Study Results
Results pending
The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.
Basic Information
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Recruitment Status
UNKNOWN
Total Enrollment
30 participants
Study Classification
OBSERVATIONAL
Study Start Date
2021-06-01
Study Completion Date
2023-12-31
Brief Summary
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This study is aimed at :
1. Identifying the exact location of the circuit of typical and atypical AVNRT by applying high-resolution electroanatomic mapping.
2. Investigating the possibility that the recently described "ring tissues" participate in the AVNRT circuit.
1. Identifying the exact location of the circuit of typical and atypical AVNRT by applying high-resolution electroanatomic mapping.
2. Investigating the possibility that the recently described "ring tissues" participate in the AVNRT circuit.
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Detailed Description
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Background The exact circuit of atrioventricular nodal reentrant tachycardia still remains unknown despite advances in high-density mapping, tissue histochemistry, and connexin genotyping. Theoretical calculations have derived a range of 0.8 to 5.2 cm for the length of the slow pathway, whereas that of the fast pathway should be within the range of 2.4 to 11.2 cm. Recent histology data also indicate that the distance of the right inferior extension of the atrioventricular node within the tricuspid vestibule, as judged histologically, and as measured from the site of penetration of the conduction axis in 31 hearts, is 8.2±2.4 mm, with a range from 5.2 to 13.6 mm. These results are compatible with theoretical calculations of the slow pathway previously performed by the investigators. On 3-dimensional reconstructed fluoroscopic images, the average distance between the compact AV node and the ablating electrode in cases of successful AVNRT ablation, however, is 17.2±1.6 to 17.8±0.9 mm. This clearly suggests that successful ablation interrupts the AVNRT circuit at a point beyond the identifiable right posterior extension, and at a consistent area on the the septal isthmus between the CS ostium and the TV. This site is beyond the histologically identifiable inferior extensions of the node.
There is additional evidence in animal studies that the right inferior extension continues within the vestibule of the tricuspid valve as "ring tissue", ie a remnant of the primary ring, while the left atrial vestibule is derived from the initial atrioventricular canal of the developing heart, which is itself known to be slow conducting but cannot be distinguished histologically from the left atrial myocardium. In the human heart, the primary ring extends through the atrioventricular node, and includes the bundle of His, which is rapidly conducting.
Hypothesis The investigators hypothesized that, in humans, the extent of ring tissues varies in such a way that some subjects are susceptible to atrioventricular nodal re-entry, whereas others are not. Thus, the entirety of the tricuspid vestibule, or even part of the mitral vestibule, are parts of the re-entry circuit, at least in some atypical forms with prolonged His-atrial intervals. The circumference of the right atrioventricular orifice has been measured at between 9 and 11 centimeters in patients aged less than 65 years, whereas that of the mitral orifice is from 7 to 9 centimeters. The possibility of the vestibules being involved in the circuit, therefore, cannot theoretically be excluded. Recently, high-density mapping of the re-entry circuit has provided valuable insights into the electrophysiologic patterns of this arrhythmia, identifying the circuit in the vicinity of the nodal area. All these mapping studies, however, were conducted in patients with typical AVNRT. In this setting, the remnants of the ring tissues might be short enough as not to allow proper discrimination of the circuit limbs. The investigators propose to apply high-resolution electroanatomic mapping in patients with both typical atypical AVNRT in which the circuit may contain longer circuit components. Mapping should be focused on both the septal area and the tricuspid, and, if feasible, the mitral ring.
Aims of the Study
This study, therefore, is aimed at :
1. Identifying the exact location of the circuit of typical and atypical AVNRT by applying high-resolution electroanatomic mapping.
2. Investigating the possibility that the recently described "ring tissues" participate in the AVNRT circuit.
Methods Clinical Studies Patients Patients with typical and atypical AVNRT will be recruited following informed consent. The investigators anticipate to study 30 patients with typical, and 10 patients with atypical AVNRT within the next two years.
Definitions AVNRT is diagnosed by fulfillment of established criteria during detailed atrial and ventricular pacing maneuvers. Typical (slow-fast) AVNRT is defined by an atrial-His/His-atrial ratio (AH/HA) \>1, and HA interval ≤70 ms. Atypical AVNRT is defined by delayed retrograde atrial activation with HA\>70 ms.
Mapping Electroanatomic mapping will be performed with CARTO, Rhythmia or Ensite programs at the operator's discretion. High-resolution mapping of the atrial vestibules is inherently difficult in this setting, nonetheless, because of the problems in separating a large ventricular electrogram from the atrial tracing. During atrioventricular nodal reentry, all these areas should show a fused signal consisting of nodal activation. Any mapping system will struggle to annotate the fused signal appropriately in the window and during tachycardia. It may also preferentially annotate the His bundle electrogram because of its high frequency (dv/dt). The implication of this error is that a site annotated as representing the earliest atrial activity may be representing activity in the His bundle. Conversely, a site marked as late may, in fact, be early, being obscured by far field ventricular activity. These limitations may also apply to animal models using micro-electrode mapping. To overcome this problem, pacing maneuvers with ventricular extrastimuli are used to differentiate atrial from ventricular electrogram components where activation appeared to be superimposed owing to simultaneous local activation. In addition, the investigators will exclude points that result in discrepant activation relative to the surrounding isochronal information due to the movement of the CS reference catheter. Activation points from ectopic beats will be excluded manually. The voltage map will be automatically acquired according to the same criteria. After automated mapping, an offline retrospective analysis will be performed by 2 independent observers, in order to manually over-read the sites of earliest atrial activation, at an override activation strength of 100 mV in cases in which (1) the earliest activation on automated mapping appeared diffuse or (2) automated annotation tagged the local ventricular component at the annulus. The His-bundle signal is generally automatically annotated by the system.
Entrainment Entrainment of AVNRT is feasible at sites close to the nodal extensions. Attempts will be made to entrain the tachycardia from various points on the TV annulus in order to investigate potential participation of the right-sided ring tissue into circuit.
Catheter ablation Being on the operation discretion, before conventional catheter ablation of the slow pathway, at least two 30 sec lesions will be delivered on the TV annulus near the isthmus, if this feasible. Interruption of the tachycardia or evoked junctional beats will be sought. Conventional catheter ablation of the slow pathway will be performed as previously described.
Histology Studies Databases from human hearts specimens will be examined and tissue-characterized in an attempt to identify the presence and extent of "ring tissues" in the human myocardium.
There is additional evidence in animal studies that the right inferior extension continues within the vestibule of the tricuspid valve as "ring tissue", ie a remnant of the primary ring, while the left atrial vestibule is derived from the initial atrioventricular canal of the developing heart, which is itself known to be slow conducting but cannot be distinguished histologically from the left atrial myocardium. In the human heart, the primary ring extends through the atrioventricular node, and includes the bundle of His, which is rapidly conducting.
Hypothesis The investigators hypothesized that, in humans, the extent of ring tissues varies in such a way that some subjects are susceptible to atrioventricular nodal re-entry, whereas others are not. Thus, the entirety of the tricuspid vestibule, or even part of the mitral vestibule, are parts of the re-entry circuit, at least in some atypical forms with prolonged His-atrial intervals. The circumference of the right atrioventricular orifice has been measured at between 9 and 11 centimeters in patients aged less than 65 years, whereas that of the mitral orifice is from 7 to 9 centimeters. The possibility of the vestibules being involved in the circuit, therefore, cannot theoretically be excluded. Recently, high-density mapping of the re-entry circuit has provided valuable insights into the electrophysiologic patterns of this arrhythmia, identifying the circuit in the vicinity of the nodal area. All these mapping studies, however, were conducted in patients with typical AVNRT. In this setting, the remnants of the ring tissues might be short enough as not to allow proper discrimination of the circuit limbs. The investigators propose to apply high-resolution electroanatomic mapping in patients with both typical atypical AVNRT in which the circuit may contain longer circuit components. Mapping should be focused on both the septal area and the tricuspid, and, if feasible, the mitral ring.
Aims of the Study
This study, therefore, is aimed at :
1. Identifying the exact location of the circuit of typical and atypical AVNRT by applying high-resolution electroanatomic mapping.
2. Investigating the possibility that the recently described "ring tissues" participate in the AVNRT circuit.
Methods Clinical Studies Patients Patients with typical and atypical AVNRT will be recruited following informed consent. The investigators anticipate to study 30 patients with typical, and 10 patients with atypical AVNRT within the next two years.
Definitions AVNRT is diagnosed by fulfillment of established criteria during detailed atrial and ventricular pacing maneuvers. Typical (slow-fast) AVNRT is defined by an atrial-His/His-atrial ratio (AH/HA) \>1, and HA interval ≤70 ms. Atypical AVNRT is defined by delayed retrograde atrial activation with HA\>70 ms.
Mapping Electroanatomic mapping will be performed with CARTO, Rhythmia or Ensite programs at the operator's discretion. High-resolution mapping of the atrial vestibules is inherently difficult in this setting, nonetheless, because of the problems in separating a large ventricular electrogram from the atrial tracing. During atrioventricular nodal reentry, all these areas should show a fused signal consisting of nodal activation. Any mapping system will struggle to annotate the fused signal appropriately in the window and during tachycardia. It may also preferentially annotate the His bundle electrogram because of its high frequency (dv/dt). The implication of this error is that a site annotated as representing the earliest atrial activity may be representing activity in the His bundle. Conversely, a site marked as late may, in fact, be early, being obscured by far field ventricular activity. These limitations may also apply to animal models using micro-electrode mapping. To overcome this problem, pacing maneuvers with ventricular extrastimuli are used to differentiate atrial from ventricular electrogram components where activation appeared to be superimposed owing to simultaneous local activation. In addition, the investigators will exclude points that result in discrepant activation relative to the surrounding isochronal information due to the movement of the CS reference catheter. Activation points from ectopic beats will be excluded manually. The voltage map will be automatically acquired according to the same criteria. After automated mapping, an offline retrospective analysis will be performed by 2 independent observers, in order to manually over-read the sites of earliest atrial activation, at an override activation strength of 100 mV in cases in which (1) the earliest activation on automated mapping appeared diffuse or (2) automated annotation tagged the local ventricular component at the annulus. The His-bundle signal is generally automatically annotated by the system.
Entrainment Entrainment of AVNRT is feasible at sites close to the nodal extensions. Attempts will be made to entrain the tachycardia from various points on the TV annulus in order to investigate potential participation of the right-sided ring tissue into circuit.
Catheter ablation Being on the operation discretion, before conventional catheter ablation of the slow pathway, at least two 30 sec lesions will be delivered on the TV annulus near the isthmus, if this feasible. Interruption of the tachycardia or evoked junctional beats will be sought. Conventional catheter ablation of the slow pathway will be performed as previously described.
Histology Studies Databases from human hearts specimens will be examined and tissue-characterized in an attempt to identify the presence and extent of "ring tissues" in the human myocardium.
Conditions
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Tachycardia, Atrioventricular Nodal Reentry
Study Design
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Observational Model Type
COHORT
Study Time Perspective
PROSPECTIVE
Study Groups
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AVNRT Cohort
Patients admitted for electrophysiological study and ablation due to AVNRT tachycardia.
During the study and before the ablation high density electroanatomical mapping will be performed.
AVNRT mapping
Intervention Type
DIAGNOSTIC_TEST
AV annuli mapping during AVNRT
Interventions
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AVNRT mapping
AV annuli mapping during AVNRT
Intervention Type
DIAGNOSTIC_TEST
Other Intervention Names
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Electroanatomic mapping
Eligibility Criteria
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Inclusion Criteria
* Patients with atypical or typical AVNRT
* Patients able to provide informed consent
* Patients able to provide informed consent
Exclusion Criteria
* Age \<16 or \>75 years
* Known heart failure
* Severe comorbidities with estimated life expectancy \< 6 months
* Known heart failure
* Severe comorbidities with estimated life expectancy \< 6 months
Minimum Eligible Age
16 Years
Maximum Eligible Age
75 Years
Eligible Sex
ALL
Accepts Healthy Volunteers
No
Sponsors
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Johns Hopkins University
OTHER
Sponsor Role
collaborator
Cardiovascular Research Society, Greece
OTHER
Sponsor Role
lead
Responsible Party
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Dr D Katritsis
Director
Responsibility Role
PRINCIPAL_INVESTIGATOR
Central Contacts
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Other Identifiers
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2021
Identifier Type: -
Identifier Source: org_study_id
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