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Cholangiography

Cholangiography is a medical imaging technique used to visualize the intrahepatic and extrahepatic ducts, , and associated biliary structures to diagnose conditions such as obstructions, stones, strictures, tumors, or leaks. It employs contrast agents, often iodine-based, injected into the biliary system or visualized indirectly, combined with X-rays, , or magnetic to produce detailed images of flow and . Developed as a key tool in hepatobiliary diagnostics since the mid-20th century, cholangiography aids in both preoperative planning and intraoperative guidance, reducing risks during procedures like . The primary types include invasive direct contrast methods such as (ERCP), (PTC), and intraoperative cholangiography (IOC), as well as non-invasive (MRCP). These modalities are selected based on clinical context, patient factors, and the need for intervention; for instance, ERCP and PTC carry higher risks of complications like or (5-10% for ERCP), while MRCP and IOC offer lower morbidity but limited therapeutic options. Cholangiography plays a critical role in managing diseases like choledocholithiasis, cholangitis, and , with advancements in fluorescence-guided and hybrid imaging enhancing precision and safety.

Overview

Definition

Cholangiography is a term derived from the Greek roots "chole," meaning , "angeion," meaning vessel, and "graphy," meaning writing or recording. This reflects its focus on the biliary vasculature. The term first appeared in in , emphasizing its historical role in radiographic diagnostics. Cholangiography is an technique used to visualize the , encompassing both direct methods involving the injection of a radiopaque contrast medium, typically iodinated, into the ducts followed by or , and indirect non-invasive methods such as (MRCP). This approach allows for detailed assessment of ductal anatomy, including any obstructions, strictures, or stones. The procedure primarily targets the intrahepatic and extrahepatic ducts, the , and occasionally the , providing critical insights into biliary system integrity. Unlike non-cholangiographic indirect imaging methods such as or non- CT, which rely on anatomical echoes or density differences without specific biliary , cholangiography achieves enhanced delineation of fine ductal through targeted or specialized sequences. This distinction makes it particularly valuable in preoperative planning or intraoperative guidance for biliary interventions.

Purpose and Indications

Cholangiography serves as a critical diagnostic and therapeutic tool in the evaluation and management of disorders, primarily aimed at identifying and characterizing obstructions within the ducts. Its core purposes include diagnosing biliary obstruction caused by various etiologies, detecting gallstones (choledocholithiasis) within the ducts, evaluating strictures or tumors that may impede flow, and assessing for leaks following surgical interventions. Additionally, it provides real-time guidance for therapeutic procedures, such as placement to relieve obstructions or drainage to manage . Specific indications for cholangiography encompass a range of clinical scenarios where biliary is suspected but not fully delineated by initial assessments. These include obstructive jaundice of unknown origin, suspected choledocholithiasis in patients with gallstone-related symptoms, post-cholecystectomy evaluation to rule out retained stones or iatrogenic injuries, assessment of for staging and intervention planning, and ongoing monitoring of to detect progressive strictures. In cases of suspected pancreaticobiliary malignancies or post-liver transplant complications, it aids in confirming ductal involvement and facilitating or sampling. The diagnostic advantages of cholangiography lie in its ability to deliver high-resolution, imaging that dynamically assesses flow, ductal anatomy, and the precise location of abnormalities, often surpassing the capabilities of non-invasive modalities like or (MRCP) in spatial detail and interventional potential. Patient selection typically prioritizes individuals where non-invasive yields inconclusive results, such as ambiguous ductal dilation or persistent symptoms despite normal preliminary tests, ensuring its use in scenarios demanding definitive visualization or immediate therapeutic action.

History

Early Developments

The earliest attempts at cholangiography occurred in 1921 when physicians Hans Burckhardt and Ph. Müller performed the procedure via percutaneous puncture of the to instill contrast medium and visualize the biliary system using rudimentary imaging. This pioneering effort, conducted in , , marked the first direct opacification of the biliary tree but was limited by poor image quality and high procedural risks. A significant milestone came in 1924 with the invention of intravenous cholecystography by American surgeons Evarts A. Graham and Warren H. Cole, who introduced the use of tetrabromophenolphthalein as a to opacify the and proximal biliary ducts non-invasively. This method, detailed in their seminal publication, revolutionized biliary diagnosis by allowing preoperative assessment without surgical intervention, though it primarily targeted the rather than the full ductal system. In 1932, Argentine surgeon Pablo L. Mirizzi advanced intraoperative cholangiography by reporting the first series of procedures during bile duct operations, employing static radiographic films to capture contrast-filled images of the biliary tree. Mirizzi's technique, performed in , enabled real-time surgical guidance to identify stones and obstructions, establishing a foundational practice in biliary surgery despite reliance on immobile X-ray equipment. Percutaneous transhepatic cholangiography (PTC) was introduced in 1937 by French physicians Paul Huard and Do-Xuan-Hop, who accessed the intrahepatic ducts via needle puncture under local anesthesia to inject oily contrast like Lipiodol for duct visualization. This approach, initially developed in Indochina, provided direct biliary mapping in jaundiced patients but faced substantial hurdles including frequent bile leakage from puncture sites, inadequate contrast agents that caused poor opacification or toxicity, and dependence on basic fluoroscopic tools with limited resolution. These early innovations were hampered by procedural dangers, such as from peritonitis due to leakage, and technical constraints like non-water-soluble contrasts that prolonged imaging times and increased allergic reactions. By 1954, intravenous cholangiography emerged as a less invasive alternative, with Frank Glenn and colleagues at demonstrating the use of iodipamide (Biligrafin) to opacify the extrahepatic ducts via systemic injection, reducing the need for direct biliary access. This development, reported in the Annals of Surgery, improved and accessibility for preoperative evaluation while building on prior contrast advancements.

Modern Advancements

In the 1960s and 1970s, significant progress in cholangiography came with the development of (ERCP), which integrated with fluoroscopic imaging to enable real-time visualization of the biliary and pancreatic ducts. This technique, first performed successfully in 1968 by William S. McCune and colleagues in the United States, marked a shift from purely or surgical approaches by allowing access through the , improving diagnostic accuracy for conditions like choledocholithiasis and strictures.00051-8/fulltext) endoscopists, including Itsuo Ogoshi and Ichiro Oi, contributed to its early refinement, achieving success rates up to 80% by combining duodenoscopes with contrast injection under . From the 1980s onward, (PTC) benefited from the adoption of thinner, "skinny" , typically 22-gauge, which substantially lowered complication rates such as hemorrhage and leakage compared to earlier thicker . Introduced in the late by Kunio Okuda and popularized through the and , this refinement increased procedural safety and success rates to over 90% in cases of dilated ducts, making PTC more viable for both and biliary . Concurrently, the introduction of C-arm intensifiers revolutionized intraoperative cholangiography by providing dynamic fluoroscopic guidance during , reducing reliance on static radiographs and enabling immediate adjustments to avoid ductal injuries. Pioneered in reports from the late , such as those by George Berci, these portable units became standard in operating rooms by the , enhancing precision in laparoscopic and open procedures. In the late 20th and early 21st centuries, cholangiography emerged as an innovative adjunct, utilizing (ICG) dye and near-infrared imaging to highlight biliary structures and mitigate injuries during . ICG, approved for clinical use since 1959, was adapted for applications in the , with initial intraoperative trials demonstrating improved visualization of the and in real time, reducing misidentification errors by up to 50% in high-risk cases. This method, first clinically applied around 2009, integrates with laparoscopic systems to provide non-ionizing, high-contrast imaging without additional radiation exposure. The integration of digital imaging technologies further advanced cholangiography, with the transition from traditional film-based to (DSA) in the 1980s and offering superior contrast resolution and reduced contrast agent volumes. , developed in the late 1970s at institutions like the University of , subtracts pre-contrast "mask" images from post-contrast ones to isolate vascular and ductal structures, minimizing overlying tissue artifacts in both ERCP and PTC procedures. This shift enabled faster image processing and archiving, with widespread adoption in by the , improving diagnostic yield for subtle strictures and leaks. Despite these refinements, the routine use of invasive cholangiographic techniques like ERCP and PTC has declined since the 1990s due to the rise of non-invasive magnetic resonance cholangiopancreatography (MRCP), which provides comparable diagnostic accuracy without procedural risks. MRCP was first introduced in 1991 by Bernhard Wallner and colleagues using heavily T2-weighted MRI sequences to visualize the biliary and pancreatic ducts non-invasively; advanced through improvements in MRI technology, it has led to a 25-76% reduction in diagnostic ERCP procedures over the past two decades, reserving invasive methods primarily for therapeutic interventions such as stone extraction or stenting. This evolution reflects a broader trend toward minimizing patient morbidity while maintaining efficacy in biliary diagnostics.

Types

Percutaneous Transhepatic Cholangiography

(PTC) is an image-guided, that involves puncturing the liver with a needle to access the , followed by the injection of contrast medium to visualize the biliary tree under . This technique provides direct access to the proximal biliary system and is particularly valuable for diagnostic evaluation and therapeutic interventions in patients with biliary obstructions. It is often indicated in cases of obstructive where endoscopic approaches are not feasible. The procedure begins with the patient positioned or prone, depending on the access route, typically in an suite under and intravenous sedation for comfort. A 22-gauge Chiba needle is advanced through the skin in the right midaxillary line, caudal to the tenth , using or fluoroscopic guidance to target a peripheral in the right hepatic lobe. Once is aspirated to confirm intrahepatic placement, a hydrophilic guidewire is inserted through the needle, which is then exchanged for a to allow contrast injection. Water-soluble , such as , is injected to opacify the biliary ducts, enabling serial fluoroscopic imaging to assess anatomy and pathology. The procedure typically lasts 30 to 60 minutes, concluding with removal or placement for if needed, followed by application of a hemostatic patch at the puncture site. PTC is uniquely suited for scenarios involving distal biliary obstructions, such as those caused by malignancies, where (ERCP) has failed or is contraindicated due to altered . It facilitates biliary drainage, stone removal, or access, extending its role beyond diagnostics to therapeutic applications like placement. Essential equipment includes imaging modalities like or for guidance, the Chiba or Seldinger needle for initial puncture, a 0.018-inch hydrophilic guidewire for tract dilation, and 5-French angiographic catheters for contrast delivery and manipulation. Nonionic contrast agents, exemplified by at concentrations of 240-350 mgI/mL, are preferred for their low osmolality and reduced risk of adverse reactions during injection. For therapeutic extensions, indwelling drainage catheters may be deployed to manage ongoing biliary issues.

Endoscopic Retrograde Cholangiopancreatography

Endoscopic retrograde cholangiopancreatography (ERCP) is a specialized endoscopic procedure that combines with fluoroscopic imaging to visualize and intervene in the biliary and pancreatic ducts, serving both diagnostic and therapeutic purposes in cholangiography. The technique involves retrograde access to the ducts via the , allowing for detailed imaging of the bile ducts through contrast injection and enabling immediate treatments such as stone removal or placement. This approach is particularly valuable for evaluating and managing pathologies in the distal biliary tree, where direct visualization and intervention can address obstructions without surgical incision. The procedure begins with the patient under conscious sedation or general anesthesia to ensure comfort and minimize movement. A side-viewing duodenoscope, a flexible instrument with an oblique viewing angle, is inserted through the mouth, advanced through the and , and positioned in the second portion of the opposite the . Once the ampulla is identified, a or guidewire is passed through the endoscope's to cannulate the biliary or pancreatic , often guided by for precision. If therapeutic intervention is required, an endoscopic sphincterotomy may be performed using a sphincterotome to incise the , facilitating access. Radiographic contrast medium is then injected into the ducts to opacify them under real-time , producing cholangiograms that reveal filling defects, strictures, or dilatations. Optional interventions, such as extraction of stones or deployment of biliary stents, can follow based on findings. The entire process is monitored continuously with fluoroscopic to ensure accurate and to the ductal anatomy. ERCP excels in applications targeting distal bile duct pathologies, including choledocholithiasis, where gallstones can be directly visualized and extracted using wire baskets or balloons passed through the endoscope. It is also ideal for evaluating sphincter of Oddi dysfunction, allowing manometry or sphincterotomy to relieve associated pain or obstruction. Therapeutically, the procedure supports stent placement to bypass malignant or benign strictures in the distal bile duct, restoring bile flow and alleviating jaundice. These capabilities highlight ERCP's versatility in managing conditions like biliary obstruction from tumors or post-surgical complications, often obviating the need for more invasive surgery. Essential equipment includes the side-viewing duodenoscope for optimal visualization of the , water-soluble contrast media for safe ductal opacification, a sphincterotome for controlled incisions, and extraction devices such as Dormia baskets or retrieval balloons for stone management. Fluoroscopy units provide the radiographic component, integrated with the suite for seamless imaging. Typically lasting 45 to 90 minutes, ERCP is performed in a dedicated suite within a or outpatient center, with most patients recovering sufficiently for same-day discharge under monitoring.

Intraoperative Cholangiography

Intraoperative cholangiography (IOC) is a real-time imaging technique employed during open or laparoscopic to evaluate the integrity and of the biliary tree. It involves the injection of radiopaque contrast medium through the or a incision, followed by visualization using portable , allowing surgeons to assess for abnormalities such as stones or ductal variations intraoperatively. This method, pioneered by Mirizzi in 1932, integrates seamlessly into biliary surgery to facilitate immediate decision-making. The procedure follows a structured sequence after initial surgical exposure of the bile ducts and confirmation of the critical view of safety. First, the is clipped at the infundibular junction, and a small incision is made distal to the clip. A cholangiocatheter is then inserted into the and secured with an additional clip or balloon to prevent leakage. Next, 10-20 mL of diluted medium is injected manually using a , while the patient holds respiration to minimize motion artifact. Immediate fluoroscopic images are acquired in multiple views—typically anteroposterior, lateral, and —using a mobile imaging unit to inspect the , hepatic ducts, and for filling defects indicative of stones or leaks, as well as to delineate anatomical variations. IOC finds unique application as a routine adjunct in gallbladder removal procedures, where it aids in detecting common bile duct stones in 3% to 15% of cases, helps prevent iatrogenic bile duct injuries by clarifying ductal anatomy, and identifies congenital variations such as aberrant right hepatic ducts. By providing dynamic visualization during surgery, it enables transcystic interventions if abnormalities are found, enhancing procedural safety without necessitating conversion to more invasive techniques. Essential equipment includes a 5-French cholangiocatheter or ureteric for cannulation, water-soluble medium diluted to 30-50% concentration for optimal opacification, and a mobile C-arm fluoroscope for real-time imaging in the operating room. Lead aprons and shields are also used for . The entire process typically requires 5-15 minutes, depending on experience and institutional protocols, and is fully integrated into the surgical workflow without prolonging overall operating time significantly.

Magnetic Resonance Cholangiopancreatography

Magnetic resonance cholangiopancreatography (MRCP) is a non-invasive imaging technique that uses (MRI) to visualize the biliary and pancreatic ducts without the need for contrast injection or . It relies on heavily T2-weighted sequences to highlight fluid-filled structures like bile ducts, providing high-resolution images of the intrahepatic and extrahepatic biliary , , and . The procedure is performed on an outpatient basis, with the patient lying in an MRI scanner under no sedation unless claustrophobia is an issue. No preparation such as is typically required, though bowel relaxants may be used to reduce motion artifacts. Sequences are acquired in multiple planes (coronal, axial, oblique), often including 3D acquisition for multiplanar , lasting 15 to 45 minutes total. Gadolinium-based contrast may be administered intravenously in some cases for enhanced visualization of strictures or tumors, but MRCP is primarily non-contrast. Images are post-processed to generate cholangiograms that depict ductal anatomy, dilatations, strictures, stones, or masses without . MRCP is particularly suited for initial diagnostic evaluation of suspected biliary or pancreatic pathologies, such as choledocholithiasis, , or , especially in patients where invasive procedures like ERCP are contraindicated due to high risk or coagulopathy. It offers high sensitivity (85-95%) for detecting ductal stones greater than 5 mm and is valuable for preoperative planning, though it lacks therapeutic capabilities. Essential equipment includes a 1.5T or MRI with phased-array coils for abdominal imaging, software for maximum intensity projection (MIP) reconstructions, and optional agents for dynamic enhancement. No catheters or endoscopes are required, making it radiation-free and suitable for repeated use in monitoring chronic conditions.

Risks and Complications

General Risks

Invasive cholangiography procedures, which involve the injection of into the biliary tree to visualize its structure, carry inherent risks applicable to variants using this approach (e.g., [PTC], [ERCP], and intraoperative cholangiography [IOC]). Non-invasive methods like (MRCP) have different risk profiles. One primary concern is , particularly cholangitis or resulting from bacterial introduction into the biliary system during contrast administration or manipulation. The incidence of such infectious complications in biliary interventional procedures, including cholangiography, ranges from 0.8% to 2.3% in adults, with cholangitis occurring in approximately 2.1% of cases and in 0.4%. These risks are heightened in patients with biliary obstruction or , as bacteria from the or can ascend into the biliary ducts. Allergic reactions to the medium used in these procedures represent another universal hazard, manifesting as mild symptoms like urticaria or severe . The overall incidence of adverse reactions to is approximately 0.6% for anaphylactic-type events, with severe cases affecting 0.04% to 0.1% of patients; these rates may be lower in cholangiography due to the relatively small contrast volume injected compared to intravenous administration. Risk factors include a prior history of contrast reactions or , and reactions can occur even with low-osmolar agents commonly used today. Radiation exposure is a concern across all fluoroscopy-guided cholangiography techniques, contributing to cumulative doses that may elevate long-term cancer risk, particularly with repeated procedures. Effective doses for patients typically range from 3 to 6 mSv for diagnostic procedures and 12 to 20 mSv for therapeutic ones, comparable to several abdominal scans. Pregnant patients face additional fetal risks, necessitating careful dose minimization through collimation and pulsed . Bleeding complications, such as hematomas at access sites or rare hemorrhage, arise from vascular during needle puncture or placement. The incidence of significant is approximately 2% to 3% in approaches, though events are uncommon and often self-limiting. To mitigate these general risks, preventive strategies include routine prophylaxis to reduce rates, with corticosteroids or antihistamines for patients with known allergies, and adherence to sterile technique throughout the . These measures, supported by preprocedural tests for clotting and renal function, significantly lower complication rates.

Type-Specific Complications

Percutaneous transhepatic cholangiography (PTC) carries specific risks related to the transhepatic puncture, including bile peritonitis due to bile leakage, which occurs in approximately 2-10% of cases as part of overall procedural complications. may arise from pleural transgression during needle insertion, particularly in intercostal approaches, while liver capsule perforation can lead to intra-abdominal hemorrhage or bile . These events are more likely with multiple puncture attempts or in patients with distorted . Endoscopic retrograde cholangiopancreatography (ERCP) is associated with unique complications stemming from endoscopic manipulation and sphincterotomy, such as post-ERCP affecting 3-10% of patients, often due to irritation or contrast injection. Duodenal occurs in about 0.5-1% of procedures, typically from scope trauma or guidewire advancement, and from sphincterotomy is reported in 1-2% of cases, exacerbated by vessel injury during cutting. Intraoperative cholangiography (IOC) during introduces risks tied to surgical integration, including false-positive findings from air bubbles mimicking calculi, which can affect up to 35% of interpretations and lead to unnecessary interventions. Allergic reactions to contrast media, though rare (less than 1%), may manifest intraoperatively as anaphylactoid events, and the procedure can prolong operative time by 10-20 minutes, increasing exposure and fatigue. Clip into the biliary tree, a rare delayed complication reported in case series comprising fewer than 100 cases worldwide and occurring up to several years post-procedure, can cause obstruction if not prevented by absorbable materials or precise placement. Magnetic resonance cholangiopancreatography (MRCP) is generally low-risk as a but carries MRI-specific complications. Contraindications include implanted devices like pacemakers or certain metal implants due to risks. Allergic reactions to gadolinium-based contrast (used in some cases) are uncommon, with mild reactions in 0.07-2.4% and severe anaphylactoid events in less than 0.1%; is a rare concern (incidence <0.07% as of ) in patients with severe renal impairment (GFR <30 mL/min). There is no risk of , , or , though affects up to 4% and may be needed in some cases. Management of PTC-related bile leaks often involves percutaneous drainage to contain and prevent , with repositioning or replacement as needed. For ERCP-induced , supportive care including fluid resuscitation, nil per os status, and analgesics is standard, resolving most mild cases within 72 hours. In IOC, false positives are mitigated by confirmatory imaging or administration to reduce , while clip migration prevention relies on intraoperative verification and selective clip use; prolonged time is addressed by standardized protocols. Complication incidence varies, with higher rates in patients with (e.g., doubled bleeding risk in ERCP) or (e.g., increased hemorrhage and technical difficulty in laparoscopic IOC).

Interpretation and Advances

Image Interpretation

Image in cholangiography involves systematic evaluation of the biliary tree's opacification, , and patency following contrast administration, applicable across modalities such as (PTC), (ERCP), and (MRCP). Normal findings include smooth, tapered measuring less than 2 mm in peripheral branches and up to 3 mm centrally, with the (CBD) typically 4-6 mm in diameter (upper limit 6-8 mm in adults without prior ). The (CHD) appears uniform without irregularities, and contrast flows promptly through the biliary system into the without delay or , confirming unobstructed drainage. Absence of filling defects ensures no intraluminal obstructions, reflecting physiological flow dynamics under fluoroscopic or static imaging. Abnormal findings signal pathology and require careful differentiation between benign and malignant processes. Ductal dilatation proximal to an obstruction, with CBD exceeding 8 mm, indicates blockage from stones, strictures, or tumors, often accompanied by upstream intrahepatic branching dilatation in a "pruned tree" pattern for chronic conditions like . Filling defects appear as lucent intraductal shadows consistent with calculi, particularly in the or gallbladder neck, while irregular narrowing or strictures manifest as focal or segmental reductions in lumen caliber—benign strictures show smooth, tapered edges, whereas malignant ones exhibit abrupt, shouldered margins with asymmetric wall thickening. Extravasation of contrast outside the ductal walls denotes bile leaks, often post-surgical, appearing as linear or pooled collections adjacent to the biliary tree. Interpretation techniques emphasize quantitative and qualitative assessments to guide clinical decisions. Duct diameters are measured using on-image calipers at standardized levels (e.g., widest point), with values compared to age- and procedure-adjusted norms to detect dilatation. Flow dynamics are evaluated by observing contrast progression in real-time or cine sequences in MRCP, noting delays or stasis that correlate with obstructive or cholangitis symptoms such as pain and elevated . Clinical correlation integrates imaging with patient history, results (e.g., liver enzymes), and findings to distinguish functional from structural abnormalities, enhancing diagnostic accuracy. Common artifacts can mimic pathology and necessitate vigilance during analysis. Air bubbles introduced during contrast injection appear as round, mobile filling defects resembling small stones, distinguishable by their and shape changes on serial images. Poor contrast mixing or layering leads to inhomogeneous opacification, creating pseudodefects or apparent strictures that resolve with repositioning or additional injections, particularly in dependent ducts. artifacts from metallic clips or gas may degrade image quality in MRCP, but these are minimized through optimized sequences. Reporting standards prioritize clear anatomic labeling and objective quantification to facilitate multidisciplinary communication. Structures are identified using abbreviations like , CHD, and intrahepatic ducts (IHD), with descriptions of their confluence and variants (e.g., aberrant right hepatic duct). Abnormalities are quantified by specifying duct diameters (e.g., " 12 mm"), stricture length (e.g., "2 cm focal narrowing"), and location relative to landmarks like the insertion, alongside recommendations for follow-up or intervention based on findings. Standardized templates ensure comprehensive coverage, including patency to the and any , aligning with guidelines for biliary imaging.

Recent Technological Advances

Recent advancements in have significantly enhanced real-time visualization of the biliary ducts during procedures like laparoscopic . (ICG) fluorescence cholangiography, utilizing near-infrared laparoscopy, allows for precise identification of extrahepatic s by highlighting their anatomy against surrounding tissues, thereby improving surgical navigation and reducing the risk of bile duct injury. Studies indicate that this technique lowers bile duct injury rates from 25 to 6 per 10,000 cases, representing a substantial decrease in complications compared to conventional methods. Additionally, ICG administration optimizes operative times and postoperative recovery without increasing adverse events. Digital enhancements, particularly (AI) integration and three-dimensional (, have improved diagnostic accuracy in cholangiography. AI algorithms applied to endoscopic images during ERCP facilitate automated detection of bile duct stones and strictures, achieving sensitivities of 83-89% for stones and a of 91.7% with specificity of 94.4% for malignant strictures, enabling faster and more reliable identification than traditional visual assessment alone. Complementing this, DynaCT technology enables 3D biliary reconstruction from standard two-dimensional fluoroscopic cholangiography by rotating the C-arm, producing high-resolution images of the biliary tree, vessels, and liver that surpass conventional in detail and immediacy during interventions. These tools enhance procedural precision and support better clinical decision-making. Hybrid procedures combining (ERCP) with digital single-operator cholangioscopy, such as the system, provide direct intraductal visualization and targeted interventions. The device, inserted via the ERCP scope, offers high-definition imaging of the biliary mucosa, facilitating biopsy sampling for indeterminate strictures and stone management with technical success rates exceeding 95%. This approach improves diagnostic yield for malignancies and allows therapeutic actions like electrohydraulic lithotripsy in a single session, minimizing the need for multiple procedures. Shifts toward minimally invasive techniques include robotic-assisted intraoperative cholangiography (IOC) and guidance for (PTC). Robotic platforms enhance IOC by providing magnified, three-dimensional views and tremor-filtered instrumentation, leading to reduced operative times and lower conversion rates to open surgery in complex cases. For PTC, fusion of with pre-procedural CT or MR imaging improves needle guidance accuracy, achieving high technical success while decreasing procedure duration and complications like hemorrhage. Looking to future directions, integration of with targeted agents holds promise for more specific biliary . Hepatocyte-targeted nanoparticles, such as gadolinium-perfluorocarbon formulations, demonstrate rapid biliary excretion and enhanced MRI for cholangiography, potentially improving for small lesions at lower doses than traditional agents. Concurrently, low-dose radiation protocols in , including pulsed modes at reduced frame rates, have achieved up to 50% decreases in patient exposure during ERCP without compromising image quality or procedural efficacy. These developments aim to further minimize risks while advancing diagnostic capabilities.