Involvement of the Sinus Node and the Conduction System in Myocarditis and Cardiomyopathy

SummaryWe studied the cardiac conduction system in a case of Hurler syndrome. There was dense fibrosis of the supporting matrix of the sinus node and accumulation of mucopolysaccharide in the nodal cells. The bundle branches showed prominent hydropic degeneration, being encased and punctuated by dense fibrous tissue. These changes in the conduction system may predispose to the development of arrhythmias, accounting for the sudden deaths in Hurler syndrome.

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Specific Arrhythmias and Syncope

10.1093/med/9780199755691.003.0044 ◽

2012 ◽

Author(s):

Peter A. Brady

Keyword(s):

Heart Rate ◽

Heart Block ◽

Heart Rate Response ◽

Spontaneous Recovery ◽

Sinus Node ◽

Conduction System ◽

Purkinje System ◽

Transient Loss ◽

System Disorder ◽

Response To Exercise

Bradycardia is defined as a heart rate less than 60 beats per minute at rest or a decreased heart rate response to exercise. Causes of bradycardia include high vagal tone (most cases occur in asymptomatic and often fit and healthy persons), sinus node dysfunction, drug therapy, heart block, and myocardial infarction. A conduction system disorder is present when there is a delay in impulses from the sinus node reaching the ventricles or when some impulses do not reach the ventricles because of block within the AV node or distal conduction system (His-Purkinje system). Conduction system disorders can be divided into first-degree, second-degree, and third-degree (complete) heart block. The tachycardias (atrial fibrillation and atrial flutter) and syncope (as a transient loss of consciousness with spontaneous recovery) are also reviewed.

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P3826Gene therapy for cardiac conduction system dysfunction in heart failure

European Heart Journal ◽

10.1093/eurheartj/ehz745.0668 ◽

2019 ◽

Vol 40 (Supplement_1) ◽

Author(s):

L Stuart ◽

I Y Oh ◽

Y Wang ◽

S Nakao ◽

T Starborg ◽

...

Keyword(s):

Heart Failure ◽

Ion Channel ◽

Transgene Expression ◽

Ex Vivo ◽

Sinus Node ◽

Conduction System ◽

Cardiac Conduction ◽

Cardiac Conduction System ◽

Gfp Expression ◽

Free Running

Abstract Background and purpose Heart failure (HF) is characterised by generalised dysfunction of the cardiac conduction system (CCS). Ion channel and structural remodelling in the CCS have been widely demonstrated in animal models of cardiovascular disease. As Purkinje fibres (PFs) are minute strands of tissue, little is known about their ultrastructure and remodelling in disease. Furthermore, given the role for microRNAs (miRs) in CCS molecular remodelling, we aimed to develop a tissue specific method for delivering therapeutic transgenes, such as miR sponges. Methods New Zealand rabbits were used for PF ultrastructural studies. HF was induced via pressure and volume overload. Free running PFs were processed for serial block face scanning electron microscopy (SBF-SEM). Manual contrast-based segmentation techniques were used on IMOD software to determine the 3D cellular ultrastructure. To target transgene expression to the CCS, adenoviral plasmids were cloned expressing a GFP reporter gene. GFP transcription was placed under control of the KCNE1 promoter, a K+ channel subunit expressed throughout the CCS, or the HCN4 promoter, a key pacemaker ion channel, to target the sinus node. The strong ubiquitous cytomegalovirus (CMV) promoter was used as a positive control. Adenovirus was produced using via transfection into the 293A cell line for viral packaging and amplification. Results Purkinje cells (PCs) formed a central core within PFs, encapsulated by an extensive collagen matrix. PCs were uninucleated and spindle shaped with an irregular membrane. Gap junctions were abundant and distributed along the lateral surface of cells, and there was a trend towards decreased expression in HF (p=0.0526, n=3 cells analysed per group). Hypertrophy and nuclear membrane breakdown were evident in HF PCs, the latter facilitating mitochondrial entry. Using the CMV-GFP adenoviral construct, abundant GFP expression was conferred in ex vivo sinus node tissue, isolated sinus node myocytes, and neonatal ventricular rat cardiomyocytes (NRCMs). The KCNE1 promoter conferred relatively high GFP expression in NRCMs, greater than that from the HCN4 promoter. In isolated sinus node myocytes, the HCN4 promoter conferred greater transgene expression than in NRCMs. In ex vivo sinus node tissue, only the CMV construct was capable of driving significant GFP expression. Notably, expression was largely confined to the sinus node, with only sparse expression detected in the surrounding atrial muscle. Conclusions SBF-SEM revealed ultrastructure of free running PFs in situ, and uncovered novel structural changes in HF that are likely to be pro-arrhythmic. Preliminary data suggest that 1.2 kb and 0.8 kb fragments of the HCN4 promoter are capable of driving sinus node specific transgene expression. Further tests are warranted to confirm the utility of these promoters to express therapeutic transgenes, such as miR sponges to competitively inhibit miR activity in vitro and in vivo. Acknowledgement/Funding The British Heart Foundation

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Angiotensin II binding sites in the conduction system of rat hearts

AJP Heart and Circulatory Physiology ◽

10.1152/ajpheart.1987.253.6.h1618 ◽

1987 ◽

Vol 253 (6) ◽

pp. H1618-H1622 ◽

Cited By ~ 7

Author(s):

K. Saito ◽

J. S. Gutkind ◽

J. M. Saavedra

Keyword(s):

Angiotensin Ii ◽

Binding Sites ◽

Enzyme Inhibitor ◽

Sinus Node ◽

Atrioventricular Node ◽

Conduction System ◽

Parasympathetic Ganglia ◽

Tissue Sections ◽

Rat Hearts ◽

Specific Receptors

Angiotensin II binding sites were localized and quantified in the conduction system of the rat heart by autoradiography in combination with computerized microdensitometry. Tissue sections (16-microns thick), containing cardiac vagus ganglia, sinus node, and atrioventricular node, were incubated with 125I-Sar1-angiotensin II to generate autoradiograms that were compared with other autoradiograms from 125I-labeled standards. Angiotensin II binding sites were highly localized in both the sinoatrial and atrioventricular nodes and in the cardiac vagus ganglia. In contrast, binding to the angiotensin converting enzyme, determined by incubation of adjacent tissue sections with the specific enzyme inhibitor 125I-351A, was very low in these areas but high in the cardiac endothelium. Our results suggest that angiotensin II may have direct chronotropic effects through stimulation of specific receptors in the conduction system of the heart and in intrinsic parasympathetic ganglia.

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Dynamical behavior of cardiac conduction system under external disturbances: simulation based on microcontroller technology

Physica Scripta ◽

10.1088/1402-4896/ac47ba ◽

2022 ◽

Author(s):

Rodrigue Fonkou ◽

Patrick Louodop ◽

Pierre Kisito Talla

Keyword(s):

Blood Pressure ◽

Electric Current ◽

Sinus Node ◽

Dynamical Behavior ◽

Heart Rhythm ◽

Conduction System ◽

Cardiac Conduction ◽

Cardiac Conduction System ◽

Very High Frequency ◽

Purkinje Fibers

Abstract The heart rhythm is one of the most interesting aspects of the dynamic behavior of biological systems. Understanding heart rhythms is essential in the dynamic analysis of the heart. Each type of dynamic behaviour can describe normal or pathological physiology. The heart is made up of nodes ranging from SA node (natural pacemaker) to Purkinje fibers. The electric current originates in the sinus node and travels through the heart until it reaches the Purkinje fibers, causing after its passage through each of the nodes a heartbeat thus constituting the electrocardiogram (ECG). Since the origin of the electric current is the sinus node, in this article we study numerically and experimentally by microcontroller the influence of the sinus node on the propagation of electric current through the heart. A study of the sinus node in its autonomous state shows us that in their coupled state, the nodes of the heart qualitatively reproduce the time series of the action potential of this latter, which leads to the recording of the ECG. A study when the sinus node is subjected to periodic pulsed excitation E 1(t) = kP(t), assumed to come from blood pressure, with P(t) the blood pressure, shows that for some selected frequencies, it is found that the nodes of the heart and the ECG exhibit responses having the same shape and the same frequencies as those of the pulsatile blood pressure. This suggests the possibility of using such a conversion and excitation mechanism to replicate the functioning of cardiac conduction system. The chaotic analysis of the sinus node subjected to a sinusoidal type disturbance (E 0sin(ωt)) is also presented, it shows that in its chaotic state, the nodes of the heart, as well as the ECG, provide very high frequency signals. This requires the control of the sinus node (natural pacemaker) in such a situation

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SEM, TEM, and IHC Analysis of the Sinus Node and Its Implications for the Cardiac Conduction System

Anatomy Research International ◽

10.1155/2013/961459 ◽

2013 ◽

Vol 2013 ◽

pp. 1-6

Author(s):

D. Mandrioli ◽

F. Ceci ◽

T. Balbi ◽

C. Ghimenton ◽

G. Pierini

Keyword(s):

Electron Microscopy ◽

Sinus Node ◽

Atrioventricular Node ◽

Definite Description ◽

Conduction System ◽

Cardiac Conduction ◽

Cardiac Conduction System ◽

Ordered Structure ◽

Healthy Individuals ◽

Optical And Electron Microscopy

More than 100 years after the discovery of the sinus node (SN) by Keith and Flack, the function and structure of the SN have not been completely established yet. The anatomic architecture of the SN has often been described as devoid of an organized structure; the origin of the sinus impulse is still a matter of debate, and a definite description of the long postulated internodal specialized tract conducting the impulse from the SN to the atrioventricular node (AVN) is still missing. In our previously published study, we proposed a morphologically ordered structure for the SN. As a confirmation of what was presented then, we have added the results of additional observations regarding the structural particularities of the SN. We investigated the morphology of the sinus node in the human hearts of healthy individuals using histochemical, immunohistochemical, optical, and electron microscopy (SEM, TEM). Our results confirmed that the SN presents a previously unseen highly organized architecture.

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How good is operator opinion at predicting high ventricular pacing burden among patients receiving device therapy for bradycardia?

EP Europace ◽

10.1093/europace/euab116.394 ◽

2021 ◽

Vol 23 (Supplement_3) ◽

Author(s):

R Chattopadhyay ◽

P Chousou ◽

R Thomas ◽

J Hayes ◽

J O"brien ◽

...

Keyword(s):

Complete Heart Block ◽

Sinus Node ◽

Group Analysis ◽

Conduction System ◽

Ventricular Pacing ◽

Single Centre ◽

System Disease ◽

Node Disease ◽

Conduction System Disease

Abstract Funding Acknowledgements Type of funding sources: None. Introduction Current guidelines indicate that pacing methods that maintain physiologic ventricular activation (biventricular pacing or His-bundle pacing) should be chosen over right ventricular pacing (Vp) among patients with EF 36-50% who are expected to Vp >40% of the time. There are no guidelines to help predict which patients will receive a high burden of Vp and this is left to operator opinion. We sought to ascertain whether operator opinion is an accurate predictor of high burden of Vp. Methods This was a single-centre single-blinded observational study of patients who received pacemaker implant for treatment of bradycardia between April 2015 and 2019 and had at least 12 month follow-up data on record. Patients’ demographic, clinical, electrocardiographic and echocardiographic data were reviewed in a blinded fashion by a senior implanting physician, who estimated whether the Vp at 12 months would exceed 40%. The Vp at approximately 12 months was obtained from the pacing records and compared with the prediction. Results Some 982 patients underwent pacemaker implantation during the study period, 698 for conduction system disease (CSD), 267 for sinus node disease (SND) and 17 for other conditions. Overall, 856 had valid follow-up data. Of these, 543 (63.4%) were predicted to Vp >40% , and 527(61.6%) were documented as having Vp >40%. The sensitivity and specificity of operator prediction were 93.2% and 84.2%, with positive and negative predictive values of 90.4% and 88.5%. Table 1 illustrates analyses of different populations by clinical parameter. In sub-group analysis, complete heart block and PR > 300ms were significant factors for accurate prediction of Vp > 40%, however clinical features, such as syncope, were poor discriminators. Conclusion In this single-centre study, among patients receiving pacemaker implant for treatment of bradycardia, operator prediction of the burden of Vp >40% has an acceptable degree of accuracy. Sub-group analysis suggests that certain clinical parameters could make this prediction easier. Table 1. Comparison of operator opinion SND CSD CHB SND+PR < 160 PR > 300 Syncope Non-syncope n 698 267 216 84 60 409 344 Sensitivity 44.4% 97.7% 100% 6.3% 100% 86.4% 87.9% Specificity 98.3% 62.0% 45.2% 97.1% 0%* 89.9% 79.6% PPV 87.0% 90.6% 91.6% 33.3% 98.3% 94.2% 92.2% NPV 87.9% 87.9% 100% 81.5% - 77.6% 70.5% * only 1 patient did not RV pace >40% - this was not predicted. SND – sinus node disease; CSD – conduction system disease; CHB – complete heart block, PPV – positive predictive value; NPV – negative predictive value

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Clinical Cardiac Electrophysiological Study on the Sinus Node and Atrioventricular Conduction System

Korean Circulation Journal ◽

10.4070/kcj.1985.15.2.255 ◽

1985 ◽

Vol 15 (2) ◽

pp. 255

Author(s):

Yun Shik Choi ◽

Myoung Mook Lee ◽

Young Bae Park ◽

Jung Don Seo ◽

Young Woo Lee

Keyword(s):

Electrophysiological Study ◽

Sinus Node ◽

Conduction System ◽

Atrioventricular Conduction

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Die Entdeckung des AV-Knotens des Herzens durch Sunao Tawara und Ludwig Aschoff

DMW - Deutsche Medizinische Wochenschrift ◽

10.1055/a-0819-7328 ◽

2019 ◽

Vol 144 (25) ◽

pp. 1771-1777

Author(s):

Gerhard Aumüller

Keyword(s):

Sinus Node ◽

Atrioventricular Node ◽

Conduction System ◽

Myocardial Cells ◽

Fiber System ◽

Av Node ◽

Functional Interpretation ◽

Purkinje Fibers ◽

Willem Einthoven ◽

Long Time

AbstractAlready in 1664, the Danish anatomist and naturalist Niels Stensen proved that the heart is a muscle. But for a long time it remained unclear what triggered the heart contractions.The Dutch physiologist Willem Einthoven registered the electrical processes in the contraction of the heart muscle and thus provided the first electrophysiological basis of cardiac muscle activity. Since 1903, Sunao Tawara was assistant to Ludwig Aschoff in Marburg. Both left Marburg in 1906: Tawara went back to Japan and Aschoff to Freiburg. In 1905, Tawara discovered the connections of the His’ bundle to the AV node and the Purkinje fibers. At that time, there was no thought of a functional interpretation. Tawara discovered a kind of “knot” that linked to the adjacent myocardial cells, as well as the “Tawara thighs”, which frayed and went into structures known as Purkinje fibers. Tawara detected the tree-like structure he had discovered as a muscle-fiber system that controlled the arousal of the heart’s musculature. Thus the old dispute between myogenic and neurogenic arousal of the heart was decided in favor of the myogenic excitation conduction. The atrioventricular node described by Tawara was given the eponym “Aschoff-Tawara node”. Tawara’s groundbreaking work on the conduction system was the basis for the discovery of the sinus node and the interpretation of the heart’s electrophysiology.

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Rare SCN10A variants associated with cardiac conduction system diseases

European Heart Journal ◽

10.1093/ehjci/ehaa946.0341 ◽

2020 ◽

Vol 41 (Supplement_2) ◽

Author(s):

K Hayashi ◽

N Fujino ◽

H Furusho ◽

S Usui ◽

K Sakata ◽

...

Keyword(s):

Rare Variants ◽

Association Studies ◽

Electrophysiological Study ◽

Sinus Node ◽

Pacemaker Implantation ◽

Conduction System ◽

Cardiac Conduction ◽

Cardiac Conduction System ◽

Genome Wide Association Studies ◽

Standards And Guidelines

Abstract Background The genetic bases of cardiac conduction-system disease (CCSD) range from ion channelopathies to mutations in many other genes. Genome-wide association studies have shown common variants in SCN10A influence cardiac conduction. However, it has not yet to be determined whether vulnerability to CCSD is associated with rare coding sequence variation in the SCN10A gene. Purpose We sought to determine the clinical impact of rare variants in SCN10A in patients with CCSD and classified the variants according to the 2015 American College of Medical Genetics and Genomics (ACMG) standards and guidelines. Methods We performed screening for rare variants (minor allele frequency ≤0.001) in SCN10A in CCSD patients with an onset at a young age under 65 or those who had a family history of pacemaker implantation (PMI) (n=40; 18 female; mean age, 41±18 years). We transiently expressed engineered variants in ND 7/23 cells, and conducted whole-cell voltage clamp experiments to clarify the functional properties of the Nav1.8 current. Results We identified nine rare variants in SCN10A in 7 patients. Two patients were carriers of two rare variants in SCN10A and 5 were carriers of one rare variant in SCN10A. Four patients were affected with sinus node dysfunction, 1 were atrioventricular block, and 2 were both dysfunctions. We performed electrophysiological study for 8 of 9 rare variants. It demonstrated that 2 rare variants showed gain-of-function, and 3 rare variants showed loss-of-function. We finally determined 5 likely pathogenic variants in SCN10A in 5 patients (12.5%) according to the ACMG standards and guidelines. All 5 patients underwent a pacemaker implantation at an average age of 43±16. Conclusions These results demonstrate that SCN10A variants play a pivotal role in enhanced susceptibility of CCSD. We suggest the importance for screening SCN10A variants in clinical settings. Funding Acknowledgement Type of funding source: None

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