Neurogenic and myogenic hearts
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Dec 10, 2016
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About This Presentation
NEUROGENIC AND MYOGENIC GENERAL INTRODUCTION BY ASIF IBRAHIM KANTH
Slide Content
LECTURER
In animals with open circulatory system the In animals with open circulatory system the
heart is usually sac-like or tubular. It has ostia heart is usually sac-like or tubular. It has ostia
or lateral openings which get closed when or lateral openings which get closed when
heart contracts and opens when heart relaxes. heart contracts and opens when heart relaxes.
When heart relaxes vaccum is created to suck When heart relaxes vaccum is created to suck
blood in the heart. Hence these hearts are blood in the heart. Hence these hearts are
known as suction pumps. known as suction pumps.
In most of the suction pump hearts the beating In most of the suction pump hearts the beating
rhythm is set through nerve impulses. Such rhythm is set through nerve impulses. Such
hearts are known as hearts are known as Neurogenic heartsNeurogenic hearts..
heart is usually sac-like or tubular. It has ostia heart is usually sac-like or tubular. It has ostia
or lateral openings which get closed when or lateral openings which get closed when
heart contracts and opens when heart relaxes. heart contracts and opens when heart relaxes.
When heart relaxes vaccum is created to suck When heart relaxes vaccum is created to suck
blood in the heart. Hence these hearts are blood in the heart. Hence these hearts are
known as suction pumps. known as suction pumps.
In most of the suction pump hearts the beating In most of the suction pump hearts the beating
rhythm is set through nerve impulses. Such rhythm is set through nerve impulses. Such
hearts are known as hearts are known as Neurogenic heartsNeurogenic hearts..
In higher animals with closed ciruclatory system 2, 3 or 4 In higher animals with closed ciruclatory system 2, 3 or 4
chambered hearts are seen with muscular ventricles which pumps chambered hearts are seen with muscular ventricles which pumps
the blood in the body with pressure and hence heart are known as the blood in the body with pressure and hence heart are known as
pressure pumps. pressure pumps.
In pressure pump heart the rhythm is set in specialised muscle In pressure pump heart the rhythm is set in specialised muscle
cells within the heart. They are known as cells within the heart. They are known as Myogenic heartsMyogenic hearts..
Most of the embryonic hearts are myogenic which later on may be Most of the embryonic hearts are myogenic which later on may be
become myogenic or neurogenicbecome myogenic or neurogenic..
chambered hearts are seen with muscular ventricles which pumps chambered hearts are seen with muscular ventricles which pumps
the blood in the body with pressure and hence heart are known as the blood in the body with pressure and hence heart are known as
pressure pumps. pressure pumps.
In pressure pump heart the rhythm is set in specialised muscle In pressure pump heart the rhythm is set in specialised muscle
cells within the heart. They are known as cells within the heart. They are known as Myogenic heartsMyogenic hearts..
Most of the embryonic hearts are myogenic which later on may be Most of the embryonic hearts are myogenic which later on may be
become myogenic or neurogenicbecome myogenic or neurogenic..
In some invertebrates and all vertebrates the heart is In some invertebrates and all vertebrates the heart is
myogenic. In them the setting of the rhythm (pacemaking) is by myogenic. In them the setting of the rhythm (pacemaking) is by
specialized cells (pacemakers). specialized cells (pacemakers).
These cells are highly specialized for generating and These cells are highly specialized for generating and
conducting the impulse. conducting the impulse.
In some animals they can be distinguished histologically from In some animals they can be distinguished histologically from
the other heart muscles the other heart muscles
whereas in some others the distinction is not clear.whereas in some others the distinction is not clear.
myogenic. In them the setting of the rhythm (pacemaking) is by myogenic. In them the setting of the rhythm (pacemaking) is by
specialized cells (pacemakers). specialized cells (pacemakers).
These cells are highly specialized for generating and These cells are highly specialized for generating and
conducting the impulse. conducting the impulse.
In some animals they can be distinguished histologically from In some animals they can be distinguished histologically from
the other heart muscles the other heart muscles
whereas in some others the distinction is not clear.whereas in some others the distinction is not clear.
Snakes
Bat
Rat
Guinea pig
Rabbit
Pace maker cells cannot be
distinguished
i.e. the distinction between
pacemakers and other cells is not
clear.
Bat
Rat
Guinea pig
Rabbit
Pace maker cells cannot be
distinguished
i.e. the distinction between
pacemakers and other cells is not
clear.
Humming bird
Chick
Platypus
Anteater
Sheep
Cow
Pig etc.
Specialized cells can be
distinguished or differentiated
Chick
Platypus
Anteater
Sheep
Cow
Pig etc.
Specialized cells can be
distinguished or differentiated
The pacemaking regions are different from animal to The pacemaking regions are different from animal to
animal.animal.
In Teleost cells of floor of atrium and auriculo-ventricular In Teleost cells of floor of atrium and auriculo-ventricular
junction act as pacemaker.junction act as pacemaker.
In elasmobranch fishes sinus venouses, In elasmobranch fishes sinus venouses,
auriculoventricular junction and truncus arterioses act as auriculoventricular junction and truncus arterioses act as
pacemaker.pacemaker.
In amphibians and reptiles sinus venousus act as In amphibians and reptiles sinus venousus act as
pacemakerspacemakers
In mammals and birds sinu-atrial and auriculo-ventricular In mammals and birds sinu-atrial and auriculo-ventricular
nodes act as pacemakers.nodes act as pacemakers.
In invertebrates the pace making area is wondering i.e. In invertebrates the pace making area is wondering i.e.
changing place.changing place.
animal.animal.
In Teleost cells of floor of atrium and auriculo-ventricular In Teleost cells of floor of atrium and auriculo-ventricular
junction act as pacemaker.junction act as pacemaker.
In elasmobranch fishes sinus venouses, In elasmobranch fishes sinus venouses,
auriculoventricular junction and truncus arterioses act as auriculoventricular junction and truncus arterioses act as
pacemaker.pacemaker.
In amphibians and reptiles sinus venousus act as In amphibians and reptiles sinus venousus act as
pacemakerspacemakers
In mammals and birds sinu-atrial and auriculo-ventricular In mammals and birds sinu-atrial and auriculo-ventricular
nodes act as pacemakers.nodes act as pacemakers.
In invertebrates the pace making area is wondering i.e. In invertebrates the pace making area is wondering i.e.
changing place.changing place.
In birds and mammals as mentioned above pacemaking In birds and mammals as mentioned above pacemaking
impulse arises in sinu-atrial node (S.A. node). It is a small impulse arises in sinu-atrial node (S.A. node). It is a small
mass in right atrium. (In man 2 cm x 2cm) It is situated near mass in right atrium. (In man 2 cm x 2cm) It is situated near
entrance of vein.Atrio-ventricular node (A.V. node) is situated entrance of vein.Atrio-ventricular node (A.V. node) is situated
near auriculoventricular junction from which the impulse is near auriculoventricular junction from which the impulse is
carried to ventricle by specialised conducting muscles carried to ventricle by specialised conducting muscles
forming auriculoventricular bundle (AV bundle) or Bundle of forming auriculoventricular bundle (AV bundle) or Bundle of
‘His’ i.e. bundle of God.‘His’ i.e. bundle of God.
In birds bundle of His forms a network in atria.In birds bundle of His forms a network in atria.
impulse arises in sinu-atrial node (S.A. node). It is a small impulse arises in sinu-atrial node (S.A. node). It is a small
mass in right atrium. (In man 2 cm x 2cm) It is situated near mass in right atrium. (In man 2 cm x 2cm) It is situated near
entrance of vein.Atrio-ventricular node (A.V. node) is situated entrance of vein.Atrio-ventricular node (A.V. node) is situated
near auriculoventricular junction from which the impulse is near auriculoventricular junction from which the impulse is
carried to ventricle by specialised conducting muscles carried to ventricle by specialised conducting muscles
forming auriculoventricular bundle (AV bundle) or Bundle of forming auriculoventricular bundle (AV bundle) or Bundle of
‘His’ i.e. bundle of God.‘His’ i.e. bundle of God.
In birds bundle of His forms a network in atria.In birds bundle of His forms a network in atria.
S.A. node is known to be true pacemaker. If it is surgically S.A. node is known to be true pacemaker. If it is surgically
manipulated or given temperature, chemical or electrical manipulated or given temperature, chemical or electrical
stimuli, it affects cardiac activity, thus the wave of heart stimuli, it affects cardiac activity, thus the wave of heart
action starts from this point. action starts from this point.
The wave is picked up by A.V. node situated in right atrium The wave is picked up by A.V. node situated in right atrium
near AV septum and then spreads into ventricle through the near AV septum and then spreads into ventricle through the
branches of auricular- ventricular bundles which forms a branches of auricular- ventricular bundles which forms a
network in ventricle.(Purkinge fibres) network in ventricle.(Purkinge fibres)
manipulated or given temperature, chemical or electrical manipulated or given temperature, chemical or electrical
stimuli, it affects cardiac activity, thus the wave of heart stimuli, it affects cardiac activity, thus the wave of heart
action starts from this point. action starts from this point.
The wave is picked up by A.V. node situated in right atrium The wave is picked up by A.V. node situated in right atrium
near AV septum and then spreads into ventricle through the near AV septum and then spreads into ventricle through the
branches of auricular- ventricular bundles which forms a branches of auricular- ventricular bundles which forms a
network in ventricle.(Purkinge fibres) network in ventricle.(Purkinge fibres)
In birds network is present in right and In birds network is present in right and
left atria as well. AV bundle tissue is left atria as well. AV bundle tissue is
highly specialized in conductance and highly specialized in conductance and
hence spreads the impulse very fast. hence spreads the impulse very fast.
left atria as well. AV bundle tissue is left atria as well. AV bundle tissue is
highly specialized in conductance and highly specialized in conductance and
hence spreads the impulse very fast. hence spreads the impulse very fast.
In myogenic heart in fact all cells have ability to set the rhythm. In myogenic heart in fact all cells have ability to set the rhythm.
But certain cells are more specialized. But certain cells are more specialized.
The difference in them and other cells is they are highly The difference in them and other cells is they are highly
unstable and have changing electrical potential. These cells unstable and have changing electrical potential. These cells
are known as pacemaker cells.are known as pacemaker cells.
According to Kollikar and Miller heart have 3 type of cells 1) According to Kollikar and Miller heart have 3 type of cells 1)
Pacemaker muscle cell 2) Conductive muscle cell 3) Pacemaker muscle cell 2) Conductive muscle cell 3)
Contracting muscle cellsContracting muscle cells
But certain cells are more specialized. But certain cells are more specialized.
The difference in them and other cells is they are highly The difference in them and other cells is they are highly
unstable and have changing electrical potential. These cells unstable and have changing electrical potential. These cells
are known as pacemaker cells.are known as pacemaker cells.
According to Kollikar and Miller heart have 3 type of cells 1) According to Kollikar and Miller heart have 3 type of cells 1)
Pacemaker muscle cell 2) Conductive muscle cell 3) Pacemaker muscle cell 2) Conductive muscle cell 3)
Contracting muscle cellsContracting muscle cells
Pacemaker cells initially have inside negative as compared to Pacemaker cells initially have inside negative as compared to
outside and have a charge or potential of about –55 mV. outside and have a charge or potential of about –55 mV.
This charge is unstable there is a slow leakage up to –30 mV This charge is unstable there is a slow leakage up to –30 mV
which is known as slow depolarization. which is known as slow depolarization.
This is followed by rapid depolarization up to +10 mV. This is followed by rapid depolarization up to +10 mV.
This depolarization causes contraction of muscles. This depolarization causes contraction of muscles.
The depolarization is followed by repolarisation which causes The depolarization is followed by repolarisation which causes
relaxation or diastole.relaxation or diastole.
outside and have a charge or potential of about –55 mV. outside and have a charge or potential of about –55 mV.
This charge is unstable there is a slow leakage up to –30 mV This charge is unstable there is a slow leakage up to –30 mV
which is known as slow depolarization. which is known as slow depolarization.
This is followed by rapid depolarization up to +10 mV. This is followed by rapid depolarization up to +10 mV.
This depolarization causes contraction of muscles. This depolarization causes contraction of muscles.
The depolarization is followed by repolarisation which causes The depolarization is followed by repolarisation which causes
relaxation or diastole.relaxation or diastole.
This way the charges on pacemaker cells This way the charges on pacemaker cells
keep on changing constantly. keep on changing constantly.
These changes in the form of depolarisation These changes in the form of depolarisation
and repolarisation spread in the heart and repolarisation spread in the heart
muscle through conducting cells causing muscle through conducting cells causing
rhythmic contraction and relaxation of heartrhythmic contraction and relaxation of heart..
keep on changing constantly. keep on changing constantly.
These changes in the form of depolarisation These changes in the form of depolarisation
and repolarisation spread in the heart and repolarisation spread in the heart
muscle through conducting cells causing muscle through conducting cells causing
rhythmic contraction and relaxation of heartrhythmic contraction and relaxation of heart..
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