Magnetic resonance cholangiopancreatography (MRCP) is a non-invasive imaging technique that employs magnetic resonance imaging (MRI) with heavily T2-weighted sequences to visualize the biliary and pancreatic ducts by exploiting the high signal intensity of static fluid within them against surrounding low-signal tissues.[1] This method allows for detailed depiction of ductal anatomy without the need for ionizing radiation or intravenous contrast agents in standard applications.[2]First described in 1991, MRCP has evolved significantly over the subsequent decades, benefiting from advancements in MRI technology such as faster acquisition times and higher resolution, transitioning from initial two-dimensional projections to sophisticated three-dimensional imaging.[1] The technique typically utilizes a 1.5-T MRI scanner and employs sequences like half-Fourier acquisition single-shot turbo spin-echo (HASTE) for breath-hold imaging or respiratory-triggered fast spin-echo (FSE) for thicker slabs, often reconstructed with maximum intensity projection (MIP) to generate cholangiographic-like views.[2] Optional enhancements, such as secretin-stimulated functional MRCP, can assess pancreatic exocrine function by evaluating ductal response to the hormone.[1]Clinically, MRCP serves as a primary diagnostic tool for evaluating a range of biliopancreatic disorders, including choledocholithiasis with a sensitivity of approximately 85%, benign and malignant strictures, congenital anomalies like choledochal cysts (90-95% accuracy), chronic pancreatitis, and postoperative complications.[1] It is particularly valuable in assessing the extent of disease beyond obstructions, such as in pancreatic head tumors, and in preoperative planning for hepatobiliary surgery.[2] Compared to invasive alternatives like endoscopic retrograde cholangiopancreatography (ERCP), MRCP offers superior safety by avoiding risks of pancreatitis, perforation, or infection, while providing comparable diagnostic yield for ductal pathology.[1]Despite its strengths, MRCP has limitations, including susceptibility to motion artifacts that can degrade image quality, potential overlap of ductal signals with bowel fluid, and reduced sensitivity for non-dilated ducts or small calculi under 5 mm.[2] It also lacks the therapeutic capabilities of ERCP, such as stone extraction or stent placement, necessitating complementary procedures in certain cases.[1] Ongoing developments, including integration with gadolinium-enhanced sequences and artificial intelligence for artifact reduction, continue to enhance its diagnostic precision.[3]
Introduction
Definition and Purpose
Magnetic resonance cholangiopancreatography (MRCP) is a non-invasive imaging technique that employs magnetic resonance imaging (MRI) to visualize the biliary and pancreatic ductal systems.[1] It specifically delineates the biliary tree, encompassing the intrahepatic and extrahepatic bile ducts, gallbladder, and cystic duct, along with the pancreatic ducts, by exploiting the high signal intensity of static fluid in these structures on heavily T2-weighted sequences, without requiring exogenous contrast agents or ionizing radiation.[1][4]The primary purpose of MRCP is diagnostic evaluation of the hepatobiliary and pancreatic systems, enabling the detection of pathologies such as obstructions, strictures, choledocholithiasis (bile duct stones), tumors, and congenital anomalies.[1] By providing detailed anatomical images comparable to those obtained via more invasive methods, MRCP facilitates initial assessment and planning for therapeutic interventions.[4]Key anatomical structures routinely visualized include the common bile duct, main pancreatic duct, and ampulla of Vater, allowing for comprehensive assessment of ductal patency and integrity.[1] As an alternative to endoscopic retrograde cholangiopancreatography (ERCP), MRCP offers reduced procedural risks, making it particularly valuable for high-risk patients while maintaining high diagnostic accuracy.[4][5]
Basic Principles
Magnetic resonance cholangiopancreatography (MRCP) relies on T2-weighted magnetic resonance imaging (MRI) sequences to visualize the biliary and pancreatic ducts, where fluid-filled structures such as bile and pancreatic juice appear bright, or hyperintense, against a suppressed background due to their high water content and prolonged T2 relaxation times.[1] This contrast arises because stationary or slow-moving fluids in these ducts exhibit high signal intensity in heavily T2-weighted images, while surrounding tissues with shorter T2 times produce low signal, effectively highlighting ductal anatomy without the need for invasive procedures.[6]To achieve this selective visualization, MRCP employs heavily T2-weighted fast spin-echo or single-shot sequences, such as half-Fourier acquisition single-shot turbo spin-echo (HASTE) or rapid acquisition with relaxation enhancement (RARE), which use long echo times to further suppress signals from non-fluid tissues and minimize motion artifacts through rapid acquisition.[1] Standard MRCP does not require intravenous gadolinium-based contrast agents, as the inherent T2 contrast from endogenous fluids suffices for imaging; however, secretin—a hormone that stimulates pancreatic exocrine secretion—may be optionally administered intravenously to increase fluid volume in the pancreatic duct, enhancing its depiction for diagnostic purposes.Spatial encoding in MRCP is accomplished through the application of magnetic field gradients and radiofrequency (RF) pulses, which selectively excite and localize protons in the imaging volume to generate two-dimensional (2D) or three-dimensional (3D) datasets.[1] These datasets are then reconstructed into projectional images using techniques like maximum intensity projection (MIP), which renders the brightest voxels (corresponding to fluid-filled ducts) onto a single plane, providing a comprehensive overview of the ductal system in multiple orientations without overlapping structures obscuring the view.[6]
Clinical Uses
Indications
Magnetic resonance cholangiopancreatography (MRCP) is primarily indicated for the noninvasive evaluation of biliary and pancreatic duct abnormalities in patients presenting with jaundice, where it helps identify the level and cause of obstruction, such as in cases of suspected pancreatic adenocarcinoma leading to the "double duct" sign involving simultaneous dilatation of the common bile duct and pancreatic duct.[1] It is also recommended for detecting choledocholithiasis, particularly in individuals with obstructive liver function tests or persistent symptoms following cholecystectomy, demonstrating a sensitivity of 85% and specificity of 93% for identifying common bile duct stones.[1] In chronic pancreatitis, MRCP visualizes ductal irregularities, such as the "chain-of-lakes" appearance due to side-branch ectasia, and secretin-enhanced protocols improve detection of early changes.[1]For pancreaticobiliary malignancies, including cholangiocarcinoma and pancreatic adenocarcinoma, MRCP assesses strictures, upstream dilatation, and peri-ampullary involvement, aiding in the characterization of obstructive lesions.[1] It is valuable for diagnosing congenital anomalies, such as choledochal cysts and pancreas divisum, with near-100% accuracy in identifying the latter through visualization of dorsal and ventral duct anatomy.[1]Postoperatively, MRCP is indicated for assessing complications after procedures like cholecystectomy or liver transplantation, including bile leaks, anastomotic strictures, and altered biliary anatomy, with reported 100% sensitivity for detecting strictures in some series.[1] In patients with persistent symptoms post-cholecystectomy, it guides further management, such as endoscopic retrograde cholangiopancreatography (ERCP), in up to 47% of cases.[7]MRCP serves as a screening tool in high-risk populations, such as those with primary sclerosing cholangitis (PSC), where it detects multifocal strictures and beading with high sensitivity and specificity, facilitating monitoring for progression or cholangiocarcinoma development (prevalence 8-25% in PSC).[8] For intraductal papillary mucinous neoplasms (IPMN), it characterizes cystic dilatations and mucin-related obstructions, supporting surveillance in at-risk patients.[1]In treatment planning, MRCP provides preoperative staging for assessing tumor resectability in pancreaticobiliary malignancies and identifies ductal variants critical for procedures like hepatectomy, thereby guiding endoscopic or surgical interventions while avoiding unnecessary invasive diagnostics.[1]
Contraindications and Precautions
Magnetic resonance cholangiopancreatography (MRCP) shares the contraindications of standard magnetic resonance imaging (MRI) due to its reliance on strong magnetic fields and radiofrequency pulses. Absolute contraindications include non-MRI-compatible cardiac pacemakers, implantable cardioverter-defibrillators, and other cardiac implantable electronic devices, as these can malfunction or cause severe arrhythmias during the procedure.[9] Ferromagnetic metallic implants or foreign bodies, such as aneurysm clips or intraocular fragments, also pose absolute risks due to potential migration, heating, or dislodgement.[9] Certain cochlear implants and neurostimulation systems are similarly contraindicated unless verified as MRI-conditional.[10]Relative contraindications encompass conditions where MRCP may proceed with caution or alternatives. Pregnancy, particularly in the first trimester, is a relative contraindication, as the procedure should be avoided unless benefits outweigh potential risks to the fetus, with ultrasound preferred initially.[11] Renal impairment is a relative concern if gadolinium-based contrast is considered, though standard MRCP typically avoids intravenous contrast to minimize nephrogenic systemic fibrosis risk in patients with severe kidney disease.[12] Metallic implants near the abdomen, such as stents or surgical clips, may cause artifacts or heating and require compatibility assessment.[9] Severe claustrophobia unresponsive to mild anxiolytics and inability to remain motionless for 20-40 minutes are also relative, potentially necessitating sedation or alternative imaging.[11]Precautions focus on patient safety and image quality optimization. For anxiety or claustrophobia, open-bore MRI scanners or conscious sedation (e.g., benzodiazepines) can be employed, with monitoring for respiratory depression.[12] If oral negative contrast agents like pineapple juice are used to suppress gastrointestinal fluid signals, patients should be screened for allergies, though reactions are rare and typically mild.[11] In acute emergencies such as cholangitis requiring therapeutic intervention, MRCP is not ideal as it is purely diagnostic; endoscopic retrograde cholangiopancreatography (ERCP) is preferred for its therapeutic capabilities.[13]In special populations, adjustments mitigate risks. For pediatric patients, shorter acquisition sequences and sedation (if needed) ensure cooperation and reduce motion artifacts, with no ionizing radiation exposure making MRCP suitable for children.[11] Obese individuals may face field-of-view limitations or scanner weight restrictions (typically 500-550 pounds), potentially degrading image quality, though MRCP remains valuable when ultrasound is limited by body habitus.[11]
Procedure
Patient Preparation
Patients undergoing magnetic resonance cholangiopancreatography (MRCP) are typically required to fast for 4-6 hours prior to the examination to reduce bowel peristalsis and gastric secretions, which can mimic or obscure signals from the biliary and pancreatic ducts on T2-weighted images.[14] This fasting period helps ensure optimal image quality by minimizing motion artifacts and overlapping fluid signals.[11]To further suppress gastrointestinal fluid signals that might interfere with ductal visualization, oral negative contrast agents such as pineapple juice or ferumoxsil may be administered. Pineapple juice, in particular, acts as an effective, natural paramagnetic agent that reduces signal intensity in the stomach and duodenum on heavily T2-weighted sequences, with studies demonstrating its comparability to commercial contrasts in improving MRCP clarity.[15][16]A comprehensive screening questionnaire is conducted before the scan to assess for MRI contraindications, including implanted metallic devices, allergies to contrast agents (if used), pregnancy, and claustrophobia, ensuring patient safety and eligibility.[11]Informed consent is then obtained, during which the procedure, its risks, and expected duration are explained to the patient.[17]Regarding hydration and medications, patients are encouraged to maintain adequate fluid intake unless restricted by fasting instructions, particularly if intravenous access is anticipated. Regular medications are generally continued as prescribed, taken with minimal sips of water if needed, though certain drugs like prokinetics may be withheld on a case-by-case basis to avoid altering bowel motility or ductal distension.[11] For individuals with claustrophobia, mild sedatives may be prescribed in advance to enhance comfort during the enclosed MRI environment.[11]
Imaging Acquisition
Magnetic resonance cholangiopancreatography (MRCP) imaging acquisition begins with the patient positioned supine on the MRI table, with a phased-array body coil centered over the abdomen to optimize signal reception from the upper abdominal region. Scans are routinely performed on 1.5 T or 3 T MRI systems, which provide sufficient field strength for high-resolution depiction of fluid-filled structures while balancing scan time and image quality. Emerging techniques, such as deep learning-based reconstruction, enable accelerated 3D acquisitions, reducing scan times by up to 62% while preserving duct visibility and minimizing artifacts.[18] The total acquisition time for a standard MRCP protocol typically ranges from 15 to 30 minutes, encompassing multiple sequences and allowing for patient comfort during the non-invasive procedure.[1][19]The primary sequence protocols emphasize heavily T2-weighted imaging to exploit the long T2 relaxation time of static bile and pancreatic secretions, producing high signal intensity in the ducts against a suppressed background. Coronal and axial 2D single-shot fast spin-echo (SSFSE) or half-Fourier acquisition single-shot turbo spin-echo (HASTE) sequences are acquired during breath-holds of 15-20 seconds each to capture initial overviews and minimize respiratory motion. These are complemented by 3D T2-weighted fast spin-echo (FSE) or turbo spin-echo (TSE) acquisitions in the coronal oblique plane, often using respiratory triggering with navigator echoes for improved delineation of the biliary tree; voxel sizes around 1 mm enable isotropic multiplanar reformations for comprehensive duct visualization. Breath-hold techniques are preferred for cooperative patients to reduce artifacts, while respiratory-triggered approaches are employed for those with irregular breathing patterns.[1][20][21]Optional enhancements can refine duct conspicuity during acquisition. Intravenous secretin administration at a dose of 0.2 μg/kg over 1 minute stimulates pancreatic exocrine secretion, increasing fluid volume in the pancreatic duct for better visualization; dynamic imaging is then performed at baseline and at intervals (e.g., 1, 3, 5, 7, and 9 minutes post-injection) to capture peak enhancement. Negative oral contrast agents, such as superparamagnetic iron oxide particles or ferumoxsil, may be ingested 15-30 minutes prior to scanning to nullify T2 signal from bowel fluid, thereby preventing superimposition over the ducts and enhancing diagnostic clarity.[22][23][24]Quality control during imaging acquisition focuses on mitigating artifacts through real-time technologist monitoring and protocol adjustments. Patient motion is addressed by coaching on breathing instructions or switching from breath-hold to navigator-based triggering if needed; phase-encoding direction is optimized (e.g., right-to-left) to reduce vascular ghosting, and oversampling techniques prevent wrap-around artifacts. When MRCP is integrated into a full abdominal MRI protocol, multi-phase acquisitions (e.g., pre- and post-contrast T1-weighted sequences) may be interleaved without significantly extending total scan time, ensuring comprehensive evaluation while prioritizing biliary and pancreatic duct imaging.[1][25][26]
Post-Processing and Interpretation
Post-processing of magnetic resonance cholangiopancreatography (MRCP) images involves advanced computational algorithms to transform raw data into clinically interpretable visualizations of the biliary and pancreatic ducts. The primary techniques include maximum intensity projection (MIP), which selects and projects the highest signal intensity voxels to highlight fluid-filled structures like bile ducts, typically generating 18 reformats at 10-degree intervals over 180 degrees for comprehensive cholangiographic and pancreatographic views. [27] Multiplanar reconstruction (MPR) complements MIP by enabling reconstruction in arbitrary planes, facilitated by the near-isotropic voxels from three-dimensional acquisitions, allowing for detailed manipulation and cross-sectional analysis of ductal anatomy. [27]Interpretation of MRCP images relies on standardized criteria to identify pathological features. Ductal dilatation is assessed by measuring diameters, with normal intrahepatic ducts ≤3 mm and extrahepatic ducts (common bile duct, CBD) ≤7 mm, though up to 10 mm may be normal post-cholecystectomy; dilatation exceeding 6-7 mm in the CBD often indicates obstruction. [27] Strictures appear as focal narrowings, with benign ones typically short, regular, and symmetric, while malignant strictures are longer (>10 mm) with irregular, asymmetric margins. [27] Filling defects manifest as hypointense intraductal signals, representing stones (choledocholithiasis, detectable as small as 2 mm), tumors, or debris, and anatomical variants such as aberrant right posterior hepatic ducts (prevalence ~5%) or triple confluence (~11%) are identified with 90-95% accuracy. [27] For malignancy assessment, quantification of duct volumes via automated tools like MRCP+ measures total biliary tree volume, where volumes ≥25 ml predict malignant obstruction with 86% sensitivity and 64% specificity (AUC 0.79). [28]Reporting standards emphasize descriptive accuracy correlated with clinical context. Choledocholithiasis is reported as hypointense, dependent filling defects within dilated ducts, with MRCP sensitivity of 85% and specificity of 93%, often integrated with elevated bilirubin levels to support diagnosis. [27]Primary sclerosing cholangitis (PSC) features a beaded or pruned-tree pattern of multifocal strictures and dilatations, described for disease extent and follow-up monitoring. [27] Findings should reference patient history, such as prior surgery, to differentiate variants from pathology.Common artifacts must be recognized to avoid misinterpretation. Motion-related blurring from inadequate breath-holding during acquisition causes ghosting or duplicated duct appearances on MIP images, mimicking strictures or multifocal disease; reviewing source images or repeating scans resolves this. [29][27]Susceptibility artifacts at air-fluid interfaces produce signal voids resembling stones or pneumobilia, but axial views show non-dependent positioning for air versus dependent for calculi. [29] Partial volume effects in thick-slab MIPs can obscure small defects, mitigated by thinner sections or MPR. [27]
Advantages and Limitations
Benefits Over Other Techniques
Magnetic resonance cholangiopancreatography (MRCP) offers significant advantages over invasive procedures like endoscopic retrograde cholangiopancreatography (ERCP) primarily due to its non-invasive nature, eliminating the risks associated with instrumentation of the biliary and pancreatic ducts.[30] Unlike ERCP, which carries a complication rate of approximately 5-10%, including post-procedure pancreatitis in about 5.4% of cases, MRCP involves no catheterization, thereby avoiding procedural risks such as infection, bleeding, or perforation.[31] Additionally, MRCP does not expose patients to ionizing radiation, a key benefit compared to computed tomography (CT) scans, which are commonly used for biliary evaluation but deliver radiation doses that can be cumulative in repeated imaging scenarios.[30]In terms of comprehensive visualization, MRCP provides high-resolution, three-dimensional imaging of the biliary and pancreatic ducts with excellent soft-tissue contrast, allowing detailed assessment without the need for contrast agents or catheters.[32] It excels at depicting ductal anatomy proximal to obstructing lesions, a limitation of ERCP where opacification beyond a blockage is often impossible.[33] For choledocholithiasis, MRCP demonstrates sensitivity of 81-93% and specificity of 91-95%, making it a reliable diagnostic tool for stone detection throughout the ductal system.[30] This capability, combined with its outpatient feasibility and lack of requirement for general anesthesia, renders MRCP more cost-effective and accessible than ERCP for purely diagnostic purposes.[30]MRCP shows superiority over ultrasound in evaluating proximal biliary ducts, where acoustic shadowing from bowel gas frequently limits sonographic visualization.[34] Studies indicate MRCP's sensitivity for detecting bile duct dilatation reaches approximately 96%, compared to 79% for ultrasound, particularly in cases of malignant obstruction or subtle ductal abnormalities.[34] Relative to CT, MRCP provides enhanced sensitivity (95.83%) for malignant biliary diseases, offering better delineation of ductal involvement without radiation exposure.[34]Patient comfort is notably improved with MRCP, as the procedure typically requires no sedation and can be completed in 15-30 minutes, enabling broader applicability, including in pediatric or claustrophobic patients who might otherwise require additional interventions for alternative imaging modalities.[32]
Potential Drawbacks
Magnetic resonance cholangiopancreatography (MRCP) has notable diagnostic limitations, particularly in detecting small choledocholithiasis, where sensitivity drops for stones smaller than 5 mm due to partial volume effects from thicker imaging slices.[35] It may also miss functional disorders such as sphincter of Oddi dysfunction and early non-obstructive lesions in conditions like primary sclerosing cholangitis, as well as subtle strictures or minimal changes in chronic pancreatitis.[1] Additionally, MRCP demonstrates lower sensitivity for visualizing peripheral intrahepatic ducts compared to central biliary structures, potentially overlooking distal abnormalities.[36]Technical challenges further compromise MRCP's reliability, including susceptibility to motion artifacts from patient breathing or uncooperativeness, which can distort ductal appearances on maximum intensity projection (MIP) reformats, leading to pseudostenosis or duplication artifacts.[1] High-quality imaging requires advanced MRI equipment, such as high-field systems, which are not universally available in all clinical settings, limiting its broader application.[36]False positives and negatives arise from signal overlaps, such as gastrointestinal fluid or cysts mimicking ductal pathology, and flow or air bubble artifacts simulating stones or strictures.[1] Accuracy is reduced in obese patients due to increased motion and magnetic field inhomogeneities, as well as in post-surgical anatomies where altered ductal configurations complicate interpretation.[36] Sensitivity for pancreatic ductal abnormalities may be lower than that of invasive alternatives like ERCP for certain abnormalities.[36]MRCP's resource demands include longer scan times—typically 20-40 minutes—compared to ultrasound, making it less suitable for urgent evaluations or real-time procedural guidance.[36] It also necessitates specialized MRI infrastructure and radiologist expertise for post-processing, contributing to higher costs than non-MRI modalities.[1]
History and Developments
Early Development
Magnetic resonance cholangiopancreatography (MRCP) was first described in 1991 by Wallner et al., who demonstrated the technique's ability to image dilated bile ducts using a T2-weighted contrast-enhanced fast gradient-echo sequence, allowing noninvasive visualization without exogenous contrast agents.[37] This initial approach relied on the high signal intensity of static bile fluid against suppressed background tissues, marking a significant step toward non-invasive biliary evaluation.In the early 1990s, key advancements in fast spin-echo techniques, such as rapid acquisition with relaxation enhancement (RARE) and half-Fourier acquisition single-shot turbo spin-echo (HASTE), transformed MRCP from an experimental method into a clinically viable tool.[27] These sequences improved signal-to-noise ratios and enabled faster acquisitions, facilitating the depiction of both biliary and pancreatic ducts. Pioneering work by Morimoto et al. in 1992 further expanded the technique's scope, introducing three-dimensional MR cholangiography to assess biliary obstructions and laying groundwork for pancreatic duct imaging applications.Initial clinical validation studies throughout the 1990s compared MRCP directly with endoscopic retrograde cholangiopancreatography (ERCP), establishing its reliability for detecting choledocholithiasis with a sensitivity of approximately 90%.[38] By the mid-1990s, MRCP had become integrated into routine abdominal MRI protocols, offering a safer alternative to invasive procedures for evaluating pancreaticobiliary pathologies.[1]Despite these progresses, early MRCP faced substantial challenges, including prolonged scan times often exceeding 30 minutes for three-dimensional acquisitions and susceptibility to motion artifacts from respiration or peristalsis.[1] These limitations were progressively mitigated through the adoption of breath-hold imaging strategies, which shortened acquisition to seconds per slice and enhanced image quality.
Recent Advancements
Recent advancements in magnetic resonance cholangiopancreatography (MRCP) since the 2010s have focused on integrating artificial intelligence (AI), higher magnetic field strengths, and optimized imaging protocols to enhance diagnostic accuracy, reduce scan times, and expand clinical applications. These developments address longstanding challenges such as motion artifacts, limited resolution, and subjective interpretation, enabling more precise evaluation of biliary and pancreatic disorders.[39][40]Deep learning (DL) reconstruction techniques have significantly accelerated 3D MRCP acquisitions while maintaining image quality. In a 2025 study involving 30 participants, DL-accelerated MRCP reduced scan times by 62.4% (from approximately 10.5 minutes to 4 minutes) compared to conventional sequences, with lower artifact levels (mean score 3.56 vs. 3.17) and no loss in bile or pancreatic duct visibility.[39] Similar DL methods applied at 3T and 0.55T fields have demonstrated preserved duct conspicuity and reduced noise, supporting broader adoption for routine clinical use.[41]Higher-field MRI systems, particularly 5.0T compared to 3.0T, offer improved spatial resolution and anatomical detailing in MRCP. A 2024 comparative study in healthy subjects and those with biliary dilation found that 5.0T MRCP provided significantly higher biliary tree branch counts and total branch lengths (P<0.05), with superior visualization of fine structures, although signal-to-noise ratios showed no statistically significant difference (P>0.05).[40] These enhancements at ultra-high fields like 5.0T are particularly beneficial for abdominal imaging, including biliary evaluation, by increasing signal quality without proportional increases in artifacts.[42]Quantitative MRCP metrics have emerged as reliable biomarkers for distinguishing malignant from benign biliary obstructions. A 2025 analysis of total biliary tree volume demonstrated that volumes ≥25 ml effectively differentiated cholangiocarcinoma-related obstructions (median 53.10 ml) from benign ones (median 16.70 ml), achieving an area under the curve (AUC) of 0.79, sensitivity of 86.96%, and specificity of 73.33%.[43] Malignant cases also exhibited higher duct numbers and total duct lengths (P<0.05), providing objective measures that outperform qualitative assessments alone.[43]Enhanced protocols incorporate AI-driven tools and contrast agents to improve specificity in complex cases. MRCP+, an AI-enhanced quantitative extension of standard MRCP, generates 3D biliary models for volumetric analysis, boosting inter-reader agreement for high-grade strictures in primary sclerosing cholangitis from 42.9% to 67.9% (P=0.02) and achieving AUC values of 0.75–0.85 for stricture detection.[44] Protocols using gadoxetic acid enable hepatobiliary phase imaging 15–20 minutes post-injection, improving lesion characterization when combined with MRCP acquired shortly after contrast administration.[45] Additionally, modified respiratory-triggered SPACE sequences shorten acquisition times to under 1 minute while preserving signal-to-noise and contrast-to-noise ratios superior to breath-hold alternatives (P<0.001), aiding evaluation of post-transplant biliary strictures in non-compliant patients.[46][47]Clinical applications have expanded through direct-access MRCP and AI-assisted interpretation. A 2025 pilot study of 15 patients with suspected acute gallstone disease found direct MRCP as a first-line test reduced time to diagnosis (2.53 vs. 4.18 days) and costs (£647 vs. £896 per case), with quantitative metrics like gallbladder volume distinguishing stone presence (80.2 cm³ vs. 30.1 cm³, P=0.018).[48]AI models integrated with MRCP have enhanced detection of extra-biliary findings, which occur in 58.2% of exams and prompt urgent follow-up in 9.4% of cases, including new malignancies in 2.6%; these tools achieve high diagnostic performance (AUC 0.80–0.98) for lesion identification across hepatobiliary imaging.[49][50]