Third degree AV block pathophysiology: Difference between revisions

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{{Third degree AV block}}
{{Third degree AV block}}
{{CMG}}; {{AE}} {{Soroush}} {{CZ}}; {{RT}}
{{CMG}}; {{AE}} {{Soroush}} {{CZ}}; {{RT}} [[User:Qasim Khurshid|Qasim Khurshid, M.B.B.S[5]]]
==Overview==
==Overview==
The exact pathogenesis of third degree AV block is not fully understood.
Normally [[Sinoatrial node|SA node]] generates impulses that travel to the [[Atrioventricular node|AV node]] and gets delayed there to assure that the [[contraction]] cycle in [[atria]] is complete before a contraction begins in the [[ventricles]]. From the [[AV node]], the impulses pass through the [[Bundle of His|His-Purkinje]] system to cause ventricular contraction. Pathological delay in the [[AV node]] is visualized on an [[electrocardiogram]] as a change in the [[PR interval|P-R interva]]<nowiki/>l. These delays are known as an [[AV block]]. No impulses from the [[SA node]] get conducted to the ventricles, and this leads to a complete [[atrioventricular dissociation]]. The SA node continues to activate at a set rate, but the ventricles will activate through an escape rhythm that can be mediated by either the AV node, one of the fascicles, or by ventricular myocytes themselves. The heart rate will mostly be less than 45 to 50 beats/min, and most patients will be hemodynamically unstable.
 
OR
 
It is thought that third degree AV block is the result of / is mediated by / is produced by / is caused by either [hypothesis 1], [hypothesis 2], or [hypothesis 3].
 
OR
 
[Pathogen name] is usually transmitted via the [transmission route] route to the human host.
 
OR
 
Following transmission/ingestion, the [pathogen] uses the [entry site] to invade the [cell name] cell.
 
OR
 
 
[Disease or malignancy name] arises from [cell name]s, which are [cell type] cells that are normally involved in [function of cells].
 
OR
 
The progression to third degree AV block usually involves the [molecular pathway].
 
OR
 
The pathophysiology of [disease/malignancy] depends on the histological subtype.


==Pathophysiology==
==Pathophysiology==
===Physiology===
===Physiology===
The normal physiology of the heart electrical activity can be understood as follows:
The normal physiology of the electrical activity of the heart can be understood as follows:


* Normal impulse initiation begins in the sinoatrial node (SAN).  
* Normal impulse is generated  in the [[sinoatrial node]] (SAN).
* Electrical pulse then travels through the atrium.  
* Electrical pulse then travels through the [[Atrium (heart)|atrium]].
* '''P wave is recorded in the ECG'''
* P wave is recorded in the [[ECG]]
* Wave reaches the atrioventricular node (AVN).  
* Wave reaches the [[atrioventricular node]] (AVN).
* The AVN then conducts the impulse to the His bundle.
* Atrioventricular node later conducts the impulse to the [[Bundle of His|His bundle]].
* The His bundle divides into the right and left bundles, which distribute this impulse to the ventricles.  
* The bundle of his again gets divided into the right and left bundles, ultimately conducting this impulse to the ventricles.  
* '''PR segment is recorded (atrial, AVN, and His-Purkinje conduction)'''
* PR segment is recorded (atrial, AVN, and His-Purkinje conduction)
* Complete heart block occurs when complete block of this conduction occurs.  
*[[Complete heart block]] occurs when complete block of this conduction occurs.


===Pathogenesis===
===Pathogenesis===
*In complete heart block because the impulse is blocked, an accessory pacemaker below the level of the block will typically activate the ventricles.  This is known as an escape rhythm. Since this accessory pacemaker activates independently of the impulse generated at the [[SA node]], two independent rhythms can be noted on the [[electrocardiogram]] (EKG).
** One will activate the atria and create the P waves, typically with a regular [[PP interval|P to P interval]].
** The second will activate the ventricles and produce the QRS complex, typically with a regular [[RR interval|R to R interval]]. The PR interval will be variable, as the hallmark of complete heart block is no apparent relationship between [[P wave]]s and [[QRS complex]]es.
Morphology of the [[QRS complex]] helps in determining the location at which the escape rhythms are occurring. 
* If the site of complete heart block is at the level of [[AV node]], two-thirds of the escape rhythms have a narrow QRS complex.
* If the site of block is the His bundle, typically a narrow QRS complex is seen.
* Patients with [[trifascicular block]] have a [[wide QRS]] complex (seen in 80% of the cases).
In short, if escape rhythm has a narrow QRS complex the level of block can be either AV node or [[His bundle]] and if the QRS duration is prolonged the level of block is in the fascicles or bundle branches.
Block at the level of AV node gives rise to an escape rhythm that generally arises from a junctional pacemaker with a heart rate of 45-60 beats per minute.  Such patients are hemodynamically stable.  Escape rhythms arise from the His bundle or bundle branch Purkinje system at rates slower than 45 beats per minute when the block is below the AV node.  These patients are hemodynamically unstable and their heart rate is unresponsive to exercise and atropine.


===Complete Heart Block in Myocardial Infarction===
** In [[complete heart block]], because the impulse is blocked, an accessory [[pacemaker]] below the level of the block will typically activate the ventricles; this is known as an escape rhythm.
* An inferior wall [[myocardial infarction]] may cause damage to the [[AV node]], causing third degree heart block. In this case, the damage is usually transitory, and the AV node may recover. Studies have shown that third degree heart block in the setting of an inferior wall myocardial infarction typically resolves within 2 weeks. The escape rhythm typically originates in the AV junction, producing a narrow complex escape rhythm.
** When there is no electrical connection between atria and ventricles, two independent pacemakers will generate impulse independent of [[Sinoatrial node|SA node]]. [[EKG]] will show two rhythms independent of each other
* An anterior wall myocardial infarction may damage the distal conduction system of the heart, causing third degree heart block.  This is typically extensive, permanent damage to the conduction system, necessitating a permanent [[artificial pacemaker |pacemaker]] to be placed. The escape rhythm typically originates in the ventricles, producing a wide complex escape rhythm.
*** One independent pacemaker will activate the atria and create the [[P waves]] with typically with a regular [[PP interval|P to P interval]].
*** The second independent pacemaker in ventricles will activate the ventricles and produce the [[QRS complex]] with typically regular [[RR interval|R to R interval]].
*** The [[PR interval|PR interva]]<nowiki/>l will be a variable that is a hallmark feature of complete heart block and with no apparent relationship between [[P wave|P waves]] and [[QRS complex|QRS complexes]].
** Morphology of the [[QRS complex]] helps in determining the location at which the escape rhythms are occurring.
** If the site of [[complete heart block]] is at the level of [[AV node|the AV node]], two-thirds of the escape rhythms have a narrow [[QRS complex]].
** If the site of block is the [[Bundle of His|His bundle]], typically a narrow [[QRS complex]] is seen.
** Patients with [[trifascicular block]] have a [[wide QRS]] complex (seen in 80% of the cases).
** In short, if escape rhythm has a narrow QRS complex, the level of the block can be either AV node or [[His bundle]], and if the QRS duration is prolonged, the level of block is in the fascicles or bundle branches.
** Block at the level of the AV node gives rise to an escape rhythm that generally arises from a junctional pacemaker with a heart rate of 45-60 beats per minute. Such patients are hemodynamically stable.
** Escape rhythms arise from the [[Bundle of His|His bundle]] or bundle branch Purkinje system at rates slower than 45 beats per minute when the block is below the [[AV node]].
** These patients are hemodynamically unstable, and their heart rate is unresponsive to exercise and [[atropine]].


==Genetics==
==Genetics==


* Third degree AV block is the result of ischemia in majority of the patients.
*[[Third degree AV block]] is the result of ischemia in majority of the patients.
* In certain disease like lyme disease also we might observe AV block.
* In certain disease like lyme disease also we might observe [[Atrioventricular block|AV block]].
* Nevertheless, there are some rare cases of idiopathic AV block
* Nevertheless, there are some rare cases of idiopathic [[AV block]]
 
* In those cases, third degree AV block is transmitted in autosomal dominant pattern most of the time.


Genes involved in the pathogenesis of third degree AV block include:
* In those cases, third degree AV block is transmitted in [[Autosomal dominant|autosomal dominan]]<nowiki/>t pattern most of the time.
 
*'''AV CONDUCTION DISEASE AND CONGENITAL CARDIAC MALFORMATIONS'''
*NKX2.5
*'''AV CONDUCTION DISEASE, VENTRICULAR HYPERTROPHY, AND WOLFF-PARKINSON-WHITE SYNDROME'''
*PRKAG2
*'''AV CONDUCTION DISEASE : A CHANNELOPATHY'''
*SCN5A
*KCNJ2 (type 1 Andersen-Tawil syndrome) <ref name="pmid15372490">{{cite journal| author=Benson DW| title=Genetics of atrioventricular conduction disease in humans. | journal=Anat Rec A Discov Mol Cell Evol Biol | year= 2004 | volume= 280 | issue= 2 | pages= 934-9 | pmid=15372490 | doi=10.1002/ar.a.20099 | pmc= | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=15372490  }} </ref>


{| class="wikitable"
|+
! colspan="2" |Genes involved in the pathogenesis of third degree AV block
|-
|AV CONDUCTION DISEASE AND CONGENITAL CARDIAC MALFORMATIONS
|
* '''NKX2.5'''
|-
|AV CONDUCTION DISEASE, VENTRICULAR HYPERTROPHY, AND WOLFF-PARKINSON-WHITE SYNDROME
|
* '''PRKAG2'''
|-
|AV CONDUCTION DISEASE : A CHANNELOPATHY
|
*'''SCN5A'''
*'''KCNJ2 (type 1 Andersen-Tawil syndrome) <ref name="pmid15372490">{{cite journal| author=Benson DW| title=Genetics of atrioventricular conduction disease in humans. | journal=Anat Rec A Discov Mol Cell Evol Biol | year= 2004 | volume= 280 | issue= 2 | pages= 934-9 | pmid=15372490 | doi=10.1002/ar.a.20099 | pmc= | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=15372490  }} </ref>'''
|}
<br />
==Associated Conditions==
==Associated Conditions==
Conditions associated with third degree AV block include:
Conditions associated with third degree AV block include:


* Ischemic heart disease (Major)
*[[Ischemic heart disease]] (Major)
* Congenital cardiac malformations
* Congenital cardiac malformations
* Ventricular hypertrophy
*[[Ventricular hypertrophy]]
* WPW syndrome
*[[WPW syndrome]]
* Chenlopatioes such as Andersen-Tawil syndrome
* Chenlopatioes such as Andersen-Tawil syndrome


*AV dissociation
*[[AV dissociation]]


=== AV dissociation ===
=== AV dissociation ===
Line 94: Line 75:


* Independent atrial and ventricular activation  either due to complete heart block or as a result of physiologic refractoriness of conduction tissue.
* Independent atrial and ventricular activation  either due to complete heart block or as a result of physiologic refractoriness of conduction tissue.
* It also may develop when the atrial/sinus rate is slower than the ventricular rate (accelerated junctional tachycardia or VT).
* It also may develop when the atrial/sinus rate is slower than the ventricular rate (accelerated junctional [[tachycardia]] or VT).
 
''Please not that sometimes the atrial and ventricular rates are so close that the tracing would suggest normal AV conduction; In this case, careful examination of the long rhythm strip is waranted to reveal a variation in the PR interval.''


* This is called isorhythmic AV dissociation.
* This is called isorhythmic AV dissociation.
* Acceleration of the atrial/sinus rate with either maneuvers or medications will result in restoration of normal conduction.
* Acceleration of the atrial/sinus rate with either maneuvers or medications will result in restoration of normal conduction.
==Gross Pathology==
On gross pathology, [feature1], [feature2], and [feature3] are characteristic findings of third degree AV block.
==Microscopic Pathology==
On microscopic histopathological analysis, [feature1], [feature2], and [feature3] are characteristic findings of third degree AV block.


==References==
==References==

Latest revision as of 13:31, 15 July 2020

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Soroush Seifirad, M.D.[2] Cafer Zorkun, M.D., Ph.D. [3]; Raviteja Guddeti, M.B.B.S. [4] Qasim Khurshid, M.B.B.S[5]

Overview

Normally SA node generates impulses that travel to the AV node and gets delayed there to assure that the contraction cycle in atria is complete before a contraction begins in the ventricles. From the AV node, the impulses pass through the His-Purkinje system to cause ventricular contraction. Pathological delay in the AV node is visualized on an electrocardiogram as a change in the P-R interval. These delays are known as an AV block. No impulses from the SA node get conducted to the ventricles, and this leads to a complete atrioventricular dissociation. The SA node continues to activate at a set rate, but the ventricles will activate through an escape rhythm that can be mediated by either the AV node, one of the fascicles, or by ventricular myocytes themselves. The heart rate will mostly be less than 45 to 50 beats/min, and most patients will be hemodynamically unstable.

Pathophysiology

Physiology

The normal physiology of the electrical activity of the heart can be understood as follows:

  • Normal impulse is generated in the sinoatrial node (SAN).
  • Electrical pulse then travels through the atrium.
  • P wave is recorded in the ECG
  • Wave reaches the atrioventricular node (AVN).
  • Atrioventricular node later conducts the impulse to the His bundle.
  • The bundle of his again gets divided into the right and left bundles, ultimately conducting this impulse to the ventricles.
  • PR segment is recorded (atrial, AVN, and His-Purkinje conduction)
  • Complete heart block occurs when complete block of this conduction occurs.

Pathogenesis

    • In complete heart block, because the impulse is blocked, an accessory pacemaker below the level of the block will typically activate the ventricles; this is known as an escape rhythm.
    • When there is no electrical connection between atria and ventricles, two independent pacemakers will generate impulse independent of SA node. EKG will show two rhythms independent of each other
      • One independent pacemaker will activate the atria and create the P waves with typically with a regular P to P interval.
      • The second independent pacemaker in ventricles will activate the ventricles and produce the QRS complex with typically regular R to R interval.
      • The PR interval will be a variable that is a hallmark feature of complete heart block and with no apparent relationship between P waves and QRS complexes.
    • Morphology of the QRS complex helps in determining the location at which the escape rhythms are occurring.
    • If the site of complete heart block is at the level of the AV node, two-thirds of the escape rhythms have a narrow QRS complex.
    • If the site of block is the His bundle, typically a narrow QRS complex is seen.
    • Patients with trifascicular block have a wide QRS complex (seen in 80% of the cases).
    • In short, if escape rhythm has a narrow QRS complex, the level of the block can be either AV node or His bundle, and if the QRS duration is prolonged, the level of block is in the fascicles or bundle branches.
    • Block at the level of the AV node gives rise to an escape rhythm that generally arises from a junctional pacemaker with a heart rate of 45-60 beats per minute. Such patients are hemodynamically stable.
    • Escape rhythms arise from the His bundle or bundle branch Purkinje system at rates slower than 45 beats per minute when the block is below the AV node.
    • These patients are hemodynamically unstable, and their heart rate is unresponsive to exercise and atropine.

Genetics

  • Third degree AV block is the result of ischemia in majority of the patients.
  • In certain disease like lyme disease also we might observe AV block.
  • Nevertheless, there are some rare cases of idiopathic AV block
  • In those cases, third degree AV block is transmitted in autosomal dominant pattern most of the time.
Genes involved in the pathogenesis of third degree AV block
AV CONDUCTION DISEASE AND CONGENITAL CARDIAC MALFORMATIONS
  • NKX2.5
AV CONDUCTION DISEASE, VENTRICULAR HYPERTROPHY, AND WOLFF-PARKINSON-WHITE SYNDROME
  • PRKAG2
AV CONDUCTION DISEASE : A CHANNELOPATHY
  • SCN5A
  • KCNJ2 (type 1 Andersen-Tawil syndrome) [1]


Associated Conditions

Conditions associated with third degree AV block include:

AV dissociation

AV dissociation is defined as:

  • Independent atrial and ventricular activation either due to complete heart block or as a result of physiologic refractoriness of conduction tissue.
  • It also may develop when the atrial/sinus rate is slower than the ventricular rate (accelerated junctional tachycardia or VT).
  • This is called isorhythmic AV dissociation.
  • Acceleration of the atrial/sinus rate with either maneuvers or medications will result in restoration of normal conduction.

References

  1. Benson DW (2004). "Genetics of atrioventricular conduction disease in humans". Anat Rec A Discov Mol Cell Evol Biol. 280 (2): 934–9. doi:10.1002/ar.a.20099. PMID 15372490.


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