17- Control of Breathing Flashcards
3 major parts of the respiratory control system
- Controller: neurons in brainstem that send signals to the respiratory muscles
- there are multiple sites in the brainstem that have some role in the control for breathing. either in rhythm generation, pattern generation, or chemoreception - Effector: components of the system that carry out gas exchange processes (muscles/lungs)
- Sensor elements: provide feedback and excitatory input (levels of PO2 and PCO2 that are registered by chemoreceptors)
Respiratory Controllers
- rhythm generator
- timing
- neurons in brainstem (intrinsic oscillator with info from neuromodulators, temp, exercise, etc.) provides trigger or signal that initiates the respiratory cycle
- activates pattern generating neurons which provide proper sequential activation of respiratory pump and airway motoneurons - pattern formation
- shaping
- starts muscle contractions (pump motorneurons in spinal cord and resistance motor neurons in crania) - pre-motor neurons
- integration - motoneurons
- motor output (activating respiratory muscles)
Central pattern generator and motoneurons
Prototypical pattern generator
- activates motoneurons in consistent sequence
- motoneurons discharge in a consistent pattern
phrenic nerve
activates the diaphragm
thoracic nerve
activates external intercostal muscles
nerves/muscles during inspiration and expiration
INSPIRATION
- Phrenic nerve activates diaphragm
- thoracic nerve activates external intercostal muscles
EXPIRATION
-thoracic nerve activation of internal intercostal muscles occurs
what occurs when the diaphragm gets activated?
esophageal pressure decreases which results in inspiratory airflow to increase inspiratory volume
what happens to frequency and tidal volume of breathing when you lesion above the brainstem (separate brainstem from rest of brain)
neither change
- respiratory rhythm and pattern were not affected
- suggesting that more rostral sites are not critical for breathing
what happens to frequency and tidal volume of breathing when you lesion in the pons
slowed breathing and increased tidal volume (something to shut off inspiration was messed up)
-neurons within medulla and pons regulate breathing
what happens to frequency and tidal volume of breathing when you lesion between the pons and medulla
breathing becomes irregular
-neurons within medulla and pons regulate breathing
what happens to frequency and tidal volume of breathing when you lesion between the medulla and the spinal cord
- breathing completely stopped
- minimum substrate for breathing was rostral to the spinal cord
Vagus Nerve and breathing control
important determinant of respiratory rhythm and pattern
Pre-Botzinger Complex
-critical site for respiratory
rhythm generation.
-respiratory frequency ceased after the caudal border of this area was lesioned.
explain the plasticity of rhythm generating mechanisms
Weekly neurotoxin preBötC injections
- Progressive increasing doses
- Incrementally totally destroyed the pre-BötC.
- Within a day after each injection, breathing was normal.
Respiratory control system is highly “plastic” because if given time for “remodeling”, breathing is normalFigure 7 without the preBötC.
How does rhythm generator work?
Neurons active in different phases of respiratory cycle
-individual brainstem respiratory neurons active in one of three phases (inspiration, late inspiration, expiration)
