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Cholangiocarcinoma

Cholangiocarcinoma, also known as bile duct cancer, is a rare and aggressive that arises from the epithelial cells lining the s, the slender tubes that carry —a digestive fluid produced by the liver—from the liver to the and . It accounts for approximately 3% of all gastrointestinal cancers and represents the second most common primary liver tumor after , comprising 10-15% of hepatobiliary malignancies. The disease is more prevalent in adults over 50 years of age and is challenging to diagnose early due to its often initial presentation and tendency to be locally invasive or metastatic by the time symptoms appear. Cholangiocarcinomas are classified into three main anatomical types based on their location within the : intrahepatic (originating inside the liver), perihilar (also called Klatskin tumors, occurring at the junction where the right and left hepatic ducts meet outside the liver), and distal (developing in the extrahepatic bile ducts near the and ). Over 95% of cases are adenocarcinomas, characterized by glandular tissue formation, and the specific type influences diagnostic and treatment approaches. Intrahepatic cholangiocarcinomas are less common than extrahepatic forms but have been increasing in incidence in certain regions, while perihilar tumors are the most frequent subtype overall. The of cholangiocarcinoma typically involves chronic inflammation and genetic in cells, leading to uncontrolled proliferation and tumor formation, though the exact triggers for these DNA changes remain unclear in most cases. Key risk factors include (which increases risk up to 400-fold), chronic liver conditions such as or , congenital biliary abnormalities like , parasitic infections from liver flukes (common in ), and lifestyle factors including , , and . Genetic predispositions, such as Lynch syndrome or , also elevate susceptibility. Symptoms often manifest in advanced stages and include (yellowing of the skin and eyes due to buildup), itchy skin, dark urine, pale or clay-colored stools, (particularly on the right side under the ribs), unintentional , , fever, and . Early detection is rare without screening in high-risk individuals, and typically involves , blood tests, and . Treatment is tailored to the tumor's location, , and patient health, with surgical resection offering the only potential cure for resectable cases, though only about one-third of tumors are operable at . Adjunctive therapies include (e.g., gemcitabine-based regimens), , targeted molecular therapies for specific mutations (such as FGFR inhibitors), and, in select intrahepatic cases, . remains poor, with five-year survival rates below 10% for advanced disease, underscoring the need for ongoing research into early detection and novel treatments.

Classification

Anatomical subtypes

Cholangiocarcinoma is classified anatomically into three main subtypes based on the location of the tumor within the biliary tree: intrahepatic, perihilar, and distal extrahepatic. This tripartite system distinguishes tumors arising from bile ducts inside the liver, at the liver hilum, and in the extrahepatic ducts below the cystic duct insertion, respectively. The classification aids in determining clinical presentation, diagnostic approaches, and therapeutic strategies, as each subtype exhibits unique anatomical constraints and obstructive patterns. Intrahepatic cholangiocarcinoma (iCCA) originates from the epithelial cells lining the , which are the smaller ducts within the liver proximal to the second-order biliary branches. These tumors account for approximately 10-20% of all cholangiocarcinoma cases. iCCA typically presents as a mass within the liver, often detected incidentally or through symptoms related to intrahepatic biliary obstruction, such as or elevated liver enzymes, rather than overt . Perihilar cholangiocarcinoma (pCCA), also known as when located at the biliary confluence, arises at the junction of the right and left hepatic ducts, forming the at the liver hilum. Representing about 50% of cases, pCCA frequently causes early biliary obstruction due to its central location, leading to conjugated hyperbilirubinemia, pruritus, and cholangitis. The tumor's proximity to the and hepatic artery complicates surgical resection and requires precise imaging to assess vascular involvement. Distal extrahepatic cholangiocarcinoma (dCCA) develops in the below the insertion, near the and . This subtype comprises roughly 30% of cholangiocarcinomas and often mimics pancreatic head clinically and radiologically, presenting with painless , , and Courvoisier's due to distal biliary obstruction. The biliary tree's —comprising intrahepatic ducts draining into the right and left hepatic ducts at the hilum, merging into the , then the after the junction, and finally entering the —underpins these subtypes' distinct behaviors. For visual reference, diagrams of the biliary tree typically illustrate the intrahepatic segments branching within the liver, the perihilar confluence as a Y-shaped junction, and the distal duct running alongside the .

Histological variants

The majority of cholangiocarcinomas exhibit histology, comprising over 90% of cases and originating from the of biliary epithelial cells. These tumors typically form glandular structures lined by cuboidal to columnar cells with varying degrees of production, embedded in a dense desmoplastic . Rare histological variants constitute less than 10% of cholangiocarcinomas and include squamous, adenosquamous, mucinous, and clear cell types, each with reported incidences below 5%. Squamous variants feature keratinizing or non-keratinizing squamous differentiation, often arising in areas of chronic inflammation or . Adenosquamous carcinomas combine glandular and squamous elements, while types show abundant extracellular pools with floating clusters of neoplastic cells; clear cell variants display glycogen-rich imparting a clear appearance, mimicking metastasis. These variants generally portend a poorer due to aggressive behavior and limited response to standard therapies. Cholangiocarcinomas are graded according to (WHO) criteria into well-differentiated, moderately differentiated, or poorly differentiated categories, primarily based on the extent of glandular or tubular formation and the degree of nuclear , such as pleomorphism, hyperchromasia, and mitotic activity. Well-differentiated tumors closely resemble normal biliary with prominent gland formation and minimal , whereas poorly differentiated ones show little to no architectural organization and marked nuclear irregularities, correlating with advanced disease and reduced survival. A distinct subtype is mixed hepatocellular-cholangiocarcinoma, which demonstrates unequivocal coexistence of hepatocellular and cholangiocellular within the same tumor mass, as defined by the 2019 WHO classification without a specified minimum for each component. This biphenotypic tumor often arises in cirrhotic livers and exhibits transitional zones between the two elements, reflecting a common origin. Immunohistochemical profiling supports histological diagnosis, with cholangiocarcinomas typically showing strong positivity for cytokeratin 7 (CK7), a biliary marker, in over 90% of cases, alongside variable expression of CK19 and for hepatocellular markers like HepPar-1 in pure forms. In mixed subtypes, dual positivity for both biliary (e.g., CK7) and hepatic (e.g., arginase-1) markers helps delineate components.

Epidemiology

Incidence and prevalence

Cholangiocarcinoma exhibits a global age-standardized incidence rate ranging from 0.3 to 6 cases per 100,000 population annually, reflecting significant regional variations. , an estimated 8,000 new cases of bile duct cancer, encompassing both intrahepatic and extrahepatic forms, are diagnosed each year as of 2025 data. According to Surveillance, Epidemiology, and End Results () program data, the overall rate for liver and intrahepatic bile duct cancers, which includes intrahepatic cholangiocarcinoma, stands at 9.4 new cases per 100,000 individuals. The incidence of intrahepatic cholangiocarcinoma has been increasing in Western countries since , with annual percentage changes typically ranging from 2% to 3%, driven by improved diagnostic capabilities and potential shifts, while extrahepatic cholangiocarcinoma rates have remained largely stable. Recent trends indicate continued rise in intrahepatic cases despite overall stabilization in liver cancers. For instance, , the incidence among White populations rose by approximately 49% from 2001 to 2017, equating to an average annual increase of about 2.5%. In contrast, GLOBOCAN 2022 estimates highlight a higher burden in , where age-standardized rates can exceed those in Western regions; in , national rates are around 20-30 per 100,000, with Northeast Thailand previously reaching up to 85 per 100,000 but recent data (as of 2022) indicating a decline to approximately 32 per 100,000 due to interventions. Recent trends show a decreasing incidence in (average annual percent change of -5.8% to -7.2% from 2012-2021), attributed to reduced infections. Prevalence estimates for cholangiocarcinoma are limited due to its aggressive nature and poor long-term survival, but it remains rare overall, accounting for approximately 3% of all malignancies and about 15% of primary liver cancers worldwide. This rarity underscores its disproportionate impact relative to more common gastrointestinal cancers, with global projections from GLOBOCAN 2022 indicating continued trends in incidence without substantial shifts in given the disease's .

Geographic and demographic patterns

Cholangiocarcinoma incidence displays marked geographic variation, with the highest rates reported in and . In northeastern , age-standardized incidence rates previously reached up to 85 cases per 100,000 population, driven by endemic risk factors prevalent in the region, but have declined to around 32 per 100,000 as of recent data (2013-2022). Similarly, rates exceed 6 per 100,000 in , , and other parts of nationally. In contrast, incidence remains low in and , with rates as low as 0.4 per 100,000 in and generally under 2 per 100,000 across . This disparity can exceed 50-fold between high-burden areas like and low-burden regions such as the . Demographically, cholangiocarcinoma predominantly affects older adults, with most diagnoses occurring between 50 and 70 years of age and a mean age of approximately 68 years. There is a slight male predominance, with a male-to-female ratio of about 1.5:1, particularly for intrahepatic subtypes. In the United States, ethnic disparities are evident, with higher incidence rates among Asians/Pacific Islanders, Hispanics, and compared to . For cholangiocarcinoma specifically, rates are highest among Asians/Pacific Islanders (approximately 2.5-3 per 100,000), followed by Hispanics and American Indian/ (around 1.5-2 per 100,000), based on 2001-2017 , potentially linked to higher burdens of and in these communities. Asians/Pacific Islanders exhibit the highest overall rates among major groups. Temporal trends indicate an increasing incidence of cholangiocarcinoma in younger adults under 50 years in certain cohorts, with an 81% rise observed among those aged 18-44 from 0.21 to 0.38 per 100,000 between 2001 and 2017 in the United States. This shift may relate to rising prevalence, though overall incidence remains low in this age group compared to older populations.

Risk factors

Infectious and parasitic causes

Infections with certain parasites and viruses are established risk factors for cholangiocarcinoma, particularly intrahepatic cholangiocarcinoma (iCCA), through mechanisms involving chronic inflammation and biliary epithelial damage. Liver flukes, specifically Opisthorchis viverrini and Clonorchis sinensis, are classified as Group 1 carcinogens by the International Agency for Research on Cancer (IARC), based on sufficient evidence of their role in human cholangiocarcinogenesis. Chronic infection with these trematodes, acquired via consumption of undercooked freshwater fish in endemic regions of Southeast Asia and East Asia, leads to persistent biliary tract irritation, with relative risks for cholangiocarcinoma reported up to 5-fold in affected populations. Hepatitis B virus (HBV) and hepatitis C virus (HCV) infections also elevate the risk of iCCA, primarily through induction of cirrhosis and, in the case of HBV, direct viral integration into host DNA. Meta-analyses indicate an odds ratio of approximately 4.5 for iCCA among individuals with chronic HBV infection, reflecting its oncogenic potential via genomic instability. Similarly, HCV infection is associated with an odds ratio of about 3.4 for iCCA, driven by sustained hepatic inflammation and fibrosis that promote cholangiocellular transformation. Human immunodeficiency virus (HIV) infection further heightens susceptibility, with an adjusted odds ratio of 5.9 for iCCA, attributed to immunosuppression facilitating opportunistic infections and HIV-associated cholangiopathy, which involves biliary strictures and inflammation. The carcinogenic mechanisms of these agents center on biliary inflammation and genotoxic effects. For liver flukes, irritation from parasite and secretion induces and endogenous formation, fostering DNA damage and cholangiocyte proliferation; fluke-derived granulin-like growth factors further drive hyperproliferation of biliary . HBV and HCV contribute via viral proteins that disrupt cellular signaling and promote , while exacerbates this through impaired immune surveillance and secondary infections like . Eradication efforts, such as treatment and public health campaigns in , have demonstrated efficacy, with annual declines in cholangiocarcinoma incidence of 2-7% in high-prevalence areas following sustained opisthorchiasis control programs. As of 2025, these programs continue to reduce transmission, projecting further decreases in incidence over coming decades.

Non-infectious causes

() is a characterized by and of the s, leading to strictures and increased risk of cholangiocarcinoma () through persistent and . The lifetime risk of developing in patients ranges from 10% to 20%, with the majority of cases occurring in the extrahepatic s. This risk is mediated by ongoing injury, which promotes cellular proliferation and genetic instability in the biliary . Congenital biliary malformations, such as , represent another significant non-infectious risk factor, where anomalous bile duct dilation predisposes to bile stasis, chronic inflammation, and potential . Untreated carry a 10-30% risk of progression to CCA, primarily due to of pancreatic enzymes into the biliary tree, which damages the ductal lining and fosters . Surgical excision reduces but does not eliminate this risk, highlighting the need for lifelong surveillance in affected individuals. Metabolic conditions, including and , have been increasingly linked to intrahepatic CCA (iCCA), often through progression from non-alcoholic steatohepatitis (NASH). Metabolic syndrome confers a 1.5- to 2-fold increased risk of iCCA, with odds ratios (OR) up to 2.68 in affected populations, driven by , chronic low-grade , and hepatic lipid accumulation that may alter biliary cell metabolism. specifically elevates iCCA risk (OR 2.13), associating with larger tumor sizes and poorer prognosis via enhanced tumor metabolic activity and immune dysregulation. Exposure to environmental toxins represents a historical and ongoing non-infectious hazard for CCA development. , a radioactive used in the mid-20th century, causes alpha-particle of the liver and bile ducts, resulting in a greater than 300-fold increased risk of CCA, with latency periods of 20-30 years. Dioxins, found in industrial pollutants, similarly elevate risk through and disruption of cellular signaling pathways in the biliary . contributes modestly, with an overall OR of 1.31 for CCA, potentially via carcinogenic compounds that induce DNA damage in cholangiocytes. Certain genetic syndromes predispose to CCA through inherited defects in or biliary architecture. Lynch syndrome, characterized by (MSI-high) tumors due to germline mutations in mismatch repair genes, increases CCA risk, with lifetime estimates around 2%, often presenting as extrahepatic disease. Biliary malformations beyond , such as (congenital hepatic ductal ectasia), further heighten susceptibility via chronic cholangitis and stone formation, though specific risk quantification remains limited.

Pathophysiology

Cellular origins

Cholangiocarcinoma primarily originates from cholangiocytes, the epithelial cells that line the intrahepatic and extrahepatic biliary tree, which embryologically derive from the ventral . These cells exhibit histological diversity, with cuboidal morphology in small intrahepatic ducts and columnar, mucin-secreting characteristics in larger ducts and the extrahepatic biliary system. Peribiliary glands, submucosal structures harboring bipotent stem/ cells, also serve as key cellular sources, particularly for tumors in the larger ducts, where these glands respond to by proliferating and differentiating into cholangiocyte-like cells. Intrahepatic cholangiocarcinoma (iCCA) commonly arises from cholangiocytes in small peripheral ductules or through biliary of hepatic cells located at the canals of Hering, enabling from hepatocyte-like states under chronic liver damage. In contrast, extrahepatic cholangiocarcinoma (eCCA), including perihilar and distal subtypes, typically derives from cholangiocytes lining larger intrahepatic or extrahepatic ducts, often involving peribiliary glands as the niche. This anatomical distinction underscores the heterogeneous embryological and histological foundations of the disease. The stem cell theory posits that cholangiocarcinoma emerges from the activation and dysregulated proliferation of hepatic stem or progenitor cells in response to persistent biliary injury, such as inflammation or cholestasis, leading to accumulation of oncogenic changes in these multipotent cells. Rare origins include tumors from gallbladder epithelium, classified separately as gallbladder carcinoma, or ampullary epithelium, termed ampullary carcinoma, which are histologically similar but excluded from pure cholangiocarcinoma definitions due to their distinct anatomical sites. Advancements in the 2020s, including single-cell RNA sequencing analyses, have substantiated these multipotent origins by revealing malignant subclusters in iCCA that co-express mature cholangiocyte markers like KRT19 alongside progenitor markers such as PROM1 and TM4SF4, highlighting cellular heterogeneity and plasticity.

Molecular mechanisms

Cholangiocarcinoma (CCA) tumorigenesis is driven by a complex array of genetic alterations that disrupt key cellular processes, leading to uncontrolled proliferation and survival. The most prevalent mutation occurs in the TP53 tumor suppressor gene, affecting 20-40% of intrahepatic CCA (iCCA) cases and 30-60% of extrahepatic CCA (eCCA), which impairs DNA damage response and apoptosis. Oncogenic mutations in KRAS are also common, reported in 7-24% of iCCA and 8-45% of eCCA, activating downstream proliferative signals. In iCCA specifically, IDH1/2 mutations arise in 10-30% of cases, altering metabolic pathways and promoting epigenetic dysregulation. FGFR2 fusions, present in 10-45% of iCCA, result in ligand-independent receptor activation and enhanced cell growth. These genetic changes converge on critical signaling pathways that sustain tumor progression. Activation of the PI3K/AKT pathway, often through receptor tyrosine kinases such as and ERBB2, enhances cell survival and inhibits in various subtypes. Similarly, the MAPK/ERK pathway is frequently dysregulated by and BRAF mutations, driving epithelial-mesenchymal transition and proliferation across . Epigenetic modifications further contribute to CCA pathogenesis by silencing tumor suppressor genes. Hypermethylation of the promoter, observed in 6-27% of iCCA and 9-28% of eCCA, leads to loss of control and pathway integrity. IDH1/2 mutations exacerbate this by inducing global DNA hypermethylation, affecting multiple suppressor loci and fostering a pro-tumorigenic state. The plays a pivotal role in CCA progression through desmoplastic reactions, where cancer-associated fibroblasts secrete growth factors that promote stromal and tumor invasion, particularly in iCCA and perihilar CCA. Immune evasion is facilitated by upregulation on tumor cells, suppressing T-cell activity and contributing to an immunosuppressive milieu. Subtype-specific molecular features highlight the heterogeneity of CCA. HER2 amplification occurs in approximately 17% of eCCA cases, driving aggressive growth via HER2 signaling. BRAF mutations, found in 3-7% of both iCCA and eCCA, activate the MAPK pathway and are more prevalent in iCCA.

Signs and symptoms

Early features

Cholangiocarcinoma frequently presents without symptoms in its initial stages, leading to incidental detection in 20-25% of intrahepatic cases (iCCA) during for unrelated conditions. Overall, approximately 20-30% of patients are at the time of , as the tumor often grows silently until it causes obstruction or other complications. This lack of early warning signs contributes significantly to delayed recognition and advanced-stage presentation in the majority of cases. In iCCA, subtle early manifestations may include mild abdominal discomfort or a sensation of fullness in the right upper quadrant, reflecting the tumor's intrahepatic location and initial without widespread obstruction. Nonspecific systemic symptoms such as fatigue and unintentional can also emerge due to the cancer's metabolic demands and early inflammatory responses. Pruritus, resulting from mild and bile salt accumulation in the skin, is another potential early indicator, particularly when biliary involvement begins. For perihilar cholangiocarcinoma (pCCA), early biliary obstruction may lead to in 10-20% of cases, manifesting as subtle yellowing of the skin or alongside dark urine from excretion. These signs are typically less pronounced initially compared to advanced , where progression can intensify obstructive features. Early symptoms, when present, often go unrecognized for several months to years before formal is made, allowing the tumor to advance undetected.

Advanced presentations

In advanced cholangiocarcinoma, obstructive emerges as a dominant feature, particularly in extrahepatic cases (eCCA), affecting 70-90% of patients due to obstruction by the tumor. This manifests as progressive yellowing of the skin and , accompanied by pale, clay-colored stools and dark urine from buildup, often leading to intense pruritus and from impaired fat absorption. Elevated serum levels, typically direct hyperbilirubinemia, confirm the obstructive nature and correlate with tumor location in the perihilar or distal bile ducts. Severe becomes prominent in late-stage disease, especially in distal cholangiocarcinoma (dCCA), where it often radiates to the back due to local invasion or peritoneal . Concurrent cholangitis can complicate advanced presentations, characterized by high fever, rigors, and right upper quadrant tenderness from bacterial ascension into obstructed ducts. These symptoms significantly impair , frequently requiring urgent biliary decompression to alleviate risk. In intrahepatic cholangiocarcinoma (iCCA), advanced progression often leads to and secondary to and , with profound . A palpable abdominal mass is rare, as the tumor typically infiltrates diffusely without forming a discrete lump. Vascular invasion in advanced disease, particularly involvement, can precipitate through variceal rupture or tumor erosion, presenting as or in affected individuals. Paraneoplastic syndromes are infrequent but notable in late-stage cholangiocarcinoma, with hypercalcemia arising from tumor secretion of in rare instances, causing confusion, , and dehydration. Coagulopathy, such as , may also occur sporadically due to tumor-induced procoagulant factors, manifesting as unexplained bruising or bleeding.

Diagnosis

Clinical evaluation

The clinical evaluation of suspected cholangiocarcinoma begins with a thorough history to identify risk factors and symptom progression. Clinicians should inquire about established risk factors such as (), which confers a 160- to 400-fold increased risk, and chronic infection with liver flukes like or , particularly in endemic regions. Additional history should cover the timeline of symptoms including progressive , pruritus, , and unintentional , as well as personal or family history of cancers associated with hereditary syndromes like Lynch syndrome. Physical examination focuses on signs of biliary obstruction and systemic effects. Jaundice is observed in approximately 60% of patients with extrahepatic cholangiocarcinoma, while hepatomegaly is present in up to 25%, often due to secondary biliary cirrhosis or tumor mass effect. Cachexia, reflecting advanced disease and malnutrition, is common in symptomatic cases. Courvoisier's sign—a palpable, nontender, distended gallbladder in the setting of jaundice—may occur in distal cholangiocarcinoma cases, indicating obstruction below the cystic duct insertion. Differential diagnosis includes malignancies with overlapping presentations, such as pancreatic ductal , which can mimic distal cholangiocarcinoma through similar obstructive and , and , particularly for intrahepatic variants presenting with and . Benign conditions like IgG4-related sclerosing cholangitis or secondary cholangiopathies must also be considered. Key red flags prompting urgent evaluation include unexplained exceeding 10% of body weight over six months or progressively rising serum levels, which may signal evolving biliary obstruction. Laboratory tests, such as those assessing , can provide supportive evidence but follow initial clinical assessment. According to AASLD and EASL guidelines, high-risk patients, especially those with , warrant structured evaluation including detailed history and physical exam as part of annual surveillance to facilitate early detection.

Laboratory tests

Laboratory tests play a crucial role in supporting the of cholangiocarcinoma by assessing liver function and identifying potential tumor markers, though they are not definitive for confirmation. frequently reveal abnormalities indicative of biliary obstruction or . Alkaline phosphatase (ALP) levels are elevated in approximately 80-90% of cases, particularly in extrahepatic cholangiocarcinoma, reflecting biliary involvement. Gamma-glutamyl transferase (GGT) is also commonly raised, confirming the biliary origin of the elevation when ALP is increased. Conjugated is often elevated in obstructive presentations, while aspartate aminotransferase (AST) and alanine aminotransferase (ALT) show only mild increases, typically less pronounced than in hepatocellular injury. Tumor markers in serum provide supportive evidence but have limitations in specificity. Carbohydrate antigen 19-9 (CA 19-9) is elevated above 100 U/mL in about 70-75% of patients with cholangiocarcinoma, with a specificity of around 80%, making it useful for risk stratification, especially in primary sclerosing cholangitis-associated cases. is raised in approximately 40% of cases, often used in combination with CA 19-9 for improved diagnostic accuracy, though levels can be calculated via an index (CA 19-9 + CEA × 40) achieving up to 86% accuracy. Both markers are limited by false positives in benign cholestatic conditions, such as cholangitis or biliary strictures, reducing their standalone diagnostic value. Routine testing for has low yield, with elevations exceeding 20 ng/mL occurring in fewer than 10-25% of cases and rarely above 400 ng/mL, as AFP is not typically produced by cholangiocarcinoma cells. A (CBC) may show nonspecific changes related to disease or . , often normocytic and due to or blood loss, is common in advanced disease. Thrombocytosis, defined as platelet counts above × 10^9/L, occurs in a subset of patients and is associated with poorer , potentially reflecting paraneoplastic effects or tumor-induced . Emerging molecular tests focus on (ctDNA) in plasma for noninvasive detection of actionable mutations. ctDNA assays can identify (FGFR) fusions or rearrangements in up to 89% of FGFR-altered cases and (IDH1) mutations with high concordance (around 87%) to tissue testing, with overall sensitivity reaching 70-85% in advanced cholangiocarcinoma using 2024-2025 next-generation sequencing platforms; as of 2025, studies report sensitivities up to 92% in advanced cases. These tests are particularly valuable for guiding targeted therapies in inoperable disease but remain investigational for routine screening due to variable shedding and assay sensitivity.

Imaging techniques

Imaging plays a crucial role in the detection, characterization, and staging of cholangiocarcinoma, allowing for the identification of biliary dilatation, tumor masses, vascular involvement, and distant metastases. Noninvasive radiological techniques are typically employed as the first-line approach following clinical suspicion prompted by laboratory abnormalities such as elevated CA 19-9 levels. These methods help differentiate cholangiocarcinoma from benign conditions like choledocholithiasis and guide subsequent or surgical planning. Ultrasound serves as an initial screening tool for cholangiocarcinoma due to its accessibility and lack of . It effectively detects biliary dilatation with a of up to 95%, though its ability to identify primary masses is more limited, achieving detection in about 50% of cases. Limitations include operator dependence and reduced efficacy in obese patients or those with bowel gas interference, often necessitating advanced for confirmation. Computed tomography (CT) and (MRI) provide detailed anatomical assessment for cholangiocarcinoma characterization. Multiphasic contrast-enhanced CT is particularly valuable for evaluating vascular invasion, offering an accuracy of around 85% in determining resectability by delineating and hepatic artery encasement. MRI, combined with (MRCP), excels in noninvasive mapping of biliary ductal involvement, demonstrating a of 90% for detecting strictures and obstructions without the need for contrast agents or . Positron emission tomography-computed tomography (PET-CT) using 18F-fluorodeoxyglucose (FDG) enhances staging accuracy in cholangiocarcinoma by highlighting metabolic activity. It shows high sensitivity of 85-95% for intrahepatic lesions and is superior to CT alone in detecting occult metastases, such as lymph node or peritoneal involvement, in up to 20-30% of cases where conventional imaging is negative. Imaging features vary by cholangiocarcinoma subtype, influencing diagnostic approach. Intrahepatic cholangiocarcinoma (iCCA) typically appears hypovascular and hypoattenuating on arterial-phase CT, presenting as a peripheral mass with irregular margins and delayed enhancement. In contrast, perihilar cholangiocarcinoma (pCCA) manifests as a stricture at the biliary confluence on MRCP, often with upstream ductal dilatation and minimal extraductal mass effect. Recent advancements as of 2025 incorporate (AI) to enhance MRI interpretation for early cholangiocarcinoma detection. AI-enhanced models, such as algorithms applied to contrast-enhanced MRI sequences, have shown improvements in specificity compared to traditional radiologist assessments, aiding in the differentiation of small lesions from benign mimics like .

Biopsy and pathology

Biopsy is essential for definitive histopathological confirmation of cholangiocarcinoma, particularly when imaging and laboratory findings suggest malignancy but require tissue verification. Endoscopic retrograde cholangiopancreatography (ERCP) with brush cytology is a common initial approach for obtaining biliary samples, offering a sensitivity of 40-60% for detecting cholangiocarcinoma due to the limited cellular yield from strictures. Endoscopic ultrasound-guided fine-needle aspiration (EUS-FNA) provides higher diagnostic accuracy, especially for distal cholangiocarcinoma, with a sensitivity of approximately 80%, as it allows targeted sampling of periductal masses under real-time visualization. For intrahepatic cholangiocarcinoma, core needle under imaging guidance is preferred, achieving a diagnostic yield of around 85% while minimizing procedural risks, including tumor seeding along the needle tract, which occurs in less than 1% of cases. In cases where endoscopic or methods are inconclusive or not feasible, surgical approaches such as or may be employed for tissue acquisition, particularly in unresectable disease or for intraoperative staging to confirm and assess resectability. Pathological examination of biopsy samples typically confirms cholangiocarcinoma as an , characterized by glandular structures within a dense fibrous , with grading based on the degree of and mitotic activity. plays a crucial role in and from metastases, showing strong positivity for 7 (CK7+) and negativity for 20 (CK20-) in most cases, aiding in distinguishing cholangiocarcinoma from colorectal or pancreatic origins. Margin assessment is vital in surgical biopsies to evaluate local extension. Diagnostic challenges arise from the tumor's desmoplastic reaction, which creates a paucicellular fibrous matrix that reduces yield and complicates interpretation of atypical cells. To address indeterminate cytology, () analysis detects (e.g., of chromosomes 3, 7, and 17), improving for cholangiocarcinoma in brush samples without altering specificity.

Staging systems

Cholangiocarcinoma employs the tumor-node-metastasis (TNM) system developed by the American Joint Committee on Cancer (AJCC) and Union for International Cancer Control (UICC), with the 8th edition published in 2017 and implemented from 2018 onward, incorporating minor updates through 2023 to refine prognostic accuracy based on large validations; the 8th edition remains in use as of 2025. This system differentiates for intrahepatic cholangiocarcinoma (iCCA), perihilar cholangiocarcinoma (pCCA), and distal cholangiocarcinoma (dCCA), reflecting their distinct anatomical and biological behaviors, with T categories emphasizing tumor and for iCCA, while pCCA and dCCA prioritize nodal involvement and vascular encasement. For iCCA, the T category is defined as follows: T1 tumors are solitary without vascular invasion, subdivided into T1a (≤5 cm) and T1b (>5 cm); T2 includes solitary tumors with intrahepatic vascular invasion or multiple tumors irrespective of vascular involvement; T3 denotes perforation of the visceral peritoneum; and T4 indicates direct invasion of extrahepatic structures by the primary tumor. Nodal status (N1 for regional lymph node metastasis) and distant metastasis (M1) remain consistent across subtypes, but key updates from the 7th edition for iCCA include splitting T1 into size-based substages and downstaging N1 from IVA to IIIB to better align with survival outcomes. In pCCA and dCCA, staging shifts focus to vascular and periductal invasion, with T1 limited to the bile duct wall, T2 extending beyond it without liver involvement, T3 invading unilateral hepatic structures, and T4 encasing major vessels like the main portal vein or hepatic arteries bilaterally. The Bismuth-Corlette classification specifically applies to pCCA and categorizes tumors based on biliary ductal extension to guide surgical resectability: Type I involves the below the right-left ; Type II reaches the ; Type IIIa extends into the right hepatic duct origin; Type IIIb into the left hepatic duct origin; and Type IV affects both sides or is multifocal, often precluding curative resection. AJCC stage groupings integrate TNM elements into prognostic categories, where Stage I (e.g., T1 N0 M0) typically represents resectable localized disease confined to the or liver without nodal spread, while Stage IV (any T/N with ) indicates metastatic involvement rendering it unresectable in most cases. Five-year relative rates underscore these distinctions, with localized disease (Stages I-II) achieving 15-40% depending on subtype (e.g., 25% for iCCA, 19% for extrahepatic), compared to less than 5% for advanced distant metastatic disease (Stage IV). Current staging systems face limitations, particularly for iCCA, which adapts elements from hepatocellular carcinoma frameworks despite distinct histologies, leading to suboptimal preoperative applicability due to reliance on histopathological confirmation of invasion depth and nodal status that often requires surgical exploration. Additionally, the absence of molecular integration hampers precision, as genomic alterations like FGFR2 fusions or IDH1 mutations influence outcomes independently of anatomical extent. As of 2025, emerging proposals advocate incorporating serum levels (e.g., >200 U/mL as a high-risk threshold) alongside genomic into refined models for iCCA, using multi-omics and to enhance prognostication and identify candidates for targeted therapies, with clinical trials validating combinations of , nodal , and mutations like TP53 or for personalized risk stratification.

Treatment

Surgical approaches

Surgical approaches for cholangiocarcinoma are determined by tumor location and resectability, as assessed through systems, with the goal of achieving complete (R0) resection for curative intent or palliative relief in advanced cases. For intrahepatic cholangiocarcinoma (iCCA), partial remains the cornerstone of curative treatment, emphasizing negative margins greater than 1 cm to optimize oncologic outcomes. R0 resection rates following for iCCA typically range from 60% to 70%, correlating with 5-year overall survival rates of 30% to 50% in appropriately selected patients. In perihilar cholangiocarcinoma (pCCA), curative resection involves extrahepatic bile duct excision with en bloc caudate lobe and regional to address the tumor's proximity to major vascular structures. For patients with underlying (PSC) and early-stage disease, orthotopic after neoadjuvant chemoradiation under the protocol offers superior outcomes, achieving 5-year survival rates of 65% to 80%. For distal cholangiocarcinoma (dCCA), the standard curative procedure is (Whipple operation), which includes resection of the distal bile duct, pancreas, and duodenum, though it carries substantial perioperative morbidity rates of 30% to 50%. Preoperative optimization is critical, particularly for extensive resections, where embolization is routinely used to induce of the future liver remnant (FLR) to exceed 30% of total estimated liver volume, thereby reducing the risk of postoperative liver insufficiency. Advances in 2024 have expanded the role of minimally invasive techniques, such as laparoscopic , which demonstrate feasibility in approximately 40% of resectable cases, offering reduced blood loss and shorter hospital stays compared to open surgery while maintaining comparable R0 margins.

Chemotherapy regimens

Chemotherapy remains a cornerstone of systemic treatment for cholangiocarcinoma, particularly in advanced, unresectable, or metastatic settings where surgical options are limited. The standard first-line regimen for advanced biliary tract cancers, including cholangiocarcinoma, is gemcitabine combined with cisplatin, established by the phase III ABC-02 trial, which demonstrated a median overall survival of 11.7 months with the combination compared to 8.1 months with gemcitabine alone (hazard ratio [HR] 0.64, 95% CI 0.52-0.80). This regimen also improved median progression-free survival to 8.0 months versus 5.0 months (HR 0.63, 95% CI 0.51-0.77). In the adjuvant setting following curative-intent resection, monotherapy is recommended based on the phase III BILCAP trial, which showed improved disease-free survival (HR 0.75, 95% CI 0.58-0.97) and a median overall survival of 53.0 months with versus 36.0 months with observation alone (HR 0.81, 95% CI 0.63-1.04 in ). This benefit supports its use for up to 6 months postoperatively in patients with R0 or R1 margins. For second-line therapy after progression on first-line gemcitabine-cisplatin, regimens such as (folinic acid, , and ) or -based alternatives are employed, with the ABC-06 trial reporting a overall of 6.2 months with compared to 5.3 months with active symptom control (HR 0.69, 95% CI 0.50-0.97). These options provide modest extension, typically achieving overall of 6-8 months in fit patients. Neoadjuvant therapy with , , and (GCD), often followed by for borderline resectable cases, is considered exploratory but shows potential for downstaging; 2025 real-world data indicate response rates around 30-50% and conversion to resection in approximately 46% of patients. Common toxicities across these regimens include grade 3-4 in about 25% of patients receiving gemcitabine-cisplatin and peripheral neuropathy associated with in , affecting up to 20% at grade 3 or higher. Management involves dose reductions or delays, with 2025 protocol updates emphasizing prophylactic growth factors for and early neuropathy screening to optimize tolerability.

Radiation and locoregional therapies

plays a crucial role in the management of cholangiocarcinoma, particularly for unresectable tumors or as an following . External beam radiation therapy (EBRT) is commonly employed in the adjuvant setting for patients with close surgical margins, defined as less than 5 mm, where it has been shown to provide an overall survival benefit of 10-15 months compared to alone. Stereotactic body (SBRT), a precise form of EBRT, is particularly effective for intrahepatic cholangiocarcinoma (iCCA), achieving local control rates of approximately 80% at one year while minimizing damage to surrounding liver tissue. Brachytherapy offers a targeted approach for perihilar cholangiocarcinoma (pCCA), often delivered intraductally via (ERCP). This method involves placing radioactive sources directly into the ducts to deliver high-dose radiation locally, providing palliative relief from in about 70% of cases and improving biliary drainage. It is especially useful for patients with unresectable disease where systemic therapies alone are insufficient. Locoregional therapies, such as transarterial chemoembolization (TACE) and transarterial radioembolization (TARE) using microspheres, are tailored for iCCA to target tumor vascularity within the liver. TACE combines delivery with to block blood supply, while TARE utilizes radioactive particles to irradiate tumors selectively; both approaches yield of 6-12 months and objective response rates around 30% in advanced cases. These therapies are often considered when surgical options are not feasible due to tumor extent or patient comorbidities. Combined chemoradiation (ChemoRT) regimens, typically incorporating 5-fluorouracil (5-FU) with EBRT, are standard for unresectable extrahepatic cholangiocarcinoma (eCCA), enhancing local control and symptom palliation by synergistically attacking tumor cells through radiosensitization. As of 2025, advances in have emerged as a promising , delivering with reduced toxicity to the liver and adjacent organs compared to conventional photon-based EBRT, potentially allowing higher doses to be tolerated in iCCA patients.

Targeted and immunotherapies

Targeted therapies for cholangiocarcinoma focus on inhibiting specific molecular alterations identified through testing, such as (FGFR) fusions, 1 (IDH1) mutations, and human epidermal growth factor receptor 2 (HER2) amplifications or overexpression. These approaches have expanded treatment options for patients with advanced disease, particularly after progression on standard . Immunotherapies, including inhibitors, have also shown promise, especially when combined with or in -selected subsets like microsatellite instability-high (MSI-H) tumors. Pemigatinib, a selective FGFR inhibitor, was the first targeted agent approved for cholangiocarcinoma harboring FGFR2 fusions or rearrangements, based on the phase 2 FIGHT-202 trial. In this trial, previously treated patients achieved an objective response rate (ORR) of 35% and median (PFS) of 7 months. The U.S. (FDA) granted accelerated approval in April 2020, with confirmation pending further data on overall survival. For IDH1-mutated cholangiocarcinoma, targets the mutant enzyme to restore normal cellular metabolism. The phase 3 ClarIDHy trial demonstrated a PFS of 2.7 months with versus 1.4 months with placebo in pretreated patients, leading to FDA approval in August 2021 for advanced or metastatic disease. Updated analyses showed a median overall survival of 10.3 months versus 5.1 months, though crossover effects influenced outcomes. Immunotherapy has transformed frontline care through the integration of , a inhibitor, with and . The phase 3 TOPAZ-1 trial reported a overall survival of 12.8 months with the combination versus 11.5 months with alone, resulting in FDA approval in September 2022 for unresectable or metastatic cancers, including cholangiocarcinoma. In the MSI-H subset, which comprises about 5% of cases, response rates to exceed 40%, highlighting the value of biomarker-driven selection. Emerging HER2-targeted options include , an antibody-drug conjugate, which showed exploratory activity with an ORR of 25% in HER2-expressing advanced cholangiocarcinoma in early-phase studies. Recent 2024-2025 developments feature nanoliposomal combinations with and leucovorin, which have been evaluated in second-line therapy; however, the phase 2 NALIRICC did not show a PFS benefit (2.6 months vs 3.1 months with 5-FU/LV alone). Other studies, such as the phase 2 NIFTY , reported improved PFS (4.2 months vs 1.7 months). Additionally, bispecific antibodies like zanidatamab, targeting HER2, received FDA accelerated approval in November 2024 for HER2-positive cases, with ongoing trials evaluating agents such as zenocutuzumab for NRG1 fusions.

Prognosis

Survival statistics

Cholangiocarcinoma exhibits poor overall prognosis, with a 5-year relative of 13% across all stages based on data from the program (2015–2021). Intrahepatic cholangiocarcinoma (iCCA) has a 5-year of 10%, while extrahepatic cholangiocarcinoma (eCCA) is 13%. These figures reflect the aggressive nature of the disease and challenges in early detection. Survival varies significantly by disease stage at and subtype. For iCCA, localized disease has a 5-year rate of 25%, regional spread 12%, and distant 3%. For eCCA, rates are 19% localized, 20% regional, and 2% distant.
SubtypeStage5-Year Relative Rate
iCCALocalized25%
iCCARegional12%
iCCADistant3%
eCCALocalized19%
eCCARegional20%
eCCADistant2%
From 2015 onward, targeted therapies have shown improvements in median overall survival in select advanced cases, with real-world data indicating 22 months versus 12 months with alone. Subtype-specific outcomes post-resection highlight variability: perihilar cholangiocarcinoma (pCCA) following achieves 5-year survival rates up to 70% in eligible patients under protocols like the regimen. In contrast, distal cholangiocarcinoma (dCCA) after (Whipple procedure) yields 5-year survival of 25% to 35%. For unresectable disease, median overall has reached about 12 months with modern systemic regimens, including gemcitabine-cisplatin combinations and subsequent targeted agents. Factors such as tumor biology and response can modify these baseline metrics, as explored in related sections.

Influencing factors

Several clinical and pathological factors significantly influence the of cholangiocarcinoma, with surgical outcomes playing a pivotal role. Achieving R0 resection, defined as complete tumor removal with negative margins, is associated with a (HR) of 0.5 for recurrence compared to incomplete resections, substantially improving disease-free . Similarly, lymph node positivity (N+) markedly worsens overall (OS), reducing it by approximately 50% in affected patients, as nodal involvement facilitates distant . Tumor characteristics further modulate , often through aggressive biological behavior. High-grade tumors (grade 3) confer an of 2 for OS, reflecting increased and that drive rapid progression. Elevated preoperative levels exceeding 1000 U/mL indicate advanced disease burden and are linked to an of 1.8 for poorer survival outcomes. Microvascular invasion, identified histopathologically, independently predicts worse , as it promotes hematogenous spread and recurrence. Patient-related factors, including comorbidities and , also impact survival. Advanced age greater than 70 years is associated with an HR of 1.5 for OS, attributable to reduced physiological reserve and tolerance to therapy. An Eastern Cooperative Oncology Group (ECOG) greater than 1 correlates with diminished survival, with HRs exceeding 2 due to frailty limiting treatment efficacy. , defined as below 3.5 g/dL, serves as a marker of and , yielding an HR of 1.6 for adverse outcomes. Molecular alterations offer prognostic insights, particularly in the context of targeted interventions. Presence of FGFR fusions, found in 10-15% of cholangiocarcinomas, is associated with improved (PFS) of approximately 4 additional months under FGFR inhibitor therapy compared to standard care. As of 2025 studies, microsatellite instability-high (MSI-high) status, occurring in about 5% of cases, enhances responses, with median OS of approximately 30 months in metastatic patients treated with inhibitors compared to 13 months with standard care.

Prevention and research

Preventive strategies

Preventive strategies for cholangiocarcinoma primarily target modifiable risk factors, with a focus on high-risk populations such as those in endemic areas for parasitic infections or with chronic liver conditions. Infection control measures are crucial in regions where liver flukes like Opisthorchis viverrini are prevalent, as repeated infections promote chronic inflammation leading to cholangiocarcinoma. Treatment with the anthelmintic drug praziquantel effectively eliminates fluke infections and decreases the associated risk of cholangiocarcinoma, though reinfection remains common due to ongoing environmental exposure. Similarly, hepatitis B virus (HBV) infection is a recognized risk factor for intrahepatic cholangiocarcinoma, and universal HBV vaccination prevents chronic infection, thereby reducing liver cancer risk by approximately 70% in vaccinated populations, with benefits extending to cholangiocarcinoma prevention through decreased viral oncogenesis. For patients with (PSC), a major risk factor, management includes the use of (UDCA), which has shown potential to lower cancer incidence in some studies, though its role remains controversial due to mixed evidence on long-term efficacy and possible adverse effects at high doses. Surveillance with annual imaging, such as MRI/MRCP combined with monitoring, is recommended for PSC patients to detect early cholangiocarcinoma, with sensitivity approaching 100% for detecting cholangiocarcinoma when combining MRI/MRCP and (cut-off ≥20 U/mL), though specificity is lower at around 38-80%. Additionally, surveillance is advised for PSC patients with to mitigate colorectal neoplasia risks that may indirectly influence overall cancer burden. Lifestyle modifications can further mitigate risk, particularly through and avoidance. , defined as ≥30 kg/m², elevates cholangiocarcinoma risk by promoting metabolic inflammation, and each 5 kg/m² decrease in is associated with an approximately 24% lower risk for intrahepatic cholangiocarcinoma, based on the inverse of ratios from pooled studies. is associated with a reduced for cholangiocarcinoma approaching that of never-smokers (OR ≈1), countering the 20-70% increased risk from active use. In individuals with choledochal malformations, prophylactic surgical excision of the cyst, typically followed by hepaticojejunostomy, is recommended to prevent progression to cholangiocarcinoma, substantially lowering the lifetime malignancy risk from up to 11-30% in untreated cases to under 5% post-resection. Routine population-based screening for cholangiocarcinoma is not recommended due to low incidence and lack of cost-effective tools, but targeted surveillance is essential for high-risk groups like those with , limiting annual to improve early detection without broad overutilization.

Emerging developments

Recent advancements in liquid biopsy techniques, particularly (ctDNA), have shown substantial promise for early of cholangiocarcinoma, addressing the challenge of detecting the disease at stages amenable to curative intervention. In a pilot trial, ctDNA demonstrated 100% sensitivity and 75% specificity for diagnosing biliary tract cancers, including cholangiocarcinoma, with high plasma-tissue concordance for key mutations such as IDH1 (87%-100%) and BRAF (100%). Ongoing studies are optimizing ctDNA for early detection and post-resection , potentially enabling personalized in high-risk populations. Research into novel molecular targets is expanding therapeutic options beyond established pathways, with KRAS G12C inhibitors emerging as candidates despite the mutation's rarity in cholangiocarcinoma (approximately 2% of cases). Phase II trials of KRAS G12C inhibitors like and in KRAS-mutated solid tumors, including cancers, have reported objective response rates (ORR) around 20% in second-line settings, prompting recommendations for routine testing to identify eligible patients. Complementing this, claudin-18.2 (CLDN18.2), which shows variable expression across subtypes and populations—up to 43% in intrahepatic and over 80% in extrahepatic cases in some Asian cohorts, but typically 8-18% in Western series, has become a focus for antibody-drug conjugates (ADCs). Agents such as AZD0901, IBI343, and LM-302 are in phase I/II/III trials for CLDN18.2-positive solid tumors, building on zolbetuximab's demonstrated (PFS) benefit of 10.61 months versus 8.67 months when combined with in positive gastric cancers, with similar potential in biliary malignancies due to shared expression profiles. Immunotherapy innovations are broadening the arsenal against cholangiocarcinoma, with expansions into neoantigen vaccines and chimeric antigen receptor T-cell (CAR-T) therapies targeting biliary cells. Personalized neoantigen vaccines, such as mRNA-based iNeo-Vac-R01 combined with PD-1 inhibitors, are under investigation in phase I trials (e.g., NCT06956716), showing feasibility and immune activation in early data, including a case of clinical benefit in advanced intrahepatic cholangiocarcinoma through T-cell responses against tumor-specific mutations. Similarly, CAR-T therapies remain largely preclinical but are advancing to phase I/II, targeting antigens like (MSLN), mucin-1 (MUC1), and (EGFR) on biliary cells; preclinical models demonstrate reduced tumor growth, while early clinical results indicate stable disease in up to 59% of patients with EGFR-targeted CAR-T. The integration of artificial intelligence (AI) with patient-derived organoids (PDOs) is revolutionizing personalized modeling for cholangiocarcinoma, enabling high-fidelity predictions of treatment responses to bridge gaps in preclinical testing. PDOs from biliary tract cancers recapitulate tumor genomics and histology, with drug screening achieving predictive accuracy for chemotherapy responses via support vector machine models yielding area under the curve (AUC) values of 93.9% for 5-fluorouracil and 99.4% for cisplatin, validated in 92.3% of clinical cases. AI-enhanced approaches, such as transfer learning models fine-tuned on organoid data, further improve response forecasting across cancers, offering up to 85% accuracy in analogous solid tumor predictions and facilitating tailored therapies for cholangiocarcinoma patients. Efforts to address key gaps in cholangiocarcinoma management include developing superior second-line options, exemplified by combinations that extend PFS in disease. Nanoliposomal combined with and leucovorin has shown PFS improvements in cancers post-gemcitabine progression, with one study reporting significant gains over standard care (e.g., median PFS of 4.2 months versus 2.8 months in exploratory analyses), though larger are needed to confirm broad efficacy. However, the phase III NALIRICC (2024) found no significant PFS improvement with this regimen compared to 5-FU/LV alone in advanced cancers (4.0 vs. 3.2 months), underscoring ongoing needs for effective second-line therapies. Additionally, global disparities in access persist, with higher incidence and mortality among Asian, , , and non-Hispanic populations due to socioeconomic factors, geographic barriers, and underrepresentation in (e.g., only 7% enrollment in key studies), underscoring the need for equitable and care distribution.