3D Printed Percutaneous Transhepatic Cholangiography and Drainage (PTCD) Simulator for Interventional Radiology.

PURPOSE: Learning how to perform percutaneous transhepatic bile duct drainage (PTCD) is challenging for interventional radiology (IR) trainees. Therefore, simulators are crucial for IR training and are being increasingly demanded in the evolving healthcare environment of value-based care. To facilitate interventional training, we tried to evaluate our newly developed liver phantom for further use in IR training. METHODS: We developed a liver phantom with a flexible hollow biliary tree, hydrogel-based liver parenchyma, plastic ribs, and silicone skin. The phantom was evaluated by 20 radiology residents from two hospitals. After an introduction, all participants tried to obtain biliary access by fluoroscopic guidance within 25 min. Puncture time, fluoroscopy time, and kerma area product were measured. After 7 days, the participants repeated the procedure on an altered and more difficult model. Additionally, a survey was handed out to every participant (20 residents, 5 experts, and 5 IR fellows) to evaluate the phantom in terms of accuracy and haptic feedback, as well as general questions regarding simulation. RESULTS: The residents performed significantly faster and were more self-confident on Day 7 than on Day 1, significantly decreasing puncture time, fluoroscopy time, and kerma area product (p ≤ 0.0001). The participants were very satisfied with their simulation experience and would trust themselves more in real-life scenarios. CONCLUSION: We were able to develop a phantom with high anatomical accuracy for fluoroscopy and ultrasound-guided interventions. The phantom successfully helped residents learn and improve their PTCD performance.

Technical considerations and tips for using the Tegus remote proctoring system in elective and emergency cases and in webinars.

Smart angiography suites (SAS) refer to the incorporation of audio-video technology and internet connectivity into the angiography suite to enable bidirectional communication for teleproctoring. Remote streaming support (RESS) is intended to increase patient safety by supporting interventionalists with limited experience or who are practicing in geographically remote areas. The aim of this review is to describe real-life experience of the Tegus system and to share practical tips concerning its use and setup. We describe the platform itself, settings and integration in our angiography suite. We provide technical tips intended to help new and potential users to achieve an optimal experience for both neurointerventionalists and proctors. We describe both elective cases that we have performed with teleproctoring and emergencies. Lastly, we describe a different room setup and software solutions used in live workshops. Use of teleproctoring enabled involvement of proctors in cases where an already experienced interventionalist needed support in the decision-making process concerning the sizing and deployment of devices with which he was familiar only on a basic level. Excellent video feed quality and instant communication enabled optimal preparation and in vivo implantation of those devices without the need for physical proctors' presence. In emergency cases the system allowed a senior physician to offer support during cases where optimal device sizing is critical. Our usage concept of the rig permitted monitoring of thrombectomy cases by junior physicians. During webinars a remote streaming platform enabled us to conduct workshops that simulated an "on-site" experience as closely as possible during the COVID-19 pandemic.

Interventional treatment of biliodigestive anastomosis leaks with a modified percutaneous transhepatic cholangiodrainage.

INTRODUCTION: Biliodigestive leaks are typically caused by an insufficiency at the surgical anastomosis. Biliodigestive anastomosis (BDA) insufficiencies can lead to bilomas, abscesses and vascular erosion in chronic conditions. MATERIAL AND METHODS: We performed a retrospective analysis of the medical and radiological records of all patients with biliodigestive insufficiency who received interventional treatment between July 2015 and February 2021. Nine patients (three with unilateral drainage and six with bilateral drainage) were treated with a modified percutaneous transhepatic cholangiodrainage (PTCD). Clinical success was considered after complete resolution of the peribiliary collections, absence of bile within the surgical drains, radiological patency of the BDA (contrast medium flowing properly through the BDA and no signs of leakage) and haemodynamic stability of the patient without signs of sepsis. RESULTS: Clinical success was achieved in all nine patients. No patients required revision surgery to repair their BDA. The mean indwelling drainage time was 34.8±16.5 days. The mean number of interventional procedures performed per patient was 6.6±2.0. CONCLUSION: Patients who present with BDA insufficiency may benefit from interventional radiological techniques. Our modified PTCD resolved the BDA leak in all nine cases and should be considered as a valuable option for the treatment of patients with this complication. Our technique demonstrated to be feasible and effective.

The Columbus steerable guidewire in neurointerventions: early clinical experience and applications.

OBJECTIVE: To report our early experience in using the steerable 'Columbus' guidewire, also known as 'Drivewire' in the USA, and its potential applications in neurovascular interventions. METHODS: Neurointerventions in 36 patients (20 female, 16 male) using the steerable Columbus guidewire were recorded from August 2019 to December 2020 and included a variety of neurovascular procedures: Treatment of aneurysms (n=17), thrombectomy in acute ischemic stroke (n=12), and others (n=7), such as treatment of stenosis and embolization procedures. Immediate follow-up with digital subtraction angiography and tracking of each patient's clinical outcome was performed. RESULTS: In 35 out of 36 cases, the target vessel was reached with Columbus, including advancement of the appropriate microcatheter. In 14 cases, additional wires were used, mainly because of the nature of the procedures (eg, use of multiple wires/buddy wires or exchange maneuvers). In five cases, the Columbus wire was damaged by the operator and had to be replaced. Peri-interventional complications occurred in two patients, neither attributed to the Columbus guidewire. CONCLUSIONS: The new Columbus neurovascular guidewire has the unique ability to be shaped within the patient. Currently available versions lack torquability compared with other available guidewires but offer tremendous support at the tip, allowing maneuvers which are impossible with other wires on the market.

Applications of the Columbus steerable guidewire.

The Columbus steerable guidewire (Rapid Medical, Israel) is a 0.014 inch guidewire with a remotely controlled deflectable tip intended for neuronavigational purposes. 1 The tip can be shaped by pulling or pushing the handle. Pulling the handle decreases the radius (from 4 mm to 2 mm) and curves the tip, while pushing the handle increases the curvature radius and straightens the tip until it bends in the opposite direction. The amount of deflection is at the discretion of the operator. Video 1 The response of the Columbus guidewire to rotational movements is inferior to that of standard wires, and the tip is very soft and malleable but brings great support when bent. We present two cases where the Columbus guidewire was used. In the first case, the Columbus enabled us to probe a posterior cerebral artery arising from a giant basilar tip aneurysm without wall contact. In the second case, the Columbus was used as a secondary wire to help cannulate the pericallosal artery in a patient with a recurrent anterior complex aneurysm; this subsequently permitted successful stent-assisted coiling of the aneurysm. neurintsurg;14/10/1045/V1F1V1Video 1.

Percutaneous transhepatic biliary puncture simulator: a cord network prototype.

BACKGROUND: The aim of this study was to present a percutaneous transhepatic biliary puncture simulator that can be used without radiation exposure and that reflects the conventional anatomy of the biliary ducts and its vicinity structures. METHODS: An anatomically based model of the biliary tree was developed using a cord network fixed to a wooden frame. The skin, ribs, intercostal muscles, and right lower lobe pleura were simulated using foam sponge, plastic tubes, a polystyrene foam panel, and an air pad, respectively. For the puncture, we used a 20-G Chiba needle and a wire with distal double arches; these were used to troll a cord, simulating the successful puncture of a bile duct. A camera was also placed above the model to allow the trainees to train eye-hand coordination while viewing the image on a monitor in real time. The simulator was tested with 60 radiology residents to evaluate the confidence and skills transferability of the training model. RESULTS: After receiving an introduction of the system and 5 min of training under tutor surveillance, all participants were able to troll a cord of the biliary simulator by themselves in less than 4 min. Only one participant punctured the simulated pleura. The participants' evaluations showed positive results, with increased user confidence and skills transferability after the training session. CONCLUSIONS: This proposed simulator can be an effective tool to improve a trainee's confidence and competence while achieving procedural and non-procedural interventional radiology skills related to the liver. TRIAL REGISTRATION: Retrospectively registered.

Temperature-induced configuration changes in hydrogel-coated coils and their relevance in embolization procedures.

BACKGROUND: The present study attempted to demonstrate how the configuration of hydrogel-coated coils is influenced by different temperature exposures. Thirty detachable hydrogel-coated coils were evaluated in an in vitro water immersion test under five different temperature ranges (22.6 °C, 37 °C, 40-50 °C, 50-60 °C, and 60-70 °C). The configuration changes were classified (configuration I, configuration II, and configuration III) according to the curling that occurred during 30 min of immersion. Configuration stability of five Hydrogel-coated coils was also evaluated in a two-step temperature immersion test. RESULTS: All hydrogel-coated coils showed some configuration changes during water immersion. However, a logarithmic transformation of the time and temperature data showed a significant (p < 0.05) negative linear correlation between time and temperature for all coil configurations (configuration I: R = 0.97, configuration II: R = 0.98, configuration III: R = 0.97). The time needed to reach configuration III (complete coiling) was 160.4 ± 41.9 s at 37.5 °C (range: 100-205 s), 45.7 ± 22.2 s at 47.5 °C (range: 23-70 s), 20.2 ± 7.2 s at 57.5 °C (range: 14-32 s), and 10.3 ± 2.4 s at 67.5 °C (range: 7-13 s). CONCLUSIONS: Temperatures above 55 °C induced immediate configurational changes in the hydro-coated coils, achieving complete curling within less than 30 s. Temperatures near 36 °C (normal body temperature) require more time to reach optimal coil curling (configuration III). The optimization of HydroCoil preparation can reduce interventional procedural time and improve clinical results.

Coil embolization of a thoracic aorta hematoma with branch artery pseudoaneurysm - case report.

BACKGROUND: A thoracic aorta hematoma with branch artery pseudonaneurysm is a very rare complication of thoraric blunt trauma. The standard treatment of this type of injury is aortic endograft placement. CASE PRESENTATION: We present a case in which a thoracic aorta hematoma with branch artery pseudoaneurysm was treated with coil embolization instead of endografting. CONCLUSIONS: Coil embolization of aortic injuries may be a safe and definitive treatment alternative in selected cases. This technique has the potential to reduce the risk of procedure-related complications.