Children with univentricular heart disease surgically palliated with a Fontan circulation have experienced remarkably increased survival into adulthood during the last few decades, up to 61%–85% worldwide (1–4). Even better results have been reported for patients operated on after 2001, who have a 95% 10-year survival rate (5). The number of patients with a Fontan circulation is steadily increasing and was estimated to be 66 per million in 2020, of whom 55% are adults, 17% adolescents, and 28% children (3, 6).

Since the first reports of pioneering and lifesaving operations performed by Francis Fontan and Guillermo Kreutzer in the early 1970s (7, 8) in patients with tricuspid atresia, this procedure has been performed on many different types of congenital heart anomalies where a two-chamber circulation cannot be achieved.

The main features of the Fontan circulation are increased central venous pressure (CVP), low cardiac output, and lymphatic overflow with obstruction. There is an increasing awareness that chronic low flow in the Fontan circulation has a deleterious effect on cardiac function itself, but it also causes complications in nearly all organ systems, such as the lungs, brain, liver, bowels, kidneys, musculoskeletal system, and lymphatic system. The development of liver fibrosis and cirrhosis, known as Fontan-associated liver disease (FALD), is of special and growing concern regarding this young population.

Although liver fibrosis in a patient following Fontan palliation was first described in 1981, it has not been widely acknowledged until the last few decades (9, 10). The duration since Fontan completion has been associated with an increased stage of fibrosis (11–13). However, there are indications that in utero pre-Fontan insults may have implications for fibrosis development (14) and that FALD may start early, in childhood, with the development of subclinical fibrosis and cirrhosis into adolescence, which progresses to end-stage liver disease. As in other types of chronic liver disease, there is a risk of transformation to malignancy, particularly hepatocellular carcinoma (HCC), with an estimated prevalence of 0.18–1.3% in FALD (15, 16). Most reported cases of HCC have been reported in young adults, but single cases have been reported in early adolescence (15, 17).

The pathogenic mechanisms underlying FALD are still not fully understood. The course of development is known to be heterogeneous and variable among patients, with many unanswered questions about disease diagnosis, development, and prognosis. Most of the knowledge gathered to date is based on retrospective data from small populations. Prospective, longitudinal, and multicenter studies are urgently needed. This requires a consensus on how and when FALD should be diagnosed, and how disease development needs monitoring with regard to treatment optimization and surveillance for malignant transformation. Questions surround the process, timeline, and screening tools involved in forming this consensus.

Since early-stage FALD is characterized by subclinical development, imaging screening has become an important part of diagnosis and follow-up, together with clinical evaluations and scoring systems, histopathology, and serological data. This requires appropriate healthcare coordinated from pediatric to adult care, including not only cardiologists and hepatologists but also multiple subspecialists familiar with the consequences and pathophysiology of Fontan physiology.

Single-ventricle circulation is a rare disorder and one of the most complex types of congenital heart disease (CHD). It constitutes less than 10% of CHD and is rather an umbrella category for diverse defects that all share one anatomic feature. Hypoplastic left heart syndrome is the most frequent type of defect, representing 1.4%–3.8% of CHD (18, 19). Other defects include unbalanced atrioventricular septal defects and hypoplastic right heart complexes with pulmonary atresia and tricuspid atresia.

The Fontan circulation is a definitive palliation for single-ventricle physiology and is currently achieved with stepwise sequential operations during the first years of life, with the final Fontan operation completed at 2–4 years of age.

The first procedure, performed shortly after birth, when necessary, ascertains blood flow and oxygenation to both the lungs and body. In addition, an unobstructed return of pulmonary and systemic venous blood is assured by a large atrial septal defect. In the second operation, the “bidirectional cavopulmonary connection” or “bidirectional Glenn procedure” is performed at approximately 3–6 months of age. Systemic venous return from the upper body is directly connected to the pulmonary arteries via the superior vena cava. In the final Fontan operation, pulmonary and systemic circulations are connected in series, now totally bypassing the subpulmonary ventricle directly channeled into the pulmonary arteries from the systemic veins by an intra-atrial “lateral” tunnel or currently by a synthetic extracardiac conduit, the “total cavopulmonary connection” (TCPC) (Figures 1, 2). This direct connection to the pulmonary arteries results in a slightly increased CVP to ensure blood flow into the lungs. Increased CVP limits the ventricular volume load reserve, which further results in a decreased cardiac output reserve (20).

Today, the operative mortality for the Fontan operation in most centers is relatively low (<3%), and the survival rate has increased considerably due to refinements in operative techniques, as well as pre-, peri-, and postoperative care (5). However, different organ complications develop over time, and most patients develop arrhythmias in the second or third decades of life (5, 21). On the other hand, there is wide functional variety in patients living with Fontan physiology, and there are patients with close to healthy cardiorespiratory fitness and without cardiac medication besides mandatory thromboemboli prophylaxis.

“Fontan failure” is the term used for a dysfunction originating from the heart itself or noncardiac complications including persistent congestion with edema, low cardiac output with limited exercise tolerance, an arrhythmia, protein-losing enteropathy (PLE), or plastic bronchitis (22, 23). This is associated with reduced quality of life and increased mortality, as well as limited options of treatment other than a cardiac transplant, which results in a considerably higher perioperative risk of mortality for such patients than other transplant candidates, especially in adults (24, 25). For a failing Fontan circulation, a total workup for an eventual transplantation should include an evaluation of liver disease comprising a physical examination, serological evaluation, and hepatic imaging.

The mechanisms underlying the pathophysiology of FALD are multifactorial and not fully understood. Most of our knowledge is based on animal models or clinical/histological data from patient cohorts with other chronic liver diseases. The main factors that influence the FALD process are summarized in Figure 3.

FALD most often exhibits subclinical development during the early phases. This demonstrates the need for disease detection screening. Clinical and laboratory findings vary according to the disease stage, and in many pediatric patients, they may be subtle, resulting only in hepatomegaly due to congestion (11, 43, 44). Even in the advanced stage of FALD with established but compensated cirrhosis, the clinical symptoms may be absent or present with more nonspecific symptoms, such as anorexia, fatigue, and weight loss (43, 45, 46). Importantly, the presence of ascites in the Fontan circulation can make it difficult to diagnose whether there is a combined cardiac and hepatic dysfunction or the presence of PLE. Pediatric patients with a Fontan circulation and ascites may have other abnormalities such as obstruction of the Fontan conduit. To differentiate ascites of hepatic from cardiac origin, brain natriuretic peptide (BNP) can be used to exclude a cardiac origin (47).

In late-stage and decompensated liver disease, ascites, jaundice, variceal bleeding, and hepatic encephalopathy may play a role and suggest the presence of PHTN, which is associated with adverse outcomes in the population with a Fontan circulation (48, 49). Identifying PHTN is important for optimizing clinical management, that is, screening for variceal bleeding and diuretic medication, and may implicate health outcomes and the decision for liver transplantation (49).

Variceal bleeding can be reported after the Fontan procedure, with a variable incidence ranging from 9.3%–38% (50, 51). In children, the prevalence of varices is even lower (about 9%), which suggests that its development is a late complication (51). Because of the high risk of mortality of this complication (15%–20%) (52), upper gastrointestinal endoscopy is commonly recommended for adult patients with cirrhosis or signs of PHTN. Imaging is not recommended as part of the screening for varices, although they can be observed with cross-sectional imaging (48).

Laboratory findings are characteristically only slightly affected by liver congestion. There are often increased aminotransferases in approximately 30% of cases accompanied by a slight increase in alkaline phosphatase (ALP), gamma-glutamyl transferase (GGT), and indirect bilirubin, in addition to a prolongation of prothrombin time (53–55). Decreased serum albumin is noted in 30%–50% of patients with chronic heart failure (56).

HCC is a rare complication with an estimated prevalence of 0.18%–1.3% in the population with a Fontan circulation (15, 16). The youngest patient reported was 12 years of age at the time of diagnosis, while the median age after Fontan completion was 22 years in two large retrospective multicenter studies (15, 57). Only 50% of patients were symptomatic at the time of diagnosis, presenting with symptoms including jaundice, abdominal pain, ascites, dyspnea, hematemesis, and fever. In a multicenter retrospective study including 54 patients with HCC who underwent a Fontan operation, the mean age was 30 years and the median tumor size at diagnosis was 4 cm (range, 1–22 cm) (57). Survival was poorer if patients had clinical symptoms at diagnosis and if the tumor size was >4 cm; the cumulative survival rate was only 50% after 1 year (57). An important feature found was that 50% of patients did not have cirrhosis when diagnosed with HCC, indicating that having established cirrhosis is not a requirement for HCC development in patients with a Fontan circulation. This has also been confirmed in smaller studies on such patients. Mazzarelli et al. revealed that HCC was registered in three patients without an association with the degree of hepatic cirrhosis, which was also confirmed in a meta-analysis by Rodriguez de Santiago et al. (58, 59). Longitudinal studies are needed to identify the risk factors for developing HCC and to find a suitable surveillance strategy to identify HCC at an early stage.

As mentioned previously, the diagnosis of FALD is a clinical challenge. However, the true incidence of FALD is not known and likely under-recognized since there is no consensus on a uniformly accepted definition of the disease. There are different definitions of FALD based on serological biomarkers, combined radiological and serological scores, and histological and clinical evaluations. A recent expert consensus statement from an association of several leading societies focused on CHD and the care of patients with a Fontan circulation proposed the following definition of FALD: “The broad spectrum of liver disease and its consequences, attributable to Fontan hemodynamics. FALD includes varying is degrees of hepatic fibrosis, compensated and decompensated cirrhosis, focal nodular hyperplasia [FNH], laboratory evidence of hepatic injury or impaired synthetic function, and hepatocellular neoplastic lesions” (60). This indicates that FALD can be present even without Fontan failure.

Liver biopsy remains the gold standard for the diagnosis of adult noncongestive liver disease. Nevertheless, this is more complicated in the case of FALD because there may be sample errors due to the heterogeneous nature and patchy distribution of fibrosis (20). With the invasive procedure, there is a potentially increased risk of bleeding due to anticoagulant medication and high CVP, and biopsy is therefore not suitable for routine longitudinal follow-up. In the pediatric population, sedation and general anesthesia are often required.

Consequently, noninvasive diagnosis and staging could be an attractive alternative, but with different limitations. Imaging alone cannot reliably detect early stages of fibrosis. Ubiquitous liver congestion in FALD can present with confounding imaging features that resemble advanced cirrhosis. Congestion is also a confounder for noninvasive imaging of fibrosis biomarkers, such as elastography (61, 62). In addition, serological markers of liver function do not correlate with liver fibrosis severity (13, 63).

Ultimately, the definition of advanced FALD with cirrhosis consists of a combination of supportive findings from clinical, laboratory, and imaging parameters of the liver and abdomen (presence of varices, portosystemic collaterals, ascites, and splenomegaly) (13, 56).

The following recommendations are mainly for advanced stage disease:

Pharmacological treatment: Medication can be reviewed and adjusted to ameliorate the deleterious effects of the Fontan circulation. However, well-documented pharmacological treatment options are limited to agents that decrease pulmonary vascular resistance, such as sildenafil and bosentan (12, 132).

Optimization of the Fontan circuit: Determining any possible surgical or interventional method to improve hemodynamics in the Fontan circulation is important (27, 133). This includes interventions such as maintaining or enlarging fenestration, the stenting of pulmonary vascular obstructions, or other measures to ensure that there is no stenosis in the Fontan circuit and manage venovenous collaterals. There are no clear recommendations on when and how to intervene, and decisions are made on an individual case-by-case basis. In this regard, preprocedural imaging can provide information to select patients in need of treatment and further hemodynamic investigation, identifying stenosis in the anastomosis or development of collateral circulation. In particular, multimodal longitudinal follow-up for an individual patient is necessary to detect sudden hemodynamic and morphological changes in the Fontan circuit.

Improvement of specific complications like PLE and PHTN: PLE is diagnosed by elevated fecal α1-antitrypsin in combination with decreased serum albumin levels. Identifying lymphatic abnormalities and sites of intrahepatic obstructions and leakage can be important in evaluating possible interventional treatment strategies (100, 101). For specific cases, a few small studies from tertiary and specific centers have investigated dynamic intrahepatic MR lymphography to guide therapeutic and new catheter-based interventional treatments (103, 104).

Clinical signs of PHTN, such as ascites, variceal bleeding, and hepatic encephalopathy, occur in a more advanced stage, are associated with adverse outcomes in the Fontan circulation, and have implications for the decision to perform transplantation (49). The hepatic vein pressure gradient (HPVG) can be used to quantify PHTN in noncongestive cirrhosis and risk stratification of its complications. However, some studies have shown a poor correlation between the HPVG and FALD stage (76, 134). Evaluating serum albumin in ascites to measure gradient ascite total protein and serum BNP may help differentiate the origin of ascites as cardiac or hepatic (135). Nevertheless, cardiac failure, advanced liver disease, PHTN, and PLE may often overlap in patients with a Fontan circulation, which is important to consider when determining treatment.

Studies have revealed a correlation between a high MELD XI score and decreased survival after transplantation (143, 144). Advanced liver cirrhosis and malignant transformation might prohibit heart transplantation or require combined liver and heart transplantation. The indication and patient selection for a combined liver–heart transplant remains a challenge in the absence of guidelines, with experience only from small outcome studies (83). The Organ Procurement and Transplantation Network database collects information on the outcomes of Fontan physiology and FALD from small single centers where differences or a lack of diagnostic codes are frequent, which make clear conclusions difficult (145). The indications for transplantation, therefore, differ between institutions, and for current practice regarding a cardiac vs. combined heart–liver transplant, the decision is case-specific. Liver transplantation alone is not recommended because the cause of liver failure and high CVP will remain and be deleterious for the new liver (65). A few studies have shown no differences in survival between cirrhotic and non-cirrhotic patients with Fontan circulation after heart transplantation (146–148). This indicates that severe fibrosis or cirrhosis, while compensated, is not a contraindication for isolated heart transplantation. Finally, the ability to reverse structural liver changes due to FALD after a heart transplant and conversion to biventricular circulation is not known (55), but in one study, regenerative capacity was reported to be higher than expected compared to those of other reversible liver diseases (133).

For adult patients with Fontan physiology, the number of heart and liver transplantations in the United States is steadily increasing (149). Many centers proceed with combined heart and liver transplantation because of the virtually universal presence of advanced liver fibrosis. Among pediatric patients, ventricular systolic dysfunction is the most common indication for cardiac transplantation; it is reported in 40%–60% of such patients (150–152). A few studies have revealed that in children, cardiac transplantation alone may be considered when indicated within a few years of the Fontan surgery (148, 153, 154). Initially, there were concerns of inferior survival in children transplanted for Fontan physiology compared to those transplanted for a non-CHD diagnosis (155). However, heart transplant outcomes for children in the current era have improved significantly, with better results than those of adult patients with a Fontan circulation. A pediatric heart transplant study described, in 2006, a 1-year survival rate of 76% after transplantation in children with a Fontan circulation, but a survival rate significantly lower than 91% in control participants without CHD (156, 157). In 2017, new data from an updated version of the above study reported a 1-year survival rate of 89% that was no longer distinguishable from the control group's survival rate, which was also confirmed in a more recent study (158, 159).

Combined heart–liver transplantation in pediatric patients is rare and data on outcomes are sparse. A single-center small series revealed limited but good early post-transplant outcomes in mostly older patients. In one study of nine patients with a median age of 20.7 years (range, 14.2–41.3 years), all with radiologic and pre-transplant evidence of cirrhosis, the 1-year survival rate without rejection was revealed to be 100% (160). Similar 1-year survival rates have been observed in other studies (161, 162). Recent studies indicate a decreased incidence of rejection after a combined heart–liver transplant, leading to the hypothesis that multiorgan transplantation induces immunotolerance and protection against rejection (162, 163); however, this needs to be further validated.

On the other hand, the development or regression of liver disease after heart transplantation in children has not been well studied. A few studies have used imaging in a follow-up of 1 year or longer after cardiac transplantation. In a retrospective study of 41 patients (median age, 12 years) with fibrosis, cirrhosis on pre-transplant imaging (29.2%) displayed less prevalence and regression in 19 patients’ imaging findings. There was no development of HCC or liver failure during short-term follow-up (164). However, continued post-transplant monitoring might be of importance, given the persistence of imaging findings suggestive of FALD, to some degree (164, 165).

The optimal surveillance strategy for FALD is still debated, especially in pediatric patients. Evidence-based studies are affected by short observational periods, and until now, the proposed published guidelines were mainly based on experience within adult age groups. Post-Fontan time is the most important predictor of advanced FALD. The risk of advanced disease is low up to 5 years after Fontan completion but increases significantly after 15 years (18, 40, 41, 54, 58). In a recent systematic review and retrospective study, HCC was unlikely within the first 10 years after the Fontan surgery (HCC was only diagnosed once before this time point), with an exponential risk markedly increasing in the third decade (59, 166). Hence, there is a general consensus that systematic monitoring for FALD and HCC is definitely indicated at 10 years post-Fontan and earlier if there are signs of Fontan failure or decreased liver function (11, 12, 56, 167). These investigations should include clinical examinations, blood tests, and imaging with US, CT, or MRI.

However, there is increasing evidence that FALD might develop earlier, within the first 5 years postoperatively, and that liver disease may even predate the Fontan procedure. Severe liver fibrosis in patients as young as 10 years of age has been described. The aim of surveillance is to diagnose FALD at a sufficiently early stage to consider interventions for optimizing the Fontan circulation in due time to prevent or delay the development of advanced fibrosis (167). There is growing evidence that an initial screening at baseline (before the Fontan creation) followed by two to three annual FALD screenings for children and adolescents, including clinical examination, biochemical evaluation, and liver Doppler US (with or without a liver stiffness assessment), might be favorable and allow early FALD detection. This scheme will provide the possibility for timely intervention in adolescents and young adults with failing Fontan physiology and might contribute to determining the optimal time point for transplantation. This is in line with the international guidelines from the American Heart Association of 2019 and the recommendations of the European Society of Pediatric Radiology (Figure 12) (11, 12, 27, 56, 167, 168).

As already mentioned, the role of liver biopsy in the follow-up of FALD also lacks consensus.

In screening young patients for liver disease and cancer development, psychological factors should also be considered. Lifelong surveillance for cancer from childhood may have important implications on the quality of life for patients and caregiver anxiety (169). The American Heart Association also recommends that such patients should be monitored in centers specialized in the Fontan circulation and with a multidisciplinary approach to diagnose and observe the different possible organ complications and development of FALD (12). This includes screening for malignancy, where imaging plays an important role, together with clinical scoring systems, biochemical workups, and biopsies.

FALD is a global liver disease that affects virtually all patients with a Fontan circulation, has a heterogeneous time course, and often commences in childhood. There are still many questions regarding the exact pathophysiology and development of FALD, and why certain patients develop malignancy. Lifelong follow-up and surveillance are mandatory to ensure the optimal timing for treatment and eventually transplantation. In this regard, monitoring with imaging plays an important role since clinical signs are indolent and serological markers are only slightly affected until the advanced stage of liver disease. Nevertheless, determining optimal surveillance protocols requires further investigation in longitudinal multicenter research studies. Importantly, Fontan physiology is a multiorgan disease where surveillance requires the involvement of a multidisciplinary team in cardiology, hepatology, anesthesiology, pathology, and radiology, in which all members are specialized in Fontan physiology and its complications.