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Learning Objectives: You should be able to:

• Draw a generalized diagram of how information flows to and from the central nervous system for the state-dependent regulation of breathing.
• List the paticipant nuclei in the brain stem responsible for the rhythmic and coordinated act of automatic breathing.
• Identify ten mechanoreceptor reflexes that alter the respiratory pattern to overcome various perturbances to normal breathing.
• Explain the protective role of peripheral and central chemoreceptors in normal breathing and pathological situations.

Neural Organization       Respiratory Controller      Mechanoreflexes      Chemoreflexes     MainMenu

General Neural Organization

1. Overview
   • breathing is a coordinated act which is subjected to many feedforward and feedback controls
   • the system has a hierarchical neural organization with involuntary and voluntary components
   • PaCO2 seems to be the regulated variable, but blood gas values of carbon dioxide fluctuate widely within normal, healthy individuals
2. Major Components of the Respiratory System
   • respiratory controllers
     • higher center feed-forwards (voluntary)
     • brainstem (automatic)
     • spinal cord 32
   • respiratory effectors
     • respiratory muscles
     • chest wall and lung
   • respiratory outputs
     • alveolar ventilation
     • blood gas tensions
   • respiratory sensors
     • mechanical feedbacks
     • chemical feedbacks
3. Cortical Influences
   • phonation and articulation
   • maximum voluntary ventilation
   • breathholding
   • central hypoventilation syndrome ("Ondine's Curse")
     • failure of automatic respiratory control when asleep
     • auxiliary ventilatory support is usually indicated
4. Abnormal Respiratory Patterns (Fig. 33)
   • mechanical or vascular damage to the CNS can result in ominous breathing patterns
     • apneusis: rostral pontine damage
     • gasping: extensive pontine damage, severe hypoxia
     • Cheyne-Stokes respiration (spindle pattern): poor brain stem perfusion
     • Biot breathing (cluster pattern): pontine malfunction
     • Kussmaul: metabolic acidosis
     • apnea: high cervical cord or extensive medullary damage

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Central Respiratory Controller

1. Nucleus Tractus Solitarius (NTS, dorsomedial medulla)
   • I responsible for phrenic motoneuron activation
   • I� responsible for vagal afferent integration
2. Nucleus Ambiguus (NA, ventrolateral, middle medulla)
   • motor I cells that activate upper airway musculature (larynx, pharynx)
3. Nucleus Retroambigualis (NRA, ventrolateral, caudal medulla)
   • premotor I cells (rostral) that activate external intercostal motoneurons
   • premotor E cells (caudal) that activate internal intercostal motoneurons
4. Nucleus Parabrachialis Medialis (NPBM, dorsolateral pons)
   • tonic discharging cells inhibitory to I� cells of inspiration
   • commonly known as the pneumotaxic center
5. Pre-B� tzinger Complex (pBOT, ventrolateral, rostral medulla)
   • pacemaker I neurons responsible for generating respiratory rhythm

   Neural Organization       Respiratory Controller      Mechanoreflexes      Chemoreflexes     MainMenu

Mechanoreflexes and Breathing

1. Vagal reflexes from the lungs
   • slowly adapting pulmonary stretch receptors
     • location: nerve filaments in smooth muscles of trachea and bronchi
     • stimulation: lung inflation (static volume detector)
     • reflex response: termination of inspiration (Hering-Breuer reflex)
   • rapidly adapting irritant receptors
     • location: unmyelinated nerve filaments in the epithelium of larynx, trachea, & extra pulmonary bronchi
     • stimulation: noxious irritants, distortion of larynx, large lung inflations & deflations, pneumothorax
     • reflex responses: cough, hyperventilation, bronchoconstriction
   • pulmonary C-fiber receptors
     • location: unmyelinated fibers in the alveolar wall
     • stimulation: vascular engorgement, interstitial edema fluid formation
     • reflex response: rapid shallow breathing, large airway constriction, bradycardia
   • bronchial C-fiber receptors
     • location: unmyelinated fibers in blood vessel walls of the bronchial circulation
     • stimulation: vascular congestion, chemical injury, microemboli
       • reflex responses: like pulmonary C-fiber receptor responses, sensation of dyspnea?
2. Reflexes from the Upper Airways
   • nasal passage receptors
     • location: nasal air passages
     • afferent pathway: trigeminal nerve
     • stimulation: mechanical or chemical irritation
     • reflex response: sneeze, bradycardia
   • larynx and tracheo-bronchial receptors
     • location: large upper airways
     • afferent pathway: vagus nerve, superior laryngeal nerve
     • stimulation: mechanical or chemical irritation
     • reflex response: cough, wide swings in blood pressure, Valsalva
   • pharynx receptors
     • location: receptors in the walls of the common air-food passageway
     • afferent pathway: vagus nerves, glossopharyngeal nerves
     • stimulation: peristaltic wave during swallowing
     • reflex response: closure of glottis
   • other reflexes of unknown origin
     • hiccup (dry food, misplaced cardiac pacemaker)
     • yawning (sleepiness, boredom, intracranial disease)
     • sighing (periodic deep inspiration every 15 to 30 sec)
3. Spinal Cord Reflexes
   • muscle spindle receptors (somatic afferents to thoracic spinal cord
     • location: intercostal musculature (very few muscle spindles in diaphragm)
     • afferent pathway: somatic afferents to thoracic spinal cord
     • stimulation: low total compliance
     • reflex response: additional respiratory muscle activation to overcome low compliance
   • nociceptive pain receptors
     • location: bare nerve endings in viscera, muscles, bone
     • afferent pathway: visceral and somatic afferents
     • stimulation: ischemia, bodily injury
     • reflex response: gasp, excited breathing, hypoventilation, apnea
   • joint receptors
     • location: joints of arms, legs, feet
     • afferent pathway: somatic afferents to spinal cord
     • stimulation: joint motion in exercise
     • reflex response: increased frequency and volume of breathing

Neural Organization       Respiratory Controller      Mechanoreflexes      Chemoreflexes     MainMenu

Chemoreflexes and Breathing

1. Location of Chemoreceptors
   • chemoreceptors are located exclusively on the arterial side of the circulation
     • peripheral chemoreceptors: aortic and carotid bodies sense
       •  PaO2
     • central chemoreceptors: chemosensitive zone of medulla sense
       •  PaCO2
   • there are no venous chemoreceptors that "taste" the venous blood
   • there are no airway chemoreceptors that "smell" the alveolar air
2. CO2 Response Curve (Fig. 35)
   • minute volume (V E = frequency (f) * tidal volume (VT)
   • V E is a sigmoidal function of inspired PiCO2
   • CO2 sensitivity = slope of plot over 5%-7% range (6 L/min per %CO2)
     • CO2 sensitivity decreases in sleep and presence of drugs
   • maximal CO2 responsivity is about 60% of maximum voluntary ventilation
3. O2 Response Curve (Fig. 36)
   • minute volume (V E) = frequency (f) * tidal volume (VT)
   • V E is a hyperbolic function of inspired PiO2 (mm Hg)
   • O2 response threshold: region where V E increases more steeply with
     •  PaO2 (�70 mm Hg)
     • normal PaO2 of 95 mm Hg is below its threshold (indirectly regulated)
   • O2 chemoreceptor threshold: region where receptors start discharging
     • with  PaO2 (�350 mm Hg)
     • receptors are discharging at PaO2 of 95 mm Hg, but they have no ventilatory effect
4. Ventilation and Integration of Chemoreceptor Inputs
   • respiratory neurons of the brainstem possess no inherent chemosensitivity to low O2
   • ventilatory outputs depend upon intact central and peripheral chemoreceptor afferent projections to respiratory nuclei of medulla and pons
   • peripheral chemoreceptors primarily respond to low PaO2 (< 70 mm Hg)
     • aortic bodies and carotid bodies
     • peripheral chemoreceptors can respond secondarily to  PaCO2 and  [H+]
   • central chemoreceptors can respond to elevated PaCO2 and/or elevated [H+]
     • central receptors are embedded within ventrolateral surface of medulla
     • CO2 crosses blood-brain barrier very quickly
     • H+ crosses blood-brain barrier very slowly
     • cerebral spinal fluid buffers response (pH = 7.32)
   • central and peripheral chemoreceptor inputs mutually potentiate each other
   • peripheral chemoreceptors protect the central nervous system against global hypoxia and neuronal depression

   Neural Organization       Respiratory Controller      Mechanoreflexes      Chemoreflexes     MainMenu

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