Cholangioscopy

Introduction

The advantages of single-operator cholangioscopy using the catheter-based fiberoptic SpyGlass system (FSOC; SpyGlass Direct Visualization System; Boston Scientific, Marlborough, MA) include the ability of a single endoscopist to perform cholangiopancreatoscopy and the use of a disposable 4-lumen 10-Fr catheter, reusable optical fiber, and four-way tip deflection (up–down and left–right) that is passed through the working channel (4.2 mm) of a standard therapeutic duodenoscope. The device is approved by the Food and Drug Administration (FDA) for both biliary and pancreatic applications. In February 2015, a fully disposable digital single-operator cholangioscope (DSOC) was introduced in the United States.

In an ex vivo study with FSOC, Chen compared four-quadrant access, simulated biopsy, irrigation flow rates, and optical resolution between FSOC and an endoscope-based system (CHF BP-30; Olympus Medical Systems, Tokyo, Japan). The author reported that the ability to access four quadrants for visualization and biopsy with FSOC was better than with the two-way tip deflection of the endoscope-based system (odds ratio 1.7 to 2.94, p < 0.001). A preliminary ex vivo study that included five investigators compared optical quality and maneuverability between DSOC and FSOC. A biliary tract model contained fixed and variable color targets. Runs (passes of the scope) were randomized, and DSOC outperformed FSOC by a higher percentage of visualized targets (96% vs 66%), successful targeting per run, and faster run times (all comparisons p < 0.01). Further, subjective parameters of image quality and ease of use were superior ( p < 0.001).

Equipment

FSOC has a control section that houses three ports: irrigation that feeds into two 0.6-mm channels, a 0.77-mm optical probe, and a 1.2-mm accessory channel that permits passage of guidewires, intraductal lithotripsy fibers, and miniature biopsy forceps. The control section is secured with a Silastic belt just below the working channel of the duodenoscope. The disposable 3.4-mm insertion tube has four steering wires embedded in its length. The 6000-pixel optical probe is a collection of light fibers that surround optical fiber bundles and is incorporated into a polyimide sheath, providing approximately a 70-degree field of view. The connector section entails a camera processor with 1/4-inch charge-coupled device (CCD) chip, a light source, an optical coupler that interfaces the optical probe with the light source and video camera head, a medical-grade isolation transformer, and a travel cart with a three-joint arm for extension. An irrigation pump with foot pedal and monitor are available through separate vendors. The DSOC has a complementary metal-oxide semiconductor (CMOS) chip for higher resolution, magnification, and field of view (120 degrees). It has a thin copper cable for digital transmission and lacks a separate fiber optic probe that may contribute to improved catheter tip articulation. A separate suction connection with the working channel seems to permit improved irrigation capability. The processor is portable for simplified setup.

Technique

For FSOC, the optical probe is preloaded into the access/therapeutic catheter and advanced to within a few millimeters of the catheter's bending portion to reduce the potential for damage during passage across the duodenoscope's elevator and ductal strictures. The DSOC system has the optical bundle incorporated into the catheter. Advancement through the duodenoscope's working channel is similar to the endoscope-based cholangioscope. Once the duct is entered with the access catheter, the optical probe is advanced gently beyond the catheter's tip for intraductal inspection. If resistance is encountered, the control section knobs should be unlocked and fluoroscopy may be used to determine whether the catheter's tip is straight. The endoscopist has control of the four-way steering dials and may periodically lock the dials to stabilize scope position at a target during tissue acquisition or intraductal lithotripsy. Irrigation is performed through two dedicated channels facilitated by a foot pedal. Irrigation rates should be kept as low as possible to reduce the risk of cholangitis.

Clinical Use and Efficacy

Intraductal Lithotripsy

Electrohydraulic lithotripsy (EHL) or laser lithotripsy (LL) can be used to treat both bile duct and pancreatic duct stones ( Fig. 27.1, A–E , and Fig. 27.2, A–E ). Cholangioscopic or pancreatoscopic visualization during intraductal lithotripsy helps to avoid duct injury. The 1.9-Fr nitinol EHL fiber contains two coaxially insulated electrodes ending at an open tip. Water or saline immersion is necessary and, as an advantage over endoscope-based cholangioscopes, the dedicated channels for irrigation provide a sufficient medium. During immersion, sparks are generated that produce high-amplitude hydraulic pressure waves for stone fragmentation. A generator produces a series of high-voltage electrical impulses at a frequency of 1 to 20 per second, with settings ranging from a power of 50 to 100. The tip of the EHL fiber should protrude no more than 2 to 3 mm from the scope and be positioned en face with the stone while the generator's foot pedal is depressed to deliver energy.

During LL, a laser beam is transmitted via a flexible quartz fiber through the working channel of the cholangiopancreatoscope. LL requires more precise localization of the stone, and though fragmentation is enhanced by direct contact, it can lead to a “drilling” effect. The application of repetitive pulses of laser energy to the stone leads to the formation of a gaseous collection of ions and free electrons of high kinetic energy. This plasma rapidly expands as it absorbs the laser energy and then collapses, inducing a spherical mechanical shockwave between the laser fiber and the stone, leading to stone fragmentation.