Magnetically Assisted Capsule Endoscopy for Endoscopic Examination of Esophagus and Stomach—Beginning of the End of Flexible Esophagogastroscopy!

 

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Capsule endoscopy (CE) has gradually replaced radiological investigations as the procedure of choice for the evaluation of small bowel mucosal pathologies since its introduction in 2000s. Good patient tolerability and lack of need for sedation have led on to expansion of the indications of CE with attempts to use CE for the evaluation of other parts of the gastrointestinal tract like the upper gut and the colon. Observation of the esophagus and especially the stomach is difficult with conventional CE. The capsule usually transits the esophagus within seconds limiting adequate visualization of the esophageal mucosa. Also, the gastric lumen is larger in surface area and is much more difficult to be completely visualized on CE. While the antrum can be adequately evaluated, visualization of the body and fundus is suboptimal due to the larger surface area and inability to adequately distend the stomach due to lack of air insufflation. Inability to suck and remove liquid residue or bubbles and to perform diagnostic biopsies or other interventions have limited the use of conventional CE in the evaluation of gastric pathologies. For evaluation of antral vascular pathologies, CE has been proposed to be better than flexible gastroscopy as it visualizes the antrum under more physiological conditions without the effect of air insufflation that may compress ectatic vessels.[1]

To overcome the above limitations of CE, investigators have tried new CE devices that have active locomotion systems. The movement of these devices can be controlled by the user from outside and the capsule can be maneuvered toward the area of interest. Two types of active locomotion systems have been developed with one having an intrinsic locomotion device in the capsule, whereas the second system relies on an external magnetic force to control the capsule movement.[1] [2] Tortora et al devised a CE system that had four motors to steer the capsule. In this procedure, the patient initially ingests 500 mL of clear liquid for adequate distension of the stomach.[3] Thereafter, the capsule is ingested and the four propellers at the rear of the CE propel the capsule in the liquid filled stomach. The CE can be controlled wirelessly by the endoscopist using a joystick. This device has shown promise in in vitro and animal experiments. However, mechanical complexity as well as need for larger power supply to battery both the capsule and locomotion are important limitations of this system.[2] [3] [4]

In 2010, Keller et al used a capsule device (magnetic maneuverable capsule [MMC]; Given Imaging Ltd, Yoqneam, Israel; 31 × 11 mm size, 7 g weight, battery life 10 hours, 256 × 256 pixels resolution, 4 frames/ second, 156-degree field of view) for examining the esophagus. This capsule device had magnetic disks placed inside one of its domes and could be controlled from outside the body using a handheld magnetic paddle.[5] The authors demonstrated that the MMC could be longitudinally rotated and tilted along its axis for adequate mucosal inspection. Moreover, the MMC stayed longer in the esophageal lumen with better visualization of Z line as compared with the conventional esophageal capsule (ESO2, Given Imaging Ltd, Yoqneam, Israel). However, the magnetic force of the external paddle was not strong enough to hold the capsule at the GE junction and prevent its propulsion into the gastric lumen. Keller et al also evaluated the same device for the evaluation of stomach in 10 healthy volunteers and found that 7 subjects had good mucosal visibility where > 75% of the gastric mucosa was visualized, while the other 3 had moderate mucosal visibility.[6]

A CE system with similar principles, the MACE (magnetic-assisted capsule endoscope) system controlled by external magnetic paddles, was developed by Intromedic Company, Korea (MiroCam Navi, size 11 × 24 mm, weight 4.2 g, battery life 8 hours, 320 × 320 pixels resolution, 3 frames/second, field of view 170 degrees). In a pilot study among 26 volunteers, Rehman et al demonstrated that the MACE system was able to provide adequate visualization of 88 to 100% of the upper gastrointestinal tract (esophagogastric junction 92%, gastric cardia 88%, fundus 96%, body 100%, incisura 96%, antrum 96% and pylorus 100%). They reported that the image quality was not so good at the esophagogastric junction and the pylorus due to rapid transit of the capsule across these parts.[7] The same group used multiplanar reconstruction computed tomography modelling to determine the optimal sites for the placement of the capsule in the stomach that would lead to complete mucosal evaluation as well as the ideal site for the placement of the handheld magnetic paddle outside the body for optimal control of the capsule and reported encouraging results.[8] MACE system has also been studied for the evaluation of upper gastrointestinal bleeding.[9] MACE detected more focal lesions compared with conventional gastroduodenoscopy, but the number of significant lesions responsible for bleeding detected was similar in both the groups. Importantly, additional source of bleeding in the small bowel was detected by MACE in 18%. Though visualization of most parts of the upper gastrointestinal tract was satisfactory, the authors reported suboptimal evaluation of some areas such as the esophagus, gastroesophageal junction, fundus, and the duodenal bulb. They also reported that the CE findings correctly predicted safe discharge for patients. This study suggested that MACE may have a role in the rapid evaluation of acute upper gastrointestinal bleeding and maybe more appropriate when the patient is not hemodynamically stable enough for a conventional diagnostic endoscopy.

The second type of magnetically controlled capsule is a device custom made for gastric evaluation, jointly developed by Olympus Medical Systems Corporation (Tokyo, Japan) and Siemens Healthcare (Erlangen, Germany) (size 31 × 11 mm, 4 frames/second, 145 degrees field of view). The mobility of this capsule device named magnetically guided capsule endoscope could be controlled using low level magnetic fields (0.1 Tesla) delivered using magnetic resonance imaging equipment. In the pilot study published in 2010, Rey et al documented a technical success rate of 98%. Adequate mucosal visualization reported was 75% in the cardia, 73% for fundus, 96% for body and 98% for the antrum of the stomach.[1] This new capsule device was subsequently compared with the standard flexible gastroscopy in a nonrandomized blinded trial in 61 patients and 58.3% gastric lesions were picked up by both gastroscopy and CE. Fourteen lesions seen on gastroscopy were missed on CE and 31 lesions missed on gastroscopy were picked up by the CE. The authors concluded that the overall diagnostic accuracy was similar for both the procedures.[10] Another trial in 189 symptomatic patients showed that this CE had an accuracy of 90.5%, sensitivity of 61.9%, and specificity of 94.1% compared with conventional gastroscopy plus biopsy.[11]

The third type of magnetically controlled device developed used a robotic C-arm as the magnetic control (Ankon NaviCam, Ankon Optoelectronic Technology Co. Ltd, Wuhan, Shanghai, China; size 28 × 12 mm, weight 5.2 g, battery life 8 to 10 hours, 480 × 480 pixels resolution, 2 frames/ second, field of view 140 degrees). The robotic C-arm greatly increased the accuracy of movement control compared with the handheld magnetic capsule endoscopes.[12] In a pilot study published in 2012, 31 healthy volunteers underwent the procedure and > 75% of the gastric mucosa could be visualized in 79.4% of the subjects. Adequate visualization reported was 82.4% in gastric cardia, 85.3% in fundus, 100% in the body, incisura, antrum, and pylorus. Moreover, the maneuverability of the capsule device was reported to be good in 85.3% of the study subjects.[12] Ching et al reported excellent visualization of all areas of the gastric mucosa using the Ankon NaviCam device.[13] In a trial comparing this capsule device to conventional gastroscopy, the diagnostic accuracy was similar with an overall agreement of 91.2% among the two modalities.[14] In a larger trial involving 350 patients with upper abdominal complaints, this device was reported to have a sensitivity of 90.4%, specificity 94.7%, positive predictive value 87.9%, and negative predictive value 95.9% for picking up gastric lesions. Importantly, 95.7% patients preferred this modality over a conventional gastroscopy.[15] A recently published study used a newer second generation version of the NaviCam capsule and compared it to the older version. This capsule had a superior frame rate of eight frames/ second, better image resolution of 720 × 720 pixels, wider field of view of 150 degrees, more than 12 hours battery life and antijamming wireless technology for optimal control of the device. Evaluation of the esophageal mucosa and the Z-line was significantly better compared with the older device. Maneuverability and image quality were also superior and gastric transit time could be shortened with the newer version. However, lesion detection rates were similar between the two models.[16]

The best way to achieve adequate gastric preparation before performing CE is a question that has not yet been sufficiently addressed. For adequate visualization, the stomach has to be properly distended, and obscuring secretions and bubbles have to be removed. Magnetically controlled CE works when there is a liquid interface enabling controlled movement of the capsule. Initially researchers attempted using gas forming powder to achieve adequate distension. However, the results were disappointing and now clear water is used to fill the stomach. Agents like simethicone are used for clearing bubbles and debris that could obstruct optimal visualization.[17] Control of the capsule in the antrum against the propulsive peristaltic forces is another reason for concern. Some investigators have used antispasmodic drugs like scopolamine to reduce peristalsis but there is insufficient data regarding the benefit of the same.[17]

Magnetically controlled CE devices have also been studied for the assessment of esophageal diseases. Lien et al in a pilot study used a cable capsule endoscope that could be controlled using a handheld magnetic navigator to examine the upper gastrointestinal tract in 10 healthy volunteers. Esophageal transit speed was controlled using the cable attached to the capsule and completeness of the examination for all esophageal landmarks was 100%.[18] Chen et al demonstrated a novel technique for the examination of the esophagus by using a detachable string magnetically controlled capsule. Once the patient swallowed the capsule, it was allowed to pass till the gastric cardia. Then it was pulled back up using the attached string and the esophageal mucosa was examined. After completing the esophageal examination, the string was detached and the capsule was allowed to pass into the gastric lumen.[19] A modification of the Ankon NaviCam capsule device with a detachable string has also been developed especially for esophageal examination. Compared with the standard wireless NaviCam device, this modified capsule gave better evaluation of the esophageal mucosa including the Z line. Use of the string enabled repeated and adequate examination for any focal lesions.[20]

In a pilot study published recently in Gastrointestinal Endoscopy Journal, Beg et al used the wireless MiroCam Navi MACE system to evaluate utility of this device in diagnosing esophageal varices (EV) and Barrett’s esophagus (BE).[21] Fifty participants were included, including 17 with known EV, 17 with known BE, and 16 controls. These participants underwent the MACE procedure, with the operator blinded to previous endoscopy reports as well as indication for the procedure. All participants ingested 1 L water with added Simethicone prior to the CE procedure. The capsule was swallowed in the supine position with the head raised at an angle of 10 degrees and this prevented the rapid transit of the capsule through the esophagus due to gravity. Moreover, the investigators used the handheld magnetic paddle to control the passage of the capsule through the esophageal lumen and attempts were made to keep the capsule in the lumen as long as possible. Once this procedure was complete, all participants underwent esophagogastroduodenoscopy (EGD) where the endoscopist was blinded to the findings of the capsule study. MACE was able to diagnose EV with a sensitivity of 73.3% and specificity 100%, whereas BE was diagnosed with sensitivity of 93.8% and specificity of 100%. The investigators were able to hold the capsule within the esophageal lumen using the handheld magnet in 68% patients. The mean esophageal transit time was 190 seconds but with a wide range from 5 seconds to 634 seconds. Visualization of esophageal landmarks was comparable to EGD, but EGD scored better for the evaluation of the Z line. Technical success was 94% with MACE compared with 100% with EGD and the patient comfort and tolerability were significantly better for the MACE procedure. This pilot study reported a reasonable accuracy for the detection of esophageal lesions for magnetically controlled CE with very high levels of patient comfort and acceptance. The EV detection rates were comparable, while the BE detection rates were better with the MACE system compared with dedicated esophageal capsules used in previous studies. Moreover, magnetically controlled CE has an advantage of adequate visualization of the gastric mucosa also. The authors concluded that with improvements in capsule technology, the ability to hold the capsule in the esophageal lumen and to modulate esophageal transit times may come under the full control of the endoscopist in the future.

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Artikel online veröffentlicht:
30. September 2020

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