Basal ganglia
Diencephalon: Thalamus; Hypothalamus

https://www.pinterest.ca/pin/117726977736536966/
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Selective Overview: Forebrain
Cerebral cortex (neocortex)
4 lobes: frontal; temporal; parietal; occipital
Prefrontal cortex (PFC): important for executive
functioning and behavioral regulation
Limbic System
Hippocampus, amygdala, anterior cingulate
cortex (ACC)
Memory (HC) and emotion/fear (amygdala)
Emotional control (ACC)
Basal Ganglia
Important for movement control, Image: https://quizlet.com/226074431/lobes-of-brain-diagram/

vigilance/attention, learning (procedural)
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Selective Overview: Forebrain
Thalamus
A regulatory gateway: relays sensorial and motor
information
Regulates consciousness, sleep, alertness

Hypothalamus
Regulation of homeostasis
Controls the autonomic nervous system and
endocrine system
Fighting, feeding, fleeing, mating, sleeping, drinking
Exert effects through the pituitary gland

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Selective Overview: Midbrain & Hindbrain
Structure within the Hindbrain and Midbrain
Brain stem: Contains the pons, medulla and midbrain
Locus Coeruleus (NE)
Substantia Nigra (Dopamine)
Raphe nuclei (Serotonin)
Reticular Formation

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 Selective Overview: Midbrain & Hindbrain
Locus coeruleus
Located in the pons
Nuclei involved in physiological response to
stress (produces NE)
Reticular formation
Bundles of nuclei
Extends from hindbrain to the diencephalon
Transmits information between CNS and PNS
Important for attention, arousal, movement,
and vital reflexes (e.g. cardiovascular control)
Fight-or-Flight Response!

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Handy model of the brain (Dan Siegel)

Image: https://blog.lcs.on.ca/2019/11/15/attention-muscle-reps/

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The Nervous System

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 PNS: Somatic Nervous System
Somatic nervous system: innervates the skeletal muscles, the skin and the sense
organs

Neural pathways that send signals from the brain to the periphery are efferent
and those that send signals from the periphery to the brain are afferent

Fight-or-flight response activates the striated (skeletal) muscles

Too much stress can lead to over-activation of striated muscles, resulting in
muscle pain and tension

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 PNS: Autonomic Nervous System
Autonomic nervous system: innervates the body’s viscera (i.e., internal organs)
through pre- and post-ganglionic neurons

Viscera consists of the organs, ducts and glands, smooth muscles, and blood
vessels

The sympathetic branch (SNS) of the autonomic nervous system is responsible
for activating the fight-or-flight responses

Parasympathetic branch (PNS) is associated with rest-and-digest responses

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PNS

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Autonomic Nervous System

Basal energy conservation/restoration
vs.
Energy mobilization /expenditure
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Endocrine System

A system of organs and glands that
secrete hormones into the blood stream
to send messages to cells and organs

Endocrine system works with the
sympathetic nervous system during fight-
or-flight activation to reach a common
outcome

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Image: https://www.pinterest.com/pin/112167846940604950/
 A Few Important Glands and their
Hormones
Hypothalamus Pituitary Adrenal Cortex Adrenal Medulla

Corticotropin-releasing Adrenocorticotropic Glucocorticoids Epinephrine(E)
hormone (CRH) hormone (ACTH) (GC)/cortisol Norepinephrine(NE)
Oxytocin Thyroid-stimulating
Vasopressin hormone (TSH)
Beta-endorphin

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 Week 3 Class objectives

Name and describe key components of the nervous system

Name and describe two key stress-sensitive systems

Describe immune system activity during acute and chronic stress

Describe stress and cellular aging (revisiting Selye)

18
 Stress Response Systems
2 important stress response systems
Sympathetic-Adrenal-Medulla (SAM) Axis
Hypothalamic-Pituitary-Adrenal (HPA) Axis

Interconnected and independent function

Timing is different
SAM = Fast, within seconds and ending in minutes
HPA = Slow, within minutes and lasting hours

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 FAST ACTING Cortex and
Limbic SLOW ACTING
SAM LC- System HPA
NE

Endocrine
Sympathetic activation
activation of Hypothalamus
Release of
ANS CRH/CRF

Stimulates anterior pituitary
gland to release ACTH
Stimulates adrenal medulla to
release Epinephrin and
Norepinephrin Stimulates adrenal cortex to
release GC (cortisol)

Supports SAM activity; regulates
Fight or Flight metabolism and immune; Negative
feedback loop
Juster et al., 2011 20
 SAM Axis
Hypothalamus

Brain Stem [reticular formation]

Autonomic Nervous System

Via nerve fibers
Adrenal Medulla

Release adrenaline (epinephrine) and noradrenaline (norepinephrine)

Physiological events
(dilating pupils, increase heart rate, dilation of bronchial tubes, sweat
stimulation, glucose release from liver, overall increase in metabolic rate)
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 HPA Axis
Stressor

Hypothalamus is alerted and secretes CRH

Hypothalamus alerts the Pituitary to secrete ACTH

ACTH travels through the blood and alerts the adrenal cortex

Adrenal cortex secretes and releases glucocorticoids/cortisol

Chain of physiological events
(increase in blood glucose, increase fatty acids and amino acids in
blood, increase blood pressure, immune regulation

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Image: https://www.integrativepro.com/Resources/Integrative-Blog/2016/The-HPA-Axis
Note:
Cortisol is a major stress hormone that helps your body respond to
stress, including the stress of illness or injury. It also helps maintain
your BP, heart function, immune system and blood glucose levels.

Cortisol is essential for life.

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 Rare Conditions of HPA Dysregulation
Addison’s disease (aka Cushing’s disease
adrenal insufficiency) Adrenal cortex produces too
Caused by much cortisol – caused by
autoimmune disorder years of glucocorticoid tx,
or damage to the tumor on pituitary or adrenal
adrenal glands gland
Adrenal cortex does Symptoms: muscle
not produce enough weakness, emotion
cortisol dysregulation, cognitive
Symptoms: muscle difficulties, high BP, infection,
weakness, low BP, bone loss, bruising, truncal
fatigue, appetite & obesity, buffalo hump
weight loss, low blood
sugar, GI disruption 24
 Week 3 Class objectives

Name and describe key components of the nervous system

Name and describe two key stress-sensitive systems

Describe immune system activity during acute and chronic stress

Describe stress and cellular aging (revisiting Selye)

25
 Psychoneuroimmunology
(psycho=consciousness, neuro=brain, immunology=body’s defense against infection

“Stress plays a role in
50% to 80%
of all illness and disease”
Pelletier 1977

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 The Immune System
The immune system protects us from harmful antigens such as bacteria,
fungi, and viruses (the invaders)
Our immune system has a number of layers of defense to protect our
body from these invaders.

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 The Immune System
Layers of defense:

Innate immune system (natural, non-specific): Defense at the level of the skin and
mucous membranes; bacteria that enter the skin are engulfed by phagocytes and
destroyed by natural killer cell lymphocytes. Inflammatory response may also come
into play.
Our first-responders

Adaptive immune system (acquired, specific): takes 4-5 days to defend against a
novel intruder. Once an intruder is recognized, it responds quickly in the future.
Know thy enemy
Importance of vaccinations
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 The Immune System
White blood cells (Leukocytes):
Phagocytes
Lymphocytes
Natural killer cells = cytotoxic, destroys invader organism as part of innate immune reaction.
Helper T cells = identify invader and stimulate multiplication of Killer T and B cells, produce
cytokines to alert the system
Killer T cells/cytotoxic T cells = destroy invader organism by puncturing and killing the
invaded cells
B cells = produce antibodies (immunoglobulins; Igs) that bind to antigens
Memory B and T cells = recognize and respond quickly to future invaders
Antibodies = cell proteins of the immune system that recognize antigens on the
pathogen and fight them.
Cytokines = cell proteins that serve as a chemical alarm bell (interleukin, interferon,
tumor necrosis factor) 29
 Immune System

Innate Immune Adaptive Immune
Non-specific Specific

Humoral
Cellular
Humoral (Th2)
Cellular (Th1)
Skin, mucosa, Lymphocytes (B
Phagocytes, NT Lymphocytes (NK, T
cytokines cells). Antibodies,
cells), phagocytes
cytokines
Cellular-mediated immunity Humoral-mediated immunity
Type 1 T-helper cell (Th1) Type 2 T-helper cell (Th2)
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 Stress and the Immune System
Does stress suppress immune
function??

BUT!
Research shows that stress can enhance immune function!!!… the paradox
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 Stress and the Immune System
Immune dysregulation:

Overactive immune system can result in allergies, arthritis, and
lupus; while an underactive immune system can result in cancer and
cold/flu outbreaks

Cortisol plays most important role in immunosuppression

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Stress and Immune function over time…Th1:Th2 ratio

Th1Th2

Th1 Th2

T Helper 1 (Th1, cellular) vs. T Helper 2 (Th2, humoral) 33
 Prolonged
Initial SAM
activation of
activation
HPA and
and release
secretion of
of NE
GC

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Examining the Relationship Between Chronic
Stress and Immune Dysregulation

Exam Stress Large-scale disasters Family caregiving

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 Stress and Immune Function:
[Caregiver = Chronic Stress Model]

Experimental, Observational Design
Sample: 13 women caring for relative and 13 age-
and income-matched controls
Wound healing: 49 vs 39 days to heal

Kiecolt-Glaser et al 1995 Lancet 36
The Caregiver: A Model of Chronic Stress?
Prospective,
Observational design
Sample: Older spousal
caregivers and non-
caregiver controls (66-96
yo)
Observational period:
1993 -1998 average 4.5
years of follow-up
Mortality: 63% relative
risk of mortality among
caregivers experiencing
caregiver burden

Schultz and Beach, 1999, JAMA
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 Caregiver Stress & Immune
Caregivers reported greater
symptoms of depression

Activation-induced T cell proliferation
is lower in caregivers than matched
controls
Greater pro-inflammatory cytokine
production in caregivers
Telomere length of leukocytes are
shorter in caregivers

Damjanovic et al., (2007). J Immonul. 38
 Week 3 Class objectives

Name and describe key components of the nervous system

Name and describe two key stress-sensitive systems

Describe immune system activity during acute and chronic stress

Describe stress and cellular aging (revisiting Selye)

39
 Revisiting Selye
“Every stress leaves an indelible scar, and the organism pays
for its survival after a stressful situation by becoming a little
older.”

Image: https://gettingstronger.org/2011/09/voluntary-stress/selye-2/

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Telomeres and
Telomerase
Telomeres = chromosome aglets
Protect the ends of chromosomes
“Disposable buffers” at the end of
chromosomes
Telomeres shorten with cell
division
Telomeres are consumed during
cell division and replenished by the
enzyme telomerase

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Telomeres and Mortality:
Cawthon et al 1999, Lancet

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 Telomeres and Stress in Caregivers
Study (Epel et al., 2004)
58 healthy mothers of a chronically ill child (n=39) or healthy child (n=19)
Measures psychological distress, TL and telomerase (blood)

Results:

High stressed women had 50% lower levels of telomerase

High stressed women had 50% lower levels of telomerase

High stressed women had shorter telomeres

Longer stress duration = shorter telomere length

Greater Perceived stress = shorter telomere length
Epel et al. 2004 PNAS
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Telomeres and Stress Biomarkers
Epel et al., 2006:
Collected evening urinary hormone excretion
Shorter telomeres associated with:
Higher cortisol
Higher norepinephrine and epinephrine

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Stress and Telomeres

Tomiyama et al 2012
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 TL is malleable!
Important: TL can change over time (Epel et al., 2009 Aging, Goglin et al., 2016)

Goglin et al 2016 46
 Telomeres and Stress
Shorter telomere length is associated with:
Smoking
Poor diet
Greater adipose composition
Increasing weight and increased insulin resistance*
Lower antioxidant intake
Sedentary (dose response effect)

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Take Home Messages
To understand stress, you need to understand what is going on
inside the body
This knowledge gives you perspective and a better understanding of how
stress may impact your health
If you can identify where stress shows up in the body, then you have a
target to work with
Chronic stress plays a significant role in a majority of poor health
outcomes
Chronic stress accelerates cellular aging
BUT! Remember, stress is in the eye of the beholder and the
relationship between chronic stress and health outcomes of
malleable
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