The Physiology and psychology of pain

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The Physiology and psychology of pain

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Title: The Physiology and psychology of pain


1
The Physiology and psychology of pain
  • Chapter 2

2
Pain
  • Of all the components of the injury response,
    none is less consistent or less understood than
    an individuals response to pain
  • The sensation of pain is a diffuse entity
    inherent to the nervous system and basic to all
    people
  • It is a personal experience that all humans
    endure
  • Acute pain is the primary reason why people seek
    medical attention and the major complaint that
    they describe on initial evaluation.

3
  • Chronic pain may be more debilitating than the
    trauma itself and, in many instances, is so
    emotionally and physically debilitating that it
    is a leading cause of suicide.
  • Pain serves as one of the bodys defense
    mechanisms by warning the brain that its tissues
    may be in jeopardy, yet pain may be triggered
    without any physical damage to tissues.
  • The pain response itself is a complex phenomenon
    involving sensory, behavioral (motor), emotional,
    and cultural components.

4
  • Once the painful impulse has been initiated and
    received by the brain, the interpretation of pain
    itself is based on interrelated biological,
    psychological, and social factors.
  • What are the nerve fibers that stimulate pain?
  • Nociceptors.
  • Once these are stimulated, pain impulses are
    sent to the brain as a warning that the bodys
    integrity is at risk.
  • The emotional response may be expressed by
    screaming, crying, fainting, or just thinking
    _at_, that hurts!

5
  • When the pain is intense or unexpected, an
    immediate reflex loop activates the behavioral
    response by sending instructions to motor nerves
    to remove the body part from the stimulus.
  • Sticking your finger with a needle
  • Placing your hand on a hot stove
  • These stimulis activate specialized nerve fibers
    to send signals through a peripheral nerve
    network
  • Routing the impulses up the spinal cord to the
    brain

6
  • When the afferent impulse reach the spinal cord,
    a reflex loop is formed within the tract to
    activate the muscles necessary to remove your
    hand or finger from the stimulus.
  • The remaining impulses of the reflex continue on
    to the brain, where they are translated as pain,
    and you respond by saying ouch! or other choice
    words.
  • If an individual has knowledge about a
    potentially painful stimulus, such as receiving
    an injection, cognitive mechanisms can inhibit
    the reflex loop and block portions of the
    behavioral response.
  • As a the painful stimulus increases, so does the
    conscious effort required to keep from trying to
    escape from the stimulus.

7
  • The emotional component may still be in place as
    you grimace, make a fist, or think what the _at_
    is this jerk doing to me.
  • The cultural components of pain are almost too
    complex to define.
  • However, pain perception has been linked to
    ethnicity and socioeconomic status.
  • Example
  • Italian patents are less inhibited in the
    expression of pain than are the Irish or
    Anglo-Saxon patients
  • Ultimately, cultural components can be viewed as
    any variable that relates to the environment in
    which a person was raised and how that
    environment deals with pain and responses to pain.

8
Pain Process
  • Noxious input or nociceptive stimulus causes the
    activation of pain fibers.
  • The painful impulse is triggered by the initial
    mechanical force of the injury (whether sudden or
    gradual onset) and is continued by chemical
    irritation resulting from the inflammatory
    process
  • In subacute and chronic conditions, pain may be
    continued by reflex muscle spasm in a positive
    feedback loop or through the continued presence
    of chemical irritation

9
  • The pain response is initiated by stimulation of
    nociceptors
  • Nociceptors- specialized nerve endings that
    respond to painful stimuli
  • Mechanical stress or damage to the tissues excite
    mechanosensitive nociceptors
  • Chemosensitive nociceptors are excited by various
    chemical substances released during the
    inflammatory response
  • Chemical irritation of nerve endings may produce
    a severe pain response without true tissue
    distruction

10
  • Unlike other types of nerve receptors,
    nociceptors display a sensitization to repeated
    or prolonged stimulation
  • During the inflammatory process, the threshold
    required to initiate an action potential is
    lowered, and the continued stimulation of the
    chemosensitve receptors perpetuates the cycle

11
  • To understand the complexity of pain,
    comprehension of the various neurophysiological
    pathways involved in transmission, perception,
    and inhibition of pain is critical.
  • The nervous system
  • Forms a complex network of afferent and efferent
    pathways.
  • Transmitting and reacting to impulses that the
    brain perceives as being painful
  • All noxious impulses are transmitted afferently
    to the thalmus
  • This produces the painful stimulus which
    triggers the physiological and psychological
    process described earlier

12
Modulation of Pain
  • Acute pain response begins with a noxious
    stimulus.
  • IE. A burn or cut externally or internally a
    muscle strain or ligament sprain
  • After trauma chemicals are released in and around
    the surrounding tissues.
  • Immediately after the trauma, primary
    hyperalgesia occurs
  • Lowers the nerves threshold to noxious stimuli
    and magnifying the pain response

13
  • Within hours, secondary hyperalgesia occurs
  • ? the size of the painful area as the chemicals
    diffuse into the surrounding tissues
  • Causes hypersensitivity
  • The initiation of the pain process always begins
    with a chemical stimulus.
  • Review chemical precursors
  • During acute trauma
  • Cell walls become damaged
  • Causes dopamine and norepinephrine (NE) to be
    released from precursors in the cell membrane
  • Causes the activation of phospholipas
  • Allowing the cell membrane to release arachidonic
    acid
  • When released in the presence of cyclooxygenase,
    it converts to prostaglandin

14
  • Prostaglandins have many roles in inflammation,
    but they also sensitize the nerve endings to
    other chemicals
  • IE bradykinin
  • Which in turn initiate nociception
  • Bradykinin, found in plasma and released during
    coagulation that follows injury, are direct
    activators of nociception.
  • Powerful vasodilators, ? vascular permeability
    during the inflammatory response
  • NSAIDs play and important role in the tx of
    acute pain in that they block the formation
    cyclooxygenase and prevent the synthesis of
    prostaglandins.
  • Therefore, NSAIDs are important as an early
    mediator for the interruption of the pain and
    inflammation cycle

15
Pain fibers
  • A-delta fibers- a type of nerve that transmits
    painful information that is often interpreted by
    the brain as burning or stinging pain
  • C-fibers- a type of nerve that transmits painful
    information that is often interpreted by the
    brain as throbbing or aching

16
  • After an injury, A-delta and C fibers carry
    noxious stimuli from the periphery (using which
    pathway?) to the dorsal horn of the spinal cord.
  • The noxious stimuli activates 10-20 of the
    A-delta fibers and 50-80 of the C-fibers.
  • Triggered by strong mechanical pressure or
    intense heat, A-delta fibers produce a fast,
    bright, localized pain sensation.
  • C-fibers are triggered by thermal, mechanical,
    and chemical stimuli and generate a more diffuse,
    nagging sensation

17
  • After an injury, such as a sprained ankle, you
    athlete feels
  • Sharp, well-localized, stinging or burning
    sensation coming from which fibers??
  • A-delta fibers
  • This initial reaction allows an indiviual to
    realized that trauma has occurred and to
    recognize the response as pain
  • Very quickly, the stinging or burning sensation
    becomes an aching or throbbing sensation, which
    indicates activation of which fiber
  • C-fibers
  • A third type of peripheral afferent nerve fiber
    warrants mention. A-beta fibers, respond to light
    touch and low intensity mechanical information.
  • Rubbing and injured area
  • These interrupt nociception to the dorsal horn

18
Ascending Pathways
  • First-order neurons- A-beta, A-delta, and C nerve
    fibers.
  • Because they all originate in the periphery and
    terminate in different areas of the dorsal horn
  • The gray matter of the spinal cord is divided
    into 10 layers of cell bodies called Laminae
  • Before synapsing in the laminae the peripheral
    afferent nerves course into the tract of Lissauer
  • Where A-delta and C fibers divide and send
    impulses up and down one to two segments of the
    spinal column.
  • Once in the dorsal horn of the spinal cord, the
    small A-delta and C fibers synapse with neurons
    and terminate in the various laminae

19
  • Lamina I contains several types of neurons
  • The 2 of interest to us are
  • Wide-dynamic-range (WDR) neurons
  • Nociceptive-specific (NS) neurons
  • WDR- respond to both noxious and non-noxious
    stimuli
  • NS- respond only to noxious stimuli
  • These neurons in lamina I are part of the cells
    that make up the Long spinothalamic tract (STT)

20
  • The Substantia Gelatinosa (SG), found partially
    within lamina II, contain small internuncial
    neurons
  • These neurons can excite (stalked cells) or
    inhibit (islet cells) the transmission of noxious
    stimuli
  • These neurons in the SG send axons to lamina I
    and release enkephalin and gamma-aminobutyric
    acid.
  • Both which inhibit the transmission of noxious
    stimuli
  • Enkephalin- a substance released by the body that
    reduces the perception of pain by bonding to pain
    receptors sites

21
  • Lamina III and IV- composed of WDR neuron cells
    and low-threshold mechanoreceptors.
  • The mechanoreceptors play a limited role in the
    modulation and transmission of pain
  • Lamina V- is a major synapse of A-delta and C
    fibers in the dorsal horn.
  • It also has a large of WDR cells that respond
    to a spectrum of stimuli from light touch to
    mechanical pressure and heat
  • WDR cells from laminae I 5 make up the majority
    of fiber in the STT.
  • Where first order neurons terminate and second
    order neurons originate
  • Second order- A nerve that has its body located
    in the spinal cord. It connects second and third
    order neurons
  • Third order- a nerve that has its body in the
    thalamus and extending into the cerebral cortex

22
  • 1st order neurons course from the periphery to
    synapse in the dorsal root ganglion and the
    laminae before crossing the spinal cord to the
    STT
  • Once in the STT, noxious stimulus is then
    transmitted to the brain via 2 different portions
    of the STT
  • The neospinothalamic (lateral) tract (NSTT)
  • Paleospinothalamic (ventral) tract (PSTT)
  • This dual-tract system of afferent pain pathways
    enables the body to have immediate warning of the
    presence, location, and intensity of an injury as
    well as the slow, aching reminder that tissue
    damage has occurred.

23
  • NSTT receives input from A-delta fibers that
    synapse with the nociceptive-specific neurons and
    the WDR neurons in Laminae I V.
  • These neurons of the NSTT immediately cross the
    ventral white column of the spinal cord to the
    opposite antrolateral white column.
  • Once in the ant horn, the fibers of the NSTT and
    a portion of STT synapse with motor units or
    stimulate preganglionic neurons of the
    sympathetic or parasympathetic system and then
    communicate with the thalamus.
  • This transmission is responsible for the motor
    and autonomic response associated with tissue
    damage and info pertinent to the site
  • Intensity
  • And duration of the painful stimulus

24
  • The NSTT has been described as the sensory
    discriminative pathway of pain.
  • The PSTT is located more medially, but still is
    in the anterolateral portion of the white matter
    of the spinal cord.
  • The PSTT receives input predominately from the C
    fibers.
  • These synapse with the nociceptive-specific
    neurons and the WDR neurons in Laminae I V
  • 2nd order neurons of Laminae I V cross over the
    spinal cord and project to the reticular
    formation (RF)
  • A diffuse network of cells and fibers located in
    the brain stem. Influences alertness, waking,
    sleeping, and certain reflexes.
  • The RF is located in the central portion of the
    brain stem, medulla oblongata, hypothalamus,
    thalamus, limbic system, and periaqueductal gray
    (PAG).

25
  • The RF is responsible for evoking motor, sensory,
    and autonomic responses to noxious stimuli.
  • This allows the injured person to respond rapidly
    to the stimuli.
  • The PSTT has multiple synapses with other areas
    of the central brain responsible for poorly
    localized, dull, aching pain as well as for the
    behavioral, emotional, and affective aspects of
    pain.

26
  • The brains limbic system aids in integrating
    higher brain function with motivational and
    emotional reactions.
  • Contains afferent nerves from the hypothalamus
    and the brain stem.
  • Receives descending influence from the cortex.
  • This communication is responsible for the
    emotional response to painful experiences.
  • When an injury occurs, the neural communication
    between the limbic system, thalamus, RF, and
    cortex produces reactions such as fear, anxiety,
    or crying.
  • In short , the limbic system is responsible for
    the bodys affective qualities of reward,
    punishment, aversive drives, and fear reactions
    to pain
  • AKA motivational-affective system.

27
  • The integration of the cortex is an important
    component in both the ascending and descending
    aspects of pain modulation.
  • Via axons, ascending pain stimuli are transmitted
    from the thalamus to the central sulcus in the
    parietal lobe (somatosensory cortex), where the
    pain is discriminated and localized.
  • Because of the proliferation of nerve cells and
    the cortexs functions
  • Consciousness
  • Speech
  • Hearing
  • Memory
  • Thought
  • It is unlikely that the afferent synapses that
    occur during noxious stimulation affect only one
    efferent neuron.
  • Thus, many areas of the cortex can be stimulated
    during a painful experience.

28
Descending Pathways
  • The descending pain modulation mechanisms could
    influence both the input and the mediation of the
    noxious stimuli
  • One of the descending mechanisms originates in
    the cortexs corticospinal tract.
  • The corticospinal tract descends from the cortex
    to the medulla, where fibers cross over to the
    opposite side of the medulla and to lower levels
    of the spinal cord, where it terminates in
    laminae I-VII and transends through the
    dorsolateral funiculus (large fiber tract)
  • This tract could act to exert postsynaptic
    (descending) control over the afferent
    transmission of thermal, mechanical, and C fiber
    input at laminae I II

29
  • A second structure exerting descending control of
    noxious stimuli is the PAG
  • PAG receives input from the cortex, limbic
    system, hypothalamus, and PSTT.
  • The hypothalamus sends ß-endorphins via neurons
    to the PAG
  • Here they are routed to the nucleusmagnocellularie
    s of the rostral medulla that descends laterally
    to the dorsal horn.
  • Another descending control system arises form the
    nucleus raphae magnus in the upper medulla
  • Descending axons from this region of the brain
    track down to the lower medulla and the spinal
    cord, where they release serotonin at their
    terminal end, producing analgesia at laminae I,
    II, and V.

30
  • The notion of central control and descending
    inhibition of pain is based on the bodys ability
    to use and produce various forms of endogenous
    opiates.
  • Each having a distinct function and a specific
    receptor affinity.
  • The enkephalins are found throughout the central
    nervous system, but particularly in the dorsal
    horn.
  • Thus, the aggregation of noxious stimuli may
    cause both presynaptic and postsynaptic control
    of nociception in the dorsal horn via enkephalin
    release

31
  • Dynorphins are primarily located in laminae I
    5, making it feasible for them to inhibit pain.
  • Levels of dynorphin ? in laminae I 5 during
    periods of hyperstimulation.
  • However, their rapid degradation limits their
    role in long-term pain reduction.
  • During periods of intense noxious input,
    ß-endorphins are released and provide temporary
    inhibition to noxious stimulation.
  • This concept is based on their location in the
    PAG and the idea that their release would block
    interneuron interaction.

32
Review of the process of Pain Transmission
  • Much decision making in the tx of pain can be
    based on the understanding of the physiological
    and chemical interaction that occurs after
    trauma.
  • In simple terms, pain transmission appears to be
    fairly straightforward.
  • The acute pain response is initiated when
    substances are released form injured tissues,
    causing a noxious stimulus to be transmitted via
    A-delta and C fiber to the dorsal horn

33
  • Once in the dorsal horn, the stimulus is
    transmitted to the higher brain centers via the
    STT, which bifurcates into 2 tracts.
  • The impulse is propagated via the NSTT to the
    thalamus and then to the cortex, where
    discrimination and location of the stimulus are
    assessed.
  • At the same time, noxious stimulation is
    projected upward toward the RF, the PAG matter,
    the hypothalamus, and the thalamus via the PSTT
  • Neurons in the thalamus send axon projections to
    the limbic system and the cortex.
  • Once the noxious stimuli have reached the higher
    centers of the brain, the descending control
    mechanisms are activated, the incoming noxious
    stimuli can be inhibited at various levels, and
    endogenous opiates can be released.

34
Pain Theory Historical Perspectives
  • Theories regarding the cause, nature, and purpose
    of pain have been debated since the dawn of
    humankind.
  • Most early theories were based on the assumptions
    that pain was related to a form of punishment.
  • The word pain is derived from the Latin word
    poena meaning fine, penalty, or punishment.

35
  • The ancient Greek believed that pain was
    associated with pleasure because the relief of
    pain was both pleasurable and emotional.
  • Aristotle reassessed the theory of pain and
    declared that the soul was the center of the
    sensory processes and that the pain system was
    located in the heart

36
  • The Romans, coming closer to contemporary
    thought, viewed pain as something that
    accompanied inflammation.
  • In the 2nd century, Galen offered the Romans his
    works on the concepts of the nervous system.
  • However, the views of Aristotle weathered the
    winds of time.
  • In the 4th century, successors of Aristotle
    discovered anatomic proof that the brain was
    connected to nervous system
  • Despite this, Aristotles belief prevailed until
    the 19th century, when German scientist provided
    irrefutable evidence that the brain is involved
    with sensory and motor function

37
Specificity Theory of Pain Modulation
  • Modern concepts of pain theory continue to
    advance from the ideas of Aristotle.
  • However, controversy still exists as to which
    theories are correct.
  • The theories accepted at the turn of the century
    were the specificity theory and the pattern
    theory, two completely different and seemingly
    contradictory views

38
  • The specificity theory suggests that there is a
    direct pathway from peripheral pain receptors to
    the brain.
  • The pain receptors are located in the skin and
    are purported to carry pain impulses via a
    continuous fiber directly to the brains pain
    center
  • The pathway includes the peripheral nerves, the
    lateral STT in the spinal cord and the
    hypothalamus (the brains pain center)
  • This theory was examined and refuted using
    clinical, psychological, and physiological
    evidence by Melzack and Wall in 1965.
  • They discussed clinical evidence describing pain
    sensations in severe burn patients, amputee
    patients, and patients with degenerative nerve
    disease.

39
  • These syndromes do not occur in a fixed, direct
    linear system
  • Rather in the quality and quantity of the
    perceived pain are directly related to a
    psychological variable and sensory input.
  • This theory had been previously addressed by
    Pavlov, who inflicted dogs with a painful
    stimulus, then immediately gave them food.
  • The dogs eventually responded to the stimulus as
    a signal for food and showed no responses to the
    pain

40
  • The psychological aspect of pain perception was
    later addressed by Beecher, who studied 215
    soldiers seriously wounded in the Battle of
    Anzio, finding that only 27 requested
    pain-relieving medication (Morphine).
  • When the soldiers were asked if they were
    experiencing pain, almost 60 indicated that they
    suffered no pain or only slight pain, and only
    24 rated the pain as bad.
  • This was most surprising because 48 of the
    soldiers had received penetrating abdominal
    wounds.
  • Beecher also noted that none of the men were
    suffering from shock or were insensitive to pain
    because inept intravenous insertions resulted in
    complaints of acute pain.

41
  • The conclusion was drawn that the pain
    experienced by these men was blocked by emotional
    factors.
  • The physical injuries that these men had received
    was an escape from the life-threatening
    environment of battle to the safety of a
    hospital, or even release form the war.
  • This relationship suggests that it is possible
    for the central nervous system to intervene
    between the stimulus and the sensation in the
    presence of certain psychological variables.
  • No physiological evidence has been found to
    suggest that certain nerve cells are more
    important for pain perception and response than
    others therefore, the specificity theory can be
    discounted.

42
Contemporary Pain Control Theories
  • Although both the specificity and pattern
    theories of pain transmission were eventually
    refuted, they did provide some lasting principles
    that are still present in contemporary pain
    modulation theories
  • The strengths of these 2 theories, plus findings
    obtained through additional research, were
    factored together to for the basis of the current
    perspective regarding pain transmission and pain
    modulation.
  • Still, there is much to be learned and studied
    before the exact mechanisms of pain transmission
    and perception are understood.

43
Next time
  • Gate control theory
  • Levels Theory of pain control
  • Assessment of pain
  • Visual analogue scale
  • McGill pain questionaire
  • Submaximal effort tourniquet test
  • Placebo effect
  • Referred pain
  • Chronic Pain
  • Pain management techniques
  • Chapter 3 Development and delivery of treatment
    protocol

44
Pattern Theory of Pain
  • States that there are no specialized receptors in
    the skin.
  • Rather, a single generic nerve responds
    differently to each type of sensation by creating
    a uniquely coded impulse formed by a
    spatiotemporal pattern involving the frequency
    and pattern of nerve transmission.

45
  • An analysis of the words elements
  • Spatio- the distance between the nerves
    impluses
  • temporal- the frequency of the transmission
  • An example of this type of coding can be found
    with most institutional phone systems.
  • A call from inside a university has a different
    ring from an outside call.
  • Although this theory was closer to being
    neurological correct there were still
    shortcomings
  • Melzack and Wall refuted this theory as well,
    based on the physical evidence of physiological
    specialization of receptor-fiber units.
  • Plus this theory failed to account for the brains
    role in pain perception.

46
Gate Control Theory
  • Implies a non-painful stimulus can block the
    transmission of a noxious stimulus.
  • Is based on the premise that the SG, located in
    the dorsal horn of the spinal cord, modulates the
    afferent nerve impulses.
  • This then influences the first central
    transmission (T) cells, which corresponds with
    the NSTT or the PSTT and activate a central
    control triggering the mechanisms responsible for
    the response and perception of pain.

47
  • The SG acts as a modulating gate or a control
    system between the peripheral nerve fibers and
    central cells that permits only one type of never
    impulse (pain or no pain) to pass through.
  • Serving in a capacity similar to that of a
    switch operator in a railroad yard, the SG
    monitors the amount of activity occuring on both
    incoming tracts in a convergent system
  • Opening and closing the gate to allow the
    appropriate information to be passed along to the
    T cell.
  • Impulses traveling on the fast, nonpain fibers ?
    activity in the SG.
  • Impulses on the slower pain fibers exert an
    inhibitory influence.
  • When the SG is active, the gate is in its
    closed position and a nonpainful stimulus is
    allowed to pass on to the T cell.

48
  • Example
  • Bumping the head
  • The initial trauma activates the A-delta and,
    eventually, C fibers
  • Rubbing the traumatized area stimulates the
    A-beta fibers, which activate the SG to close the
    spinal gate
  • Thus inhibiting transmission of the painful
    stimulus

49
Assessment of pain
  • Visual analogue scale
  • Picture
  • McGill pain questionnaire
  • Part I is used to localize the pain and identify
    whether the perceived source of the pain is
    superficial (external), internal, or both.
  • Part II incorporates the VAS that was described
    in the visual analogue scale.
  • Part III is the pain rating index, a collection
    of 76 words grouped into 20 categories. Patients
    are to underline or circle the words in each
    group that describes the sensation of pain being
    experienced.
  • Groups 1-10 somatic in nature
  • Groups 11-15 affective
  • Group 16 evaluative
  • Group 17-20 miscellaneous words that are used on
    in the scoring process.

50
Scoring
  • Add up the total number of words chosen, up to
    the maximum of 20 words (one for each category)
  • The level of intensity of pain is determined by
    the value assigned to each word.
  • 1st word 1 point
  • 2nd word 2 point
  • And so on
  • Pt could have a high score of 20, but have a
    low-intensity score by selecting the 1st word in
    each category.

51
Submaximal Effort Tourniquet Test
  • In 1966, Smith et al described a method of
    matching a patients pain using a SETT.
  • The SETT is performed by inflating a BP cuff to
    above systolic pressure on the pt elevated arm.
  • Once the cuff is inflated, the pt is instructed
    to open and close the hand or fist rhythmically.
  • A handgrip dynamometer and a metronome can be
    used for standardization.
  • The pt should continue opening and closing the
    hand or fist until the cramping sensation that he
    or she feels matches the pain from the
    original pathology.
  • The amount of time that elapses form onset to
    fruition of matched pain is the recorded
    objective measure.
  • The SETT can be repeated at every tx session to
    gauge tx progress and is effective in matching
    all types of pain

52
Placebo Effect
  • Placebo stems from the Latin word for I shall
    please
  • Used to describe pain reduction obtained from a
    mechanism other than those related to the
    physiological effects of the tx.
  • Linked to psychological mechanisms
  • All TM have some degree of placebo effect
  • Most studies involving TM involving the use of a
    sham TM (ultrasound set at the intensity of 0)
    and an actual treatment have shown ? levels of
    pain in each group.

53
Referred pain
54
Chronic Pain
  • Characteristics of
  • Symptoms last longer than 6 months
  • Few objective medical findings
  • Medication abuse
  • Difficulty sleeping
  • Depression
  • Manipulative behavior
  • Somatic preoccupation

55
Pain Management Techniques
  • Physical measures
  • Behavioral and cognitive measures

56
On to Chapter 3
  • Development and Delivery of Treatment Protocol

57
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