4@neaural control of respiration
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About This Presentation
anatomy and physiology. neural control of respiration
Slide Content
CONTROL OF RESPIRATION
QAP20803
DR. MOHANAD
QAP20803
DR. MOHANAD
Neural Control of Ventilation
Goals of regulation of ventilation is to
keep arterial levels of O
2& CO
2constant
The nervous system adjusts the level of
ventilation (RR & TV) to match perfusion
of the lungs (pulmonary blood flow)
By matching ventilation with pulmonary
blood flow (CO) we also match ventilation
with overall metabolic demand
Goals of regulation of ventilation is to
keep arterial levels of O
2& CO
2constant
The nervous system adjusts the level of
ventilation (RR & TV) to match perfusion
of the lungs (pulmonary blood flow)
By matching ventilation with pulmonary
blood flow (CO) we also match ventilation
with overall metabolic demand
Neural
Control Of
Breathing
Voluntary
Cerebral
cortex
Autonomic
Medullary
Centers
Dorsal
Respiratory
Group
Ventral
Respiratory
Group
Pontine
Centers
Pneumotaxic
Center
Apneustic
Center
Control Of
Breathing
Voluntary
Cerebral
cortex
Autonomic
Medullary
Centers
Dorsal
Respiratory
Group
Ventral
Respiratory
Group
Pontine
Centers
Pneumotaxic
Center
Apneustic
Center
Control of Respiration
Respiration is controlled by areas of the brain
that stimulate the contraction of the diaphragm
and the intercostal muscles.
These areas, collectively called
RESPIRATORY CENTERS
Respiration is controlled by areas of the brain
that stimulate the contraction of the diaphragm
and the intercostal muscles.
These areas, collectively called
RESPIRATORY CENTERS
Diagram showing the pons and medulla oblongata
Respiratory Center
The Respiratory Center is
composed of several groups
of neurons located bilaterally
in the medulla oblongata
and pons of the brain stem.
It is divided into :
1.Dorsal Respiratory Group
2.Ventral Respiratory Group
3.Pneumotaxic Center
4.Apneustic Center
The Respiratory Center is
composed of several groups
of neurons located bilaterally
in the medulla oblongata
and pons of the brain stem.
It is divided into :
1.Dorsal Respiratory Group
2.Ventral Respiratory Group
3.Pneumotaxic Center
4.Apneustic Center
8
Respiratory Centers
Respiratory Centers
To larynx and bronchi
To respiratory muscles
Pontine center
Dorsal Respiratory Group
Brainstem Respiratory Centres
Pons
Medulla
Ventral respiratory group
-Nucleus ambiguus
-Nucleus retroambigualis
To respiratory muscles
Pontine center
Dorsal Respiratory Group
Brainstem Respiratory Centres
Pons
Medulla
Ventral respiratory group
-Nucleus ambiguus
-Nucleus retroambigualis
Respiratory Center
Medullary Respiratory Centers
Dorsal respiratory group-DRG-Inspiratory area-
Ventral respiratory group-VRG-Expiratory &
inspiratory area
Pons Respiratory centers
Pontine respiratory group –(Pneumotaxic area),
Apneustic Center
Medullary Respiratory Centers
Dorsal respiratory group-DRG-Inspiratory area-
Ventral respiratory group-VRG-Expiratory &
inspiratory area
Pons Respiratory centers
Pontine respiratory group –(Pneumotaxic area),
Apneustic Center
Neural control of ventilation
Dorsal respiratory group
located primarily in the nucleus tractus
solitariusin medulla
Sets the basic drive of ventilation
Termination of CN IX & X (G.ph, VagusN.)
Receives input from:
Peripheral chemoreceptors
Baroreceptors
Receptors in the lungs
Rhythmically self excitatory
Ramp signal
Excites muscles of inspiration
Dorsal respiratory group
located primarily in the nucleus tractus
solitariusin medulla
Sets the basic drive of ventilation
Termination of CN IX & X (G.ph, VagusN.)
Receives input from:
Peripheral chemoreceptors
Baroreceptors
Receptors in the lungs
Rhythmically self excitatory
Ramp signal
Excites muscles of inspiration
Dorsal respiratory group
INSPIRATORY CENTER
When fired they generates
rhythmic nerve impulses that travel
along the phrenic nerveto
diaphragm and intercostal nerves
to excite external intercostal
muscles
As a result, these muscles will
contract and the thorax expand,
Volume increase
Pressure decrease
Air pushes into lungs
INSPIRATORY CENTER
When fired they generates
rhythmic nerve impulses that travel
along the phrenic nerveto
diaphragm and intercostal nerves
to excite external intercostal
muscles
As a result, these muscles will
contract and the thorax expand,
Volume increase
Pressure decrease
Air pushes into lungs
Dorsal Respiratory
Group
DRG then becomes dormant,
and expiration occurs passively
as the inspiratory muscle relax
and the lungs recoil.
This cyclic activity of the
inspiratory neurons repeats and
produce respiratory rate of 12 –
15 breaths per minute
Group
DRG then becomes dormant,
and expiration occurs passively
as the inspiratory muscle relax
and the lungs recoil.
This cyclic activity of the
inspiratory neurons repeats and
produce respiratory rate of 12 –
15 breaths per minute
Ventral Respiratory
Group
VRG contain mix of neurons
Inspiratory
Expiratory (mainly)
The VRG is responsible for motor
control of inspiratory and expiratory
muscles during exercise.
Inactive during normal respiration
They are especially important in
providing the powerful expiratory
signals to the abdominal muscles
during very heavy expiration
Group
VRG contain mix of neurons
Inspiratory
Expiratory (mainly)
The VRG is responsible for motor
control of inspiratory and expiratory
muscles during exercise.
Inactive during normal respiration
They are especially important in
providing the powerful expiratory
signals to the abdominal muscles
during very heavy expiration
Pontine Respiratory
Center
Ponscontains 2 centres
for control of
respiration:
1.Pneumotaxic Center
2.Apneustic Center
Center
Ponscontains 2 centres
for control of
respiration:
1.Pneumotaxic Center
2.Apneustic Center
Pontine respiratory
group
A collection of neurons in the
reticular formation within the Pons
Pneumotaxic center
a network of neurons in the rostral
dorsal lateral Pons
Effectively decreasing the tidal volume
and regulating the respiratory rate.
Absence of the PRG results in an
increase in depth of respiration and a
decrease in respiratory rate
group
A collection of neurons in the
reticular formation within the Pons
Pneumotaxic center
a network of neurons in the rostral
dorsal lateral Pons
Effectively decreasing the tidal volume
and regulating the respiratory rate.
Absence of the PRG results in an
increase in depth of respiration and a
decrease in respiratory rate
Neural control of ventilation
Apneustic center (lower pons)
Functions to prevent inhibition of DRG under some
circumstances
This center increasesdepth of inspiration (tidal
volume ) by acting directly on the inspiratory
center.
If damaged it will lead to arrest of
breathing in inspiration
Apneustic center (lower pons)
Functions to prevent inhibition of DRG under some
circumstances
This center increasesdepth of inspiration (tidal
volume ) by acting directly on the inspiratory
center.
If damaged it will lead to arrest of
breathing in inspiration
The “apneustic centre”
Apneustic centre
Impulses from
these neurones
excite
inspiratory
areaof
medulla
Prolong inspiration
Conclusion?
Rhythmgenerated in
medulla
Rhythmcan be modified
by inputs from pons
Apneustic centre
Impulses from
these neurones
excite
inspiratory
areaof
medulla
Prolong inspiration
Conclusion?
Rhythmgenerated in
medulla
Rhythmcan be modified
by inputs from pons
Neuralcontrol
Afferents from higher centers:
1. Cerebral cortex: voluntary control of respiration.(
Ondine curse)
2.Cerebellum: coordination with swallowing and talking
3.Hypothalamus: increased resp, with high temp.
4. Limbic system: pain and emotional stimuli affect resp.
Afferents from higher centers:
1. Cerebral cortex: voluntary control of respiration.(
Ondine curse)
2.Cerebellum: coordination with swallowing and talking
3.Hypothalamus: increased resp, with high temp.
4. Limbic system: pain and emotional stimuli affect resp.
Chapter 22, Respiratory System 21
Medullary Respiratory Centers
Medullary Respiratory Centers
Neural Control of Ventilation
Herring-Breuer Inflation reflex
stretch receptors located in wall of airways
+ when stretched at tidal volumes > 1500 ml
Inhibits the DRG Increased or decrease
respiratory rate ?????
Irritant receptors-among airway epithethium
+ sneezing & coughing & possibly airway
constriction
J receptors -in alveoli next to pulmonary caps.
Stimulated by hyperinflation and chemicals (pulmonary
chemoreflex) Mechanoreceptors
Herring-Breuer Inflation reflex
stretch receptors located in wall of airways
+ when stretched at tidal volumes > 1500 ml
Inhibits the DRG Increased or decrease
respiratory rate ?????
Irritant receptors-among airway epithethium
+ sneezing & coughing & possibly airway
constriction
J receptors -in alveoli next to pulmonary caps.
Stimulated by hyperinflation and chemicals (pulmonary
chemoreflex) Mechanoreceptors
1) Impulses from higher centers: impulses
from higher center can stimulate or inhibit
respiratory centers directly.
2) Impulses from stretch receptors of lung
from higher center can stimulate or inhibit
respiratory centers directly.
2) Impulses from stretch receptors of lung
Factors influencing the Respiratory center
of the brain
Pulmonary irritant reflexes
Receptors in the lung that respond to irritants
Activation of irritant receptors
Send signals to respiratory centers through vagal nerve
Modify respiratory rate and depth
of the brain
Pulmonary irritant reflexes
Receptors in the lung that respond to irritants
Activation of irritant receptors
Send signals to respiratory centers through vagal nerve
Modify respiratory rate and depth
Inflation of the lungs →+pulmonary stretch
receptor →+vagus nerve →-medually
inspiratory neurons →+eliciting expiration
receptor →+vagus nerve →-medually
inspiratory neurons →+eliciting expiration
Factors influencing the Respiratory center of
the brain
Influence of higher brain centers
Hypothalamic controls
Activation of sympathetic centers in hypothalamus
Send signals to respiratory centers
Modify respiratory rate and depth
the brain
Influence of higher brain centers
Hypothalamic controls
Activation of sympathetic centers in hypothalamus
Send signals to respiratory centers
Modify respiratory rate and depth
Factors influencing the respiratory
center of the brain
Influence of higher brain centers
Cortical controls -Voluntary controls
Cerebral motor cortex
Send signals to motor neurons
Stimulate respiratory muscles
(Bypassing the medullary center)
center of the brain
Influence of higher brain centers
Cortical controls -Voluntary controls
Cerebral motor cortex
Send signals to motor neurons
Stimulate respiratory muscles
(Bypassing the medullary center)
CHEMORECEPTORS
Central chemoreceptors
Located in bilaterally in medulla
Sensitive to the pH extracellular fluid(ECF):
Cerebrospinal fluid(CSF)
Peripheral chemoreceptors
Located in great vessels of neck
Sensitive to PO
2, PCO
2and pH
Central chemoreceptors
Located in bilaterally in medulla
Sensitive to the pH extracellular fluid(ECF):
Cerebrospinal fluid(CSF)
Peripheral chemoreceptors
Located in great vessels of neck
Sensitive to PO
2, PCO
2and pH
Chemical Control of Ventilation
Central chemoreceptors
Chemosensitive area of respiratory center
Hydrogen ions-primary stimulus but can’t
cross membranes (blood brain barrier-BBB)
carbon dioxide-can cross BBB
inside cell converted to H+
rises of CO2 in CSF-effect on + ventilation faster
due to lack of buffers compared to plasma
unresponsive to falls in oxygen-hypoxia
depresses neuronal activity
70-80 % of CO2 induced increase in vent.
Central chemoreceptors
Chemosensitive area of respiratory center
Hydrogen ions-primary stimulus but can’t
cross membranes (blood brain barrier-BBB)
carbon dioxide-can cross BBB
inside cell converted to H+
rises of CO2 in CSF-effect on + ventilation faster
due to lack of buffers compared to plasma
unresponsive to falls in oxygen-hypoxia
depresses neuronal activity
70-80 % of CO2 induced increase in vent.
Chemical Control of Breathing
31
31
32
Changing P
CO2levels are monitored by
chemoreceptors of the brain stem
Carbon dioxide in the blood diffuses into the
cerebrospinal fluid where it is hydrated
Resulting carbonic acid dissociates, releasing
hydrogen ions
P
CO2levels rise (hypercapnia) resulting in
increased depth and rate of breathing
Depth and Rate of Breathing: P
CO2
Changing P
CO2levels are monitored by
chemoreceptors of the brain stem
Carbon dioxide in the blood diffuses into the
cerebrospinal fluid where it is hydrated
Resulting carbonic acid dissociates, releasing
hydrogen ions
P
CO2levels rise (hypercapnia) resulting in
increased depth and rate of breathing
Depth and Rate of Breathing: P
CO2
Increase in CO
2increases
H
+
concentration in CSF
(CO2 + H2O in CSF H
2CO
3HCO
3
–
+ H
+)
Stimulates H
+
receptors
Stimulates
RESPIRATORY
CENTERS
Increases rate and
depth of breathing
Fall in blood CO
2slightly depresses shallow breathing
2increases
H
+
concentration in CSF
(CO2 + H2O in CSF H
2CO
3HCO
3
–
+ H
+)
Stimulates H
+
receptors
Stimulates
RESPIRATORY
CENTERS
Increases rate and
depth of breathing
Fall in blood CO
2slightly depresses shallow breathing
Chemical Control of Ventilation
Peripheral Chemoreceptors
Aortic and Carotid bodies
20-30% of CO2 induced increase in vent.
Responsive to hypoxia
response to hypoxia is blunted if CO2 falls as the
oxygen levels fall
responsive to slight rises in CO2 (2-3 mmHg)
but not similar falls in O2
sensitivity altered by CNS
SNS decreasing flow-increased sensitivity to hypoxia
Peripheral Chemoreceptors
Aortic and Carotid bodies
20-30% of CO2 induced increase in vent.
Responsive to hypoxia
response to hypoxia is blunted if CO2 falls as the
oxygen levels fall
responsive to slight rises in CO2 (2-3 mmHg)
but not similar falls in O2
sensitivity altered by CNS
SNS decreasing flow-increased sensitivity to hypoxia
Cells sensitive to arterial PO
2
are found in:
Peripheral chemoreceptors:
Aortic bodies
In arch of aorta
Carotid bodies
In common carotid artery
2
are found in:
Peripheral chemoreceptors:
Aortic bodies
In arch of aorta
Carotid bodies
In common carotid artery
Peripheral chemoreceptors
Carotid chemoreceptors:
Near carotid bifurcation. It has two types
of cells 1&11.
Impulses carried by the glossopharyngeal
nerve & carotid sinus to the medulla.
More sensitive to drop of O2 by type 1 cells.
Type 1 cells contain dopamine which is released
in response to low O2.
Carotid chemoreceptors:
Near carotid bifurcation. It has two types
of cells 1&11.
Impulses carried by the glossopharyngeal
nerve & carotid sinus to the medulla.
More sensitive to drop of O2 by type 1 cells.
Type 1 cells contain dopamine which is released
in response to low O2.
Other receptors
1.Nose and upper airway
2.Joint and muscle
3.Gamma system
4.Arterial baroreceptors
5.Pain and temperature
1.Nose and upper airway
2.Joint and muscle
3.Gamma system
4.Arterial baroreceptors
5.Pain and temperature
Factors influencing the respiratory center of
the brain
Chemical factors:
Oxygen (O
2)
Carbon dioxide (CO
2)
Hydrogen ion (H
+
)
Sensed by CHEMORECEPTORS
the brain
Chemical factors:
Oxygen (O
2)
Carbon dioxide (CO
2)
Hydrogen ion (H
+
)
Sensed by CHEMORECEPTORS
Influence of PCO
2 and H
+
Most potent and most
closely controlled
Sensed by central
chemoreceptors
35-45 mm Hg
The normal PaCO2 (arterial partial pressure
of carbon dioxide in the blood) is
40mmHg. There is a normal range, which
is 35-45mmHg.
2 and H
+
Most potent and most
closely controlled
Sensed by central
chemoreceptors
35-45 mm Hg
The normal PaCO2 (arterial partial pressure
of carbon dioxide in the blood) is
40mmHg. There is a normal range, which
is 35-45mmHg.
Chapter 22, Respiratory System 42
Depth and Rate of Breathing: P
CO2
Figure 22.26
Depth and Rate of Breathing: P
CO2
Figure 22.26
43
Hypothalamic controls act through the limbic
system to modify rate and depth of
respiration
Example: breath holding that occurs in anger
A rise in body temperature acts to increase
respiratory rate
Cortical controls are direct signals from the
cerebral motor cortex that bypass medullary
controls
Examples: voluntary breath holding, taking a
deep breath
Depth and Rate of Breathing: Higher
Brain Centers
Hypothalamic controls act through the limbic
system to modify rate and depth of
respiration
Example: breath holding that occurs in anger
A rise in body temperature acts to increase
respiratory rate
Cortical controls are direct signals from the
cerebral motor cortex that bypass medullary
controls
Examples: voluntary breath holding, taking a
deep breath
Depth and Rate of Breathing: Higher
Brain Centers
44
Hyperventilation –increased depth and rate
of breathing that:
Quickly flushes carbon dioxide from the blood
Occurs in response to hypercapnia
Though a rise CO
2acts as the original
stimulus, control of breathing at rest is
regulated by the hydrogen ion concentration
in the brain
Depth and Rate of Breathing: P
CO2
Hyperventilation –increased depth and rate
of breathing that:
Quickly flushes carbon dioxide from the blood
Occurs in response to hypercapnia
Though a rise CO
2acts as the original
stimulus, control of breathing at rest is
regulated by the hydrogen ion concentration
in the brain
Depth and Rate of Breathing: P
CO2
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