Types of Anesthesia

The anesthetic plan must be individually tailored, depending on the nature of procedure, patient characteristics, hospital resources, patient preference, and anesthesia skill/training of the EP team. Furthermore, changes in the level of sedation and in the type of drugs used can be necessary during the course of the procedure and must be aligned with the needs of the interventional procedures. For example, the optimal degree of anesthesia may vary from minimal (during induction of arrhythmias) to deep (during painful ablation or electrical cardioversion). Also, the anesthesiologist should be asked to avoid or minimize nondepolarizing muscle relaxants when the evaluation of phrenic nerve function is required during ablation. Therefore close communication and collaboration between the electrophysiologists and anesthesia providers are crucial to perform EP procedures safely and successfully.

One of following anesthesia techniques or their combinations may be used: (1) local anesthesia at the site of vascular access; (2) conscious (moderate) sedation with intravenous (IV) sedatives; (3) deep sedation with IV sedatives; and (4) general anesthesia.

Jet Ventilation

Using high-frequency ventilation during general anesthesia decreases the regular chest wall motion associated with standard mechanical ventilation, thus minimizing respiration-related cardiac movement. Recent data suggest that the use of jet ventilation in the EP laboratory can enhance catheter stability during mapping and ablation and potentially improve the efficacy and safety of the ablation procedure, especially when a stable field needs to be established.

On the other hand, several disadvantages of high-frequency jet ventilation have been reported, including the lack of airtight sealing of airway to decrease secretions, the inability to use inhaled anesthesia, and the difficult measurement of resulting ventilator parameters and efficiency of gas exchange. Furthermore, the risk of barotrauma (e.g., volutrauma, pneumothorax, mediastinal emphysema) is increased, especially in patients with chronic obstructive pulmonary disease. Mucosal damage, especially necrotizing tracheobronchitis, has been reported, and can be prevented by adequate humidification of the ventilator circuit.

Electrophysiological Effects of Anesthetic Medications

The exact influences anesthetics have on cardiac EP in the clinical setting are not entirely certain. In general, sedation of any kind decreases endogenous catecholamine release, potentially suppressing arrhythmic activity, which can impede the mapping and ablation procedure. Nonetheless, some anesthetics (e.g., ketamine) induce sympathetic stimulation, which can potentially facilitate or induce arrhythmias.

Benzodiazepines reduce blood pressure by decreasing peripheral vascular resistance leading to reflex tachycardia. Opioids, especially at high doses, have a central vagotonic effect with resultant bradycardia. Propofol can trigger vagally mediated bradycardia and inhibit spontaneous ventricular arrhythmias.

Inhalational anesthetics enhance automaticity of latent atrial pacemakers relative to the sinus node, promoting ectopic atrial rhythms and wandering atrial pacemakers. In addition, these agents demonstrate varying effects on the atrioventricular node (AVN) and His-Purkinje system (HPS). Isoflurane prolongs the atrial refractory period and delays ventricular repolarization, but the clinical significance of these effects appears minimal.

Neuromuscular relaxants modulate autonomic tone; some agents can precipitate vasodilatation and reflex tachycardia while others can cause bradycardia, particularly if used in combination with other vagotonic drugs. Ketamine can increase heart rate and blood pressure by increasing central sympathetic outflow. Also, ketamine is a direct myocardial depressant.

Right Atrial Catheter

A fixed-tip, 5 or 6 Fr quadripolar electrode catheter is typically used. The RA may be entered from the IVC or SVC. The femoral veins are the usual entry sites. Most commonly, stimulation and recording from the RA is performed by placing the RA catheter tip at the high posterolateral wall at the SVC-RA junction in the region of the sinus node or in the RA appendage ( Fig. 4.4 ).

Fluoroscopic Views of Catheters in Study for Supraventricular Tachycardia.

Catheters are labeled high right atrium (RA), right ventricle (RV) , and coronary sinus (CS) ; the CS catheter was inserted from a jugular venous approach. HB, His bundle; LAO, left anterior oblique; RAO, right anterior oblique.

Right Ventricular Catheter

A fixed-tip, 5 or 6 Fr quadripolar electrode catheter is typically used. All sites in the RV are accessible from any venous approach. The RV apex is most commonly chosen for stimulation and recording because of stability and reproducibility (see Fig. 4.4 ).

His Bundle Catheter

A fixed- or deflectable-tip, 6 Fr quadripolar electrode catheter is typically used. The catheter is passed via the femoral vein into the RA and across the tricuspid annulus until it is clearly in the RV (under fluoroscopic monitoring, using the right anterior oblique [RAO] view) (see Fig. 4.4 ). It is then withdrawn across the tricuspid orifice while maintaining a slight clockwise torque for good contact with the septum until a His potential is recorded. Initially, a large ventricular electrogram can be observed; then, as the catheter is withdrawn, the right bundle (RB) potential can appear (manifesting as a narrow spike less than 30 milliseconds before the ventricular electrogram). When the catheter is further withdrawn, the atrial electrogram appears and grows larger. The His potential usually appears once the atrial and ventricular electrograms are approximately equal in size and is manifest as a biphasic or triphasic deflection interposed between the local atrial and ventricular electrograms. If the first pass was unsuccessful, the catheter should be passed again into the RV and withdrawn with a slightly different rotation. If, after several attempts, a His potential cannot be recorded using a fixed-tip catheter, the catheter should be withdrawn and reshaped, or it may be exchanged with a deflectable-tip catheter. Once the catheter is in place, a stable recording can usually be obtained. Occasionally, continued clockwise torque on the catheter shaft is required to obtain a stable HB recording, which can be accomplished by looping the catheter shaft remaining outside the body and fixing the loop by placing a couple of towels on it, or by twisting the connection cable in the opposite direction so that it maintains a gentle torque on the catheter.

When the access is from the SVC, it is more difficult to record the His potential because the catheter does not lie across the superior margin of the tricuspid annulus. In this case, a deflectable-tip catheter is typically used, advanced into the RV, positioned near the HB region by deflecting the tip superiorly to form a J shape, and then withdrawing the catheter so that it lies across the superior margin of the tricuspid annulus. Alternatively, the catheter can be looped in the RA (“figure-of-6” position); then the body of the loop is advanced into the RV so that the tip of the catheter is pointing toward the RA and lying on the septal aspect of the RA. Gently withdrawing the catheter can increase the size of the loop and allow the catheter tip to rest on the HB location.

Recording of the HB electrogram can also be obtained via the retrograde arterial approach. Using this approach, the catheter tip is positioned in the noncoronary sinus of Valsalva (just above the aortic valve) or in the left ventricular outflow tract (LVOT), along the interventricular septum (just below the aortic valve).

Coronary Sinus Catheter

A femoral, internal jugular, or subclavian vein can be used to access the CS. It is easier to cannulate the CS using the right internal jugular or left subclavian vein versus the femoral vein because the CS valve is oriented anterosuperiorly and, when prominent, can prevent easy access to the CS from the femoral venous approach. A fixed-tip, 6 Fr decapolar electrode catheter is typically used for access from the SVC, whereas a deflectable-tip catheter is preferred for CS access from the femoral veins.

The standardized RAO and left anterior oblique (LAO) fluoroscopic views are used to guide placement of catheters in the CS. Although the CS cannot be directly visualized with standard fluoroscopy, the epicardial fat found in the posteroseptal space just posterior to the CS ostium (os) can be visualized as a characteristic radiolucency on cine fluoroscopy in the RAO projection, where the cardiac and diaphragmatic silhouettes meet.

When cannulating the CS from the SVC approach, the LAO view is used, the catheter tip is directed to the left of the patient, and the catheter is advanced with some clockwise torque to engage the CS os; electrodes should resemble rectangles rather than ovals when the catheter tip is properly oriented to advance into the CS. Once the CS os is engaged, the catheter is further advanced gently into the CS, so that the most proximal electrodes lie at the CS os (see Fig. 4.4 ).

During cannulation of the CS from the IVC approach, the tip of the catheter is first placed into the RV, in the RAO fluoroscopy view, and flexed downward toward the RV inferior wall. Subsequently, the catheter is withdrawn until it lies at the inferoseptal aspect of the tricuspid annulus. In the LAO or RAO view, the catheter is then withdrawn gently with clockwise rotation until the tip of the catheter drops into the CS os. Afterward, the catheter is advanced into the CS concomitantly with gradual release of the catheter curve ( Fig. 4.5 ). Alternatively, the tip of the catheter is directed toward the posterolateral RA wall and advanced with a tight curve to form a loop in the RA, in the LAO view, with the tip directed toward the inferomedial RA. The tip is then advanced with gentle up-down, right-left manipulation using the LAO and RAO views to cannulate the CS. In the RAO view, the atrioventricular (AV) fat pad (containing the CS) appears as more radiolucent than surrounding heart tissue.

Fluoroscopic Views of Catheters in a Study of Typical Atrial Flutter.

A 20-pole Halo catheter is positioned along the tricuspid annulus. The coronary sinus (CS) catheter was introduced from a femoral venous approach. The ablation catheter (Abl) is at the cavotricuspid isthmus. LAO, Left anterior oblique; RAO, right anterior oblique.

When attempting CS cannulation, the catheter can enter the RV, and premature ventricular complexes (PVCs) or VT can be observed. Catheter position in the right ventricular outflow tract (RVOT) can be misleading and simulate a CS position. Confirming appropriate catheter positioning in the CS can be achieved by fluoroscopy and recorded electrograms. In the LAO view, further advancement in the CS directs the catheter toward the left heart border, where it curves toward the left shoulder. Conversely, advancement of a catheter lying in the RVOT leads to an upward direction of the catheter toward the pulmonary artery. In the RAO view, the CS catheter is directed posteriorly, posterior to the AV sulcus, whereas the RVOT position is directed anteriorly. Recording from the CS catheter shows simultaneous atrial and ventricular electrograms, with the atrial electrogram falling in the later part of the P wave, whereas a catheter lying in the RVOT records only a ventricular electrogram. The catheter can also pass into the LA via a patent foramen ovale, in which case it takes a straight course toward the left shoulder, and all recordings are atrial.

If used, the CS catheter should be placed first because its positioning can be impeded by the presence of other catheters. It is also recommended that the CS catheter sheath be sutured to the skin to prevent displacement of the catheter during the course of the EP study.

Anatomical Considerations

Knowledge of septal anatomy and its relationship with adjacent structures is essential to ensure safe and effective access to the LA. Many apparent atrial septal structures are not truly septal. The true interatrial septum is limited to the floor of the fossa ovalis (primary septum), the flap valve, and the anteroinferior rim of the fossa. Therefore the floor of the fossa (with an average diameter of 18.5 ± 6.9 mm [vertically] and 10.0 ± 2.4 mm [horizontally] and 1 to 3 mm in thickness) is the target for atrial septal crossing ( Fig. 4.6 ). The area between the superior border of the fossa and the mouth of the SVC is an infolding of the atrial musculature filled with adipose tissue (corresponding to the pericardial transverse sinus and the anterosuperior interatrial groove). Although this area is often described incorrectly as the “septum secundum,” it is not really a true septum, and puncture in this region would lead to exiting the heart. The infolded groove ends at the superior margin (superior rim) of the fossa ovalis. The anteroinferior muscular buttress anchors the primary septum to the muscular ventricular septum and attaches to the central fibrous body (which is composed of the right fibrous trigone and the AV portion of the membranous septum) just beneath the noncoronary aortic sinus. Anterior and superior to the fossa ovalis, the RA wall overlies the aortic root. Advancing the transseptal needle in this area can puncture the aorta.

Anatomy of the Atrial Septum.

En face view of the atrial septum, observed from a 35 right anterior oblique view. Ao, Ascending aorta; CS, coronary sinus; ER, eustachian ridge; ICV, inferior caval vein; MS, membranous septum; N, noncoronary aortic sinus; OF, oval fossa; R, right coronary aortic sinus; RIPV, right inferior pulmonary vein; RSPV, right superior pulmonary vein; RV, right ventricle; SCV, superior caval vein; TVA, tricuspid valve attachment.

(From Mori S, Fukuzawa K, Takaya T, et al. Clinical cardiac structural anatomy reconstructed within the cardiac contour using multidetector-row computed tomography: atrial septum and ventricular septum. Clin Anat . 2016;29:342–352.)

Understanding the attitudinal anatomical relationships of the atrial septum and adjacent structures as well as the fluoroscopic anatomy based on conventional landmarks is critical for a safe and successful transseptal puncture procedure. When the heart is viewed in an attitudinally correct orientation (as it lies within the chest), the RA lies rightward and anterior, while the LA lies posterior, leftward, and slightly superior in relation to the RA. The aortic root runs along the anterior aspect of the interatrial septum ( Fig. 4.7 ). The fossa ovalis is located inferior and posterior relative to the noncoronary aortic sinus, and posterior to the triangle of Koch. The plane of the interatrial septum is slanted from left anterior to right posterior, with a mean orientation of 37 degrees, but can vary from 19 to 53 degrees. The orientation of the atrial septum orientation was found to strongly correlate with the direction of the CS, despite a wide range of variability in our patient population. Hence, typically the interatrial septum is almost perpendicular to the plane of the screen in the LAO 50- to 60-degree projection angle, and horizontal in the RAO 30- to 40-degree projection angle. However, adjustment of the RAO and LAO projection angles can be required to account for rotation of the interatrial septum observed in some patients. This can be facilitated by aligning the RAO projection to an angle where the proximal part of CS catheter lies perpendicular to the screen or a His recording catheter is pointing directly toward the screen.

Volume-Rendered Images of the Atrial Septum.

(A) The “atrial septum” (AS) is merged with the fluoroscopy-like image. White arrows show the radiolucent band. Note that the oval fossa (OF) , interatrial fold, and anteroinferior muscular buttress were reconstructed as one piece (red) . Only the OF and muscular buttress are the true AS. (B) The ascending aorta (Ao) , coronary sinus (CS) , and middle coronary vein (MCV) are added. The yellow arrow indicates where the inferior free wall of the right atrium directly faces the inferior pyramidal space. AIV, Anterior interventricular vein; GCV, great cardiac vein; L, left coronary aortic sinus; LAO, left anterior oblique; N, noncoronary aortic sinus; R, right coronary aortic sinus; RAO, right anterior oblique.

(From Mori S, Fukuzawa K, Takaya T, et al. Clinical cardiac structural anatomy reconstructed within the cardiac contour using multidetector-row computed tomography: atrial septum and ventricular septum. Clin Anat . 2016;29:342–352.)

Anticoagulation

Anticoagulation is essential for prevention of thromboembolism during any left-sided heart catheterization. Current recommendations advocate that IV heparin bolus be administered immediately after or, preferably, just before puncturing the atrial septum, followed by intermittent boluses or continuous heparin infusion to maintain an elevated ACT (300 to 400 seconds), even in patients on uninterrupted therapeutic doses of oral anticoagulation. However, recent evidence found that unfractionated heparin displays unexpected slow anticoagulation kinetics in a significant proportion of patients for up to 20 minutes after infusion (reflected in ACTs less than 300 seconds). Hence, some investigators have suggested administering IV heparin at least 10 minutes before transseptal puncture and assessing ACT at 10 minutes with an additional unfractionated heparin infusion in patients with subtherapeutic ACT.

Fluoroscopy-Guided Transseptal Catheterization

Equipment required for atrial septal puncture includes the following: an 8 Fr transseptal sheath for LA cannulation (e.g., SR0, SL series, Mullins, or Agilis NxT Steerable sheath, St. Jude Medical, Minnetonka, MN, United States), a 0.032-inch J guidewire, a Brockenbrough needle (e.g., BRK, St. Jude Medical), and a 190-cm, 0.014-inch guidewire. The transseptal sheaths and Brockenbrough needles are available in two different lengths; it is important to ensure that the length of needle matches that of the sheath.

Venous access is obtained via the femoral vein, preferably the right femoral vein because it is closer to the operator. The sheath, dilator, and guidewires are flushed with heparinized saline. The transseptal sheath-dilator assembly is advanced over a 0.032-inch J guidewire under fluoroscopy guidance into the SVC (to the level of the tracheal carina). The guidewire is then withdrawn, thus leaving the sheath and its dilator locked in place. The dilator within the sheath is flushed and attached to a syringe to avoid introduction of air into the RA.

Attention is then directed to preparing the transseptal needle. The Brockenbrough needle comes prepackaged with an inner stylet, which may be left in place to protect it as it is advanced within the sheath. Alternatively, the inner stylet may be removed and the needle connected to a pressure transducer line (pressure monitoring through the Brockenbrough needle will be required during the transseptal puncture); continuous flushing through the Brockenbrough needle is used while advancing the needle into the dilator. A third approach, when the use of contrast injection is planned, is to attach the Brockenbrough needle to a standard three-way stopcock via a freely rotating adapter. A 10-mL syringe filled with radiopaque contrast is attached to the other end of the stopcock while a pressure transducer line is attached to the third stopcock valve for continuous pressure monitoring. The entire apparatus should be vigorously flushed to ensure that no air bubbles are present within the circuit.

Before making an attempt at puncturing the atrial septum, it is important to ensure that all equipment is working properly, especially the pressure transducer attached to the needle. If this detail is not attended to prior to the septal puncture attempt, it becomes difficult to interpret a flat pressure tracing when the needle tip is supposedly in the LA cavity. This may mean the needle is in fact in the LA but the stopcock on the pressure tubing is turned incorrectly, or that the wrong tubing was connected to the needle hub, or that the needle tip is not in the LA. Assuring that the pressure system is working properly by “flicking” the needle shaft and seeing its corresponding pressure reverberation waveform obviates uncertainty as to whether the connections are correct. In addition, taking note of baseline blood pressure and appearance of the left heart border on fluoroscopy are important for reference; unanticipated decreases in blood pressure or decreased motion of the left heart border, compared to baseline, may be early clues to a developing pericardial effusion.

Engaging the fossa ovalis.

The Brockenbrough needle is advanced into the dilator until the needle tip is within 1 to 2 cm of the dilator tip. The needle tip must be kept within the dilator at all times, except during actual septal puncture. This can be ensured by holding the sheath-dilator assembly by the left hand, and holding the needle by the right hand, while minding a safe distance of the proximal needle hub from the dilator. The curves of the dilator, sheath, and needle (as indicated by the side port of the sheath and the pointer on the proximal hub of the needle) should be aligned so that they are all in agreement and not contradicting each other. The sheath, dilator, and needle assembly is then rotated leftward and posteriorly (usually with the Brockenbrough needle arrow pointing at the 3 to 6 o’clock position relative to its shaft) and retracted caudally as a single unit (while maintaining the relative positions of its components) to engage the tip of the dilator into the fossa ovalis. Under fluoroscopy monitoring (30-degree LAO view), the dilator tip moves slightly leftward on entering the RA and then leftward again while descending below the aortic root. A third abrupt leftward movement (“jump”) below the aortic root indicates passage over the limbus into the fossa ovalis ( Fig. 4.8 ). This jump generally occurs at the level of the HB region (marked by an EP catheter recording the HB potential). If the sheath and dilator assembly is pulled back farther than intended (i.e., below the level of the fossa and HB region), the needle should be withdrawn and the guidewire placed through the dilator into the SVC. The sheath and dilator assembly is then advanced over the guidewire into the SVC and repositioning attempted, as described earlier. The sheath and dilator assembly should never be advanced without the guidewire at any point during the procedure.

Fluoroscopic Views During Transseptal Catheterization.

Right anterior oblique (RAO, left panels) and left anterior oblique (LAO, right panels) are shown. (A) Initially, the transseptal sheath-dilator assembly is advanced into the superior vena cava. (B) The transseptal assembly is withdrawn into the high right atrium. (C) With further withdrawal, the dilator tip abruptly moves leftward, indicating passage over the limbus into the fossa ovalis at the level of the His bundle catheter. At the fossa ovalis, the dilator tip has an anteroposterior orientation in the RAO view and a leftward orientation in the LAO view. (D) The transseptal assembly is advanced across the atrial septum. CS, Coronary sinus.

Confirming position in the LA.

After passage through the fossa ovale and before advancing the dilator and sheath, an intraatrial position of the needle tip within the LA, rather than the ascending aorta or posteriorly into the pericardial space, needs to be confirmed. Recording an LA pressure waveform from the needle tip confirms an intraatrial location ( Fig. 4.9 ). An arterial pressure waveform indicates intraaortic position of the needle. Absence of a pressure wave recording can indicate needle passage into the pericardial space or sliding up and not puncturing through the atrial septum. A second method is injection of contrast through the needle to assess the position of the needle tip. Opacification of the LA (rather than the pericardium or the aorta) verifies the successful transseptal access. Alternatively, passing a 0.014-inch floppy guidewire through the Brockenbrough needle into a left-sided PV (beyond the cardiac silhouette in the LAO fluoroscopy view) helps verify that needle tip position is within the LA. If the guidewire cannot be advanced beyond the fluoroscopic border of the heart, atrial free-wall puncture with pericardial needle location should be suspected. In addition, aortic puncture should be suspected if the guidewire seems to follow the course of the aorta. In these situations, contrast should be injected to assess the position of the Brockenbrough needle before advancing the transseptal dilator. Sometimes, the guidewire enters the LA appendage rather than a PV; in this setting, a clockwise torque of the sheath and dilator assembly can help direct the guidewire posteriorly toward the ostium of the left superior or left inferior PV.

Fluoroscopic Views and Simultaneous Electrical and Pressure Recordings During Transseptal Catheterization.

Left, The transseptal assembly is in the right atrium (RA) , indicated by typical A and V waves of right-heart pressure tracing. Middle, The pressure waveform is dampened somewhat as the catheter tip abuts the septum. Right, The needle is across the atrial septum, and characteristic waves (V larger than A) are seen. CS, Coronary sinus; CS _dist , distal coronary sinus; CS _prox , proximal coronary sinus; LA, left atrium; LAO, left anterior oblique; P, pressure.

Once the position of the needle tip is confirmed to be in the LA, both the sheath and dilator are advanced as a single unit over the needle by using one hand while fixing the Brockenbrough needle in position with the other hand (to prevent any further advancement of the needle). Preferably, the sheath-dilator assembly is advanced into the LA over a guidewire placed distally into a left-sided PV, which helps direct the path of the assembly as it enters the LA and minimize the risk of inadvertent puncture of the LA free wall, especially in the presence of an elastic or redundant septum that can suddenly release, resulting in a significant forward lurch of the dilator and sheath. Once the dilator tip is advanced into the LA over the needle tip, the needle and dilator are firmly stabilized as a unit—to prevent any further advancement or withdrawal of the needle and dilator—and the sheath is advanced over the dilator into the LA. It is important to keep the needle across the septum at this time to facilitate advancement of the sheath through the puncture site. In some cases, the septum is very stiff (after prior transseptal procedures, especially) and attempts to advance the sheath into the LA result in bowing of the assembly in the RA, risking “backing out” of the dilator from the LA. In such cases, rotating the entire apparatus such that the dilator points toward the head or right superior PV can facilitate passage of the sheath through the septum, since the pushing force administered along the long axis of the assembly is now transmitted in line with the intended direction of the sheath tip (as opposed to pushing from the groin and hoping the sheath advances more sideways, toward the left shoulder). Once the transseptal sheath tip is within the LA, the dilator and needle are withdrawn slowly during continuous flushing through the needle or while suction is maintained through a syringe placed on the sheath side port to minimize the risk of air embolism and while fixing the sheath with the other hand to prevent dislodgment outside the LA. The sheath should be aspirated until blood appears without further bubbles; this usually requires aspiration of approximately 5 mL and sometimes “flicking” the sheath hub with a finger is needed to dislodge trapped air. The sheath is then flushed with heparinized saline at a flow rate of 3 mL/min during the entire procedure.

The mapping-ablation catheter is advanced through the sheath into the LA. This is safely done by advancing the catheter tip to the tip of the sheath, and while holding the catheter steady, withdrawing the sheath slightly over the catheter, exposing about 2 cm of the catheter tip. In so doing, one ensures that the catheter (stiffened by being inside the sheath) does not perforate the atrial wall. Flexing the catheter tip and applying clockwise and counterclockwise torque to the sheath help confirm free movement of the catheter tip within the LA, rather than possibly in the pericardium. It is important to recognize that merely recording atrial electrograms does not confirm an LA catheter location because an LA recording can be obtained from the epicardial surface of the LA, from the RA, or even the aortic root.

Intracardiac Echocardiography–Guided Transseptal Catheterization

Although fluoroscopy provides sufficient information to allow safe transseptal puncture in most cases, variations in septal anatomy, atrial or aortic root dilation, the need for multiple punctures, and the desired ability to direct the catheter to specific locations within the LA can make fluoroscopy inadequate for complex LA ablation procedures. Intraoperative TEE allows identification of the fossa ovalis and its relation to surrounding structures and provides real-time evaluation of the atrial septal puncture procedure, with demonstration of tenting of the fossa prior to entry into the LA and visualization of the sheath advancing across the septum. However, the usefulness of TEE is limited by the fact that the probe obstructs the fluoroscopic field, and it is impractical in the unanesthetized patient. ICE, which provides similar information on septal anatomy, can be used for the conscious patient and does not impede fluoroscopy.

The intent of ICE-guided transseptal catheterization is to image intracardiac anatomy and identify the exact position of the distal aspect of the transseptal dilator along the atrial septum—in particular, to assess for tenting of the fossa ovalis with the dilator tip.

Two types of ICE imaging systems are currently available: the electronic phased-array ultrasound catheter and the mechanical ultrasound catheter. The phased-array ultrasound catheter sector imaging system (AcuNav, Siemens Medical Solutions, Malvern, PA, United States) uses an 8 or 10 Fr catheter that has a forward-facing 64-element vector phased-array transducer scanning in the longitudinal plane. The catheter has a four-way steerable tip (160 degree anteroposterior or left-right deflections). The catheter images a sector field oriented in the plane of the catheter. The mechanical ultrasound catheter radial imaging system (Ultra ICE, EP Technologies, Boston Scientific, San Jose, CA, United States) uses a 9-MHz catheter-based ultrasound transducer contained within a 9 Fr (110-cm length) catheter shaft. It has a single rotating crystal ultrasound transducer that images circumferentially for 360 degrees in the horizontal plane. The catheter is not freely deflectable.

When using the mechanical radial ICE imaging system, a 9 Fr sheath (preferably a long, preshaped sheath) for the ICE catheter is advanced via a femoral venous access. To enhance image quality, all air must be eliminated from the distal tip of the ICE catheter by flushing vigorously with 5 to 10 mL of sterile water. The catheter then is connected to the ultrasound console and advanced until the tip of the rotary ICE catheter images the fossa ovalis. Satisfactory imaging of the fossa ovalis for guiding transseptal puncture is viewed from the mid-RA ( Fig. 4.10 ).

Intracardiac Echocardiography (ICE)-Guided Transseptal Puncture Using the Ultra-ICE Catheter.

These ICE images are obtained with the transducer placed in the right atrium (RA) . (A) The RA, fossa ovalis (arrowheads) , left atrium (LA) , and aorta (AO) are visualized. (B) The transseptal needle is properly positioned, with tenting (yellow arrow) against the mid-interatrial septum at the fossa ovalis. RV, Right ventricle.

The AcuNav ICE catheter is introduced under fluoroscopy guidance through a 23-cm femoral venous sheath. Once the catheter is advanced into the mid-RA with the catheter tension controls in neutral position (the ultrasound transducer oriented anteriorly and to the left), the RA, tricuspid valve, and RV are viewed. This is called the home view ( Fig. 4.11A ). Gradual clockwise rotation of a straight catheter from the home view allows sequential visualization of the aortic root and the pulmonary artery (see Fig. 4.11B ), followed by the CS, the mitral valve, the LA appendage orifice, and a cross-sectional view of the fossa ovalis (see Fig. 4.11C and D ). The mitral valve and interatrial septum are usually seen in the same plane as the LA appendage. Posterior deflection or right-left steering of the imaging tip in the RA, or both, is occasionally required to optimize visualization of the fossa ovalis; the tension knob (lock function) can then be used to hold the catheter tip in position. Further clockwise rotation beyond this location demonstrates images of the left PV ostia (see Fig. 4.11E ). The optimal ICE image to guide transseptal puncture demonstrates adequate space beyond the interatrial septum on the LA side and clearly identifies adjacent structures, but it does not include the aortic root because it would be too anterior for the interatrial septum to be punctured safely. In patients with an enlarged LA, a cross-sectional view that includes the LA appendage is also optimal if adequate space exists beyond the atrial septum on the LA side.

Phased-Array Intracardiac Echocardiography (ICE).

Phased-array ICE (AcuNav) serial images with the transducer placed in the middle right atrium (RA) demonstrate serial changes in tomographic imaging views following clockwise rotation of the transducer. Each view displays a left-right orientation marker to the operator’s left side (i.e., craniocaudal axis projects from image right to left ). (A) Starting from the home view, the RA, tricuspid valve (yellow arrowheads) , and right ventricle (RV) are visualized. (B) Clockwise rotation brings the aorta (AO) into view. (C) Further rotation allows visualization of the interatrial septum (green arrows) , left atrium (LA) , coronary sinus (CS) , left ventricle (LV) , and mitral valve (red arrowheads) . (D) Subsequently, the left atrium appendage (LAA) becomes visible. (E) The ostia of the left superior pulmonary vein (LSPV) and left inferior PV (LIPV) can be visualized with further clockwise rotation. PA, Pulmonary artery.

(Courtesy AcuNav, Siemens Medical Solutions, Malvern, PA, United States.)

The sheath-dilator-needle assembly is introduced into the RA, and the dilator tip is positioned against the fossa ovalis, as described earlier. Before advancing the Brockenbrough needle, continuous ICE imaging should direct further adjustments in the dilator tip position until ICE confirms that the tip is in intimate contact with the middle of the fossa, confirms proper lateral movement of the dilator toward the fossa, and excludes inadvertent superior displacement toward the muscular septum and aortic valve. With further advancement of the dilator, ICE demonstrates tenting of the fossa ( Figs. 4.10 and 4.12 ). If the distance from the tented fossa to the LA free wall is small, minor adjustments in the dilator tip position can be made to maximize the space. The Brockenbrough needle is then advanced. With successful transseptal puncture, a palpable pop is felt, and sudden collapse of the tented fossa is observed (see Fig. 4.12 ). Advancement of the needle is then immediately stopped. Saline infusion through the needle is visualized on ICE as microbubbles in the LA, thus confirming successful septal puncture. With no change in position of the Brockenbrough needle, the transseptal dilator and sheath are advanced over the guidewire into the LA, as described earlier.

Phased-Array Intracardiac Echocardiography (ICE)-Guided Transseptal Puncture.

(A) These ICE images, with the transducer placed in the right atrium (RA) , show a transseptal dilator tip (yellow arrowhead) lying against the interatrial septum (green arrows) . (B) With further advancement of the dilator, ICE demonstrates tenting of the interatrial septum at the fossa ovalis. (C) Advancement of the transseptal needle is then performed, with the needle tip visualized in the left atrium (LA) , and tenting of the interatrial septum is lost.

Alternative Methods for Difficult Transseptal Catheterization

In some cases, the conventional approach using a Brockenbrough needle sheath fails to pierce the septum because of the presence of a small fossa area, a thick interatrial septum, fibrosis and scarring of the septum from previous interventions, or an aneurysmal septum with excessive laxity. Applying excessive force to the needle-dilator-sheath assembly against a resistant septum (which can be seen as bending and buckling of the assembly in the RA) can lead to building pressure of the needle tip on the septum, which can potentially lead to an uncontrolled sudden jump of the assembly once across the fossa ovalis, thus perforating the opposing lateral LA wall. Similarly, excessive tenting of the interatrial septum (beyond halfway into the LA) can bring it in close proximity to the lateral LA wall, so that the needle can potentially puncture the lateral LA wall once across the septum. Some of these difficulties can be overcome by manual reshaping of the curvature of the Brockenbrough needle tip, applying slight rotation on the needle and sheath assembly to puncture a different point on the fossa ovalis, or using a sharper transseptal needle type (BRK-1 extra sharp).

Other tools designed specifically for transseptal puncture, including the SafeSept Transseptal Guidewire and the radiofrequency (RF)-powered needle, can help minimize pressure application to the needle as it crosses the septum and tenting of the septum, which can potentially reduce the chances of sudden advancement through the lateral LA as the needle crosses the septum.

Transseptal Puncture in the Presence of Atrial Septal Defect Repair

Transseptal catheterization is feasible and safe in most patients with prior surgical repair of an atrial septal defect or a patent foramen ovale. Nonetheless, because of the altered anatomical landmarks after repair, fluoroscopic guidance for transseptal puncture is not as reliable, and the procedure can be challenging. In these patients, an understanding of the method of repair and utilization of ICE guidance are essential.

In patients with a septal stitch or pericardial or Dacron patch, puncture can be achieved through the thickened septum or the patch. However, transseptal access is typically not achievable through a Gore-Tex patch (W.L. Gore & Associates, Flagstaff, AZ, United States) because of its resistant texture; instead, puncture can be performed directly through neighboring native interatrial tissue. However, when the patch is wide, sufficient free septal tissue for transseptal puncture may not be available, in which setting transseptal access to the LA may not be feasible.

In patients with atrial septal defect closure devices, puncture is preferably performed at the portion of the septum located inferior and posterior to the closure device and not through the device itself ( eFig. 4.5 ). When areas of native septum are not available for transseptal access, recent reports described successful LA access through a direct puncture of the closure device.

Transseptal Puncture in a Patient With Atrial Septal Defect Closure Device.

A left anterior oblique fluoroscopic view shows the transseptal needle crossing the atrial septum at a site inferior to an Amplatzer occluder device, in a portion of the native interatrial septum not covered by the closure device. CS, Coronary sinus catheter; HB, His bundle catheter; RA, right atrial catheter.

Complications of Atrial Transseptal Puncture

Injury to cardiac and extracardiac structures is the most feared complication. Because of its stiffness and large caliber, the transseptal dilator should never be advanced until the position of the Brockenbrough needle is confirmed with confidence. Advancing the dilator into an improper location, such as the aortic root, can be fatal. Therefore many operators recommend the use of ICE-guided transseptal puncture, especially for patients with normal LA chamber size.

Anatomical Considerations

The pericardium is a double-walled sac that contains the heart and the roots of the great arteries, SVC, and PVs. By separating the heart from its surroundings—the descending aorta, lungs, diaphragm, esophagus, trachea, and tracheobronchial lymph nodes—the pericardial space allows complete freedom of cardiac motion within this sac.

The pericardium consists of two sacs intimately connected with one another: an outer fibrous envelope (the fibrous pericardium) and an inner serous sac (the serous pericardium). The fibrous pericardium (0.8 to 2.5 mm in thickness) consists of fibrous tissue and forms a flask-shaped bag, the neck of which is closed by its fusion with the adventitia of the great vessels, while its base is attached by loose fibroareolar tissue to the central tendon and to the muscular fibers of the left side of the diaphragm. The fibrous pericardium is also attached to the posterior sternal surface by superior and inferior sternopericardial ligaments. These attachments are essential to maintain the normal cardiac position in relation to the surrounding structures, to restrict the volume of the thin-walled cardiac chambers (RA and ventricle), and also to serve as direct protection against injuries.

The serous pericardium is a delicate membrane that lies within the fibrous pericardium and lines its walls; it is composed of two layers: the parietal pericardium and the visceral pericardium. The parietal pericardium is fused to and inseparable from the fibrous pericardium. On the other hand, the visceral pericardium, which is composed of a single layer of mesothelial cells, is part of the epicardium (i.e., the layer immediately outside of the myocardium) and covers the heart and the great vessels except for a small area on the posterior wall of the atria. The visceral layer extends to the beginning of the great vessels, and is reflected from the heart onto the parietal layer of the serous pericardium along the great vessels in tube-like extensions. This happens at two areas: where the aorta and pulmonary trunk leave the heart and where the SVC, IVC, and PVs enter the heart.

The pericardial cavity or sac is a continuous virtual space that lies between the parietal and visceral layers of serous pericardium. The heart invaginates the wall of the serous sac from above and behind, and practically obliterates its cavity, the space being merely a potential one. The pericardial sac normally contains 20 to 40 mL of clear fluid that occupies the virtual space between the two layers and serves as a lubricant.

The lateral surfaces of the heart are predominantly covered by the lungs, prohibiting a direct percutaneous access to the pericardial space. The anterior borders of the lungs extend vertically downward along the midsternal line. The right lung anterior border curves laterally and downward at the level of the sixth costal cartilage on the right side. On the left side, however, the anterior border of the lung diverges laterally at an earlier point (at the level of the fourth costal cartilage), forming the cardiac notch, and reaches the parasternal line at the fifth costal cartilage (about 1 inch from the sternal border) before turning medially and downward (as the lingula) to the sixth sternocostal junction ( eFig. 4.6 ). Thus, the subxiphoid region offers a window for direct pericardial access without traversing the lungs. Nonetheless, even with the subxiphoid approach, a needle angulated too far in the lateral direction can potentially puncture the left lung and result in pneumothorax.

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