Pericardiocentesis under two-dimensional echocardiographic guidance in loculated pericardial effusion

Complications of Percutaneous Pericardiocentesis under Fluoroscopic Guidance

Complications in 352 cases of fluoroscopy-guided percutaneous pericardiocentesis accomplished through an indwelling catheter were reviewed following surgery and non-surgery. Thirteen major complications were found, namely 3 cardiac perforations, 2 cardiac arrhythmias, 4 cases of arterial bleeding, 2 cases of pneumothorax in children, one infection, and one major vagal reaction. No significant difference in complications was found between pericardiocenteses for pericardial effusions after cardiac surgery (n = 208) and those for effusions of non-surgical (n = 144) origin. Fluoroscopy-guided pericardiocentesis by the subxiphoid approach with placement of an indwelling catheter is a safe method for achieving pericardial drainage in both surgical and non-surgical effusions. Accidental cardiac perforation with a fine needle is a minor complication as long as the needle is directed towards the anterior diaphragmatic border of the right ventricle and drainage is achieved with a reliable indwelling catheter.

CASPER, a Computer ASsisted PERicardial puncture system: first clinical results

Pericardial puncture is the percutaneous insertion of a needle into the pericardial space to drain a pathological pericardial effusion. The challenge for the operating surgeon is to reach percutaneously a target zone in the vicinity of the mobile heart, in a soft-tissue environment. The surgeon's ability to accomplish this depends on his own mental picture of the effusion. CASPER is a navigation software using an optical localizer which assists the surgeon by enhancing the representation of the effusion and guiding the needle's progress. Using a localized and calibrated echographic probe, the surgeon acquires a set of images in the region of interest. This zone is then manually segmented on each image, a common zone is computed, and the surgeon defines a trajectory for the needle. During the puncture procedure, the surgeon follows the position of the localized needle on a computer monitor. After initial validation on an experimental phantom, a feasibility study was performed using canine and porcine models. The optical localization device was changed from an Optotrak to a Polaris device for easier use in the clinical setting. Prior to clinical application, various tests were performed concerning the mobility of the thoracic cage, the reproducibility of the thoracic position over several apneas, and the stability of anatomic structures relative to the thoracic cage. Finally, a first clinical application was successfully performed using this system. The present paper reports on these last two stages.

Accurate guidance for percutaneous access to a specific target in soft tissues: preclinical study of computer-assisted pericardiocentesis

In the field of percutaneous access to soft tissues, our project was to improve classical pericardiocentesis by performing accurate guidance to a selected target, according to a model of the pericardial effusion acquired through three-dimensional (3D) data recording. Required hardware is an echocardiographic device and a needle, both linked to a 3D localizer, and a computer. After acquiring echographic data, a modeling procedure allows definition of the optimal puncture strategy, taking into consideration the mobility of the heart, by determining a stable region, whatever the period of the cardiac cycle. A passive guidance system is then used to reach the planned target accurately, generally a site in the middle of the stable region. After validation on a dynamic phantom and a feasibility study in dogs, an accuracy and reliability analysis protocol was realized on pigs with experimental pericardial effusion. Ten consecutive successful punctures using various trajectories were performed on eight pigs. Nonbloody liquid was collected from pericardial effusions in the stable region (5 to 9 mm wide) within 10 to 15 minutes from echographic acquisition to drainage. Accuracy of at least 2.5 mm was demonstrated. This study demonstrates the feasibility of computer-assisted pericardiocentesis. Beyond the simple improvement of the current technique, this method could be a new way to reach the heart or a new tool for percutaneous access and image-guided puncture of soft tissues. Further investigation will be necessary before routine human application.

Echocardiographically guided pericardiocentesis: evolution and state-of-the-art technique

Percutaneous pericardiocentesis was introduced during the 19th century and became a preferred technique for the management of pericardial effusion by the early 20th century. Until the era of two-dimensional echocardiographically guided pericardiocentesis, however, the procedure was essentially "blind," and serious complications were comparatively common, an outcome that resulted in an increased preference for surgical solutions. Because two-dimensional echocardiography facilitates direct visualization of cardiac structures and adjacent vital organs, percutaneous pericardiocentesis can be performed with minimal risk. Since its inception in 1979 (19 years ago), the echocardiographically guided pericardiocentesis technique has continued to evolve. Important procedural adaptations and modifications that optimize safety, simplicity, and patient comfort and minimize the recurrence of effusion have been defined and incorporated. This technique has been proved to be safe and effective. A detailed step-by-step description of the procedure and the necessary precautions to optimize success and safety is presented herein.

Outpatient two-dimensional echocardiography-guided pericardiocentesis

Two-dimensional echocardiography-guided pericardiocentesis is an accepted, safe, and cost-effective procedure. Carefully selected patients can be treated with this technique in an outpatient setting. A consecutive series of outpatient echocardiography-directed pericardiocentesis performed for diagnostic or therapeutic indications is described. Appropriate technique and precautions are discussed.

Echocardiography in thoracic trauma

The availability of bedside ultrasonography can dramatically impact the care of patients with cardiac or aortic injuries. A focused, limited echocardiographic examination in the initial evaluation of victims with thoracic injuries can provide vital information the clinician needs to expedite the management of these patients. This article reviews the current use of transthoracic and transesophageal echocardiography in patients with thoracic trauma.

Echocardiography-guided pericardiocentesis with a needle attached to a probe

Pericardiocentesis with a needle attached to a probe was performed under two-dimensional echocardiographic guidance in 9 patients with pericardial effusion after cardiac operations. The first 5 mm of the tip of a puncture needle for percutaneous transhepatic cholangiodrainage is scratched with a scalpel to give the tip high echo intensity. When the probe is placed on the skin, the direction of puncture at that probe angle appears automatically on the monitor.

Pericardio-peritoneal window for recurrent postoperative effusion. Case report

A pericardio-peritoneal window was created to relieve cardiac tamponade by recurrent effusion after heart transplantation. The effect was echocardiographically evaluated. The technique is described. It requires no sternal splitting for pericardial access and no foreign materials such as drains or shunts. The method should be considered for immunologically compromised, infection-prone patients with heart transplantation.

Pericardiocentesis guided by a pulse generator

This study was performed to compare pericardiocentesis guided by a pacing current applied through the pericardiocentesis needle with the traditional method of monitoring ST segment elevation from the needle tip electrogram. ST segment elevation was measured at 3 mm from the epicardium, after epicardial contact, after epicardial penetration and again at 3 mm from the epicardium after epicardial penetration. Two millivolts of ST segment elevation gave the highest combined positive (86%) and negative (79%) predictive value for epicardial contact by the pericardiocentesis needle between the two groups with the largest difference: 3 mm from the epicardium before contact and after epicardial penetration. Therefore, ST segment monitoring cannot reliably determine the point of epicardial contact. To determine the optimal stimulus strength for pulse generator-guided pericardiocentesis, pacing studies were performed using 2, 4, 6, 8 and 10 mA unipolar stimulus strengths. The pacing studies were performed both with and without a hemodynamically significant pericardial effusion to determine if increased pericardial pressure altered the pacing threshold. A 4 mA unipolar cathodal stimulus was chosen because it captured the ventricle only with direct contact of the epicardium. Ten dogs were instrumented and cardiac tamponade produced so that a subxiphoid approach to the epicardium with the pacing needle electrode could be attempted. During pericardiocentesis, needle tip electrograms were recorded, alternating with pacing attempts using a 4 mA unipolar stimulus. In all 10 dogs, the effusion was entered and epicardium was contacted as indicated by capture. No myocardial perforation or coronary artery or venous injuries were produced. These findings support the use of a pulse generator to guide pericardiocentesis.