In this study, suspected drug signals related to pediatric liver injury were identified by conducting a disproportional analysis of data from FAERS in the period 2004–2020 to provide information on safe medication for children. To the best of our knowledge, this study confirms the issues raised in the previous literature and provides new insights into pediatric liver injury associated with drugs. In 2010, Ferrajolo et al. explored drug-induced hepatic injury in children based on VigiBase from 2000 to 2006 in a case/non-case study [8]. Both paracetamol and methotrexate were among the top 10 drugs according to the number of reports in previous and current studies. Forty-two suspected drugs identified in the former (e.g., basiliximab, caspofungin, isoniazid) were also identified in our results. Basiliximab, a novel selective anti-human interleukin-2 receptor monoclonal antibody used for immunosuppressive therapy, was the only novel signal detected in children in a previous study, which suggested future monitoring, and this was confirmed herein. Liver injury associated with basiliximab has not been included in the FDA’s prescribing information, but the incidence of abnormal liver biochemical parameters associated with basiliximab, which is greater than 5%, has been indicated by Japanese package inserts [32, 33]. A randomized controlled trial of adults found an increase in serum alkaline phosphatase within the first month after the administration of basiliximab, but it was considered to be “functional cholestasis” [34, 35]. No elevated liver enzyme levels or hepatotoxicity were reported in clinical trials among children treated with basiliximab [36, 37].
Forty-three signals found in Ferrajolo’s study (chlorprothixene, methylphenidate, infliximab, etc.) were not included here. The reasons for this could be as follows: (1) different data sources. VigiBase is the world’s largest database of individual case safety reports, having collected data on AEs from more than 130 countries since the late 1960s, whereas FAERS has collected data reported to the FDA only since 2004 [38]. (2) Distinct algorithms have been used for signal detection. Only ROR was adopted in the former, whereas ROR and PRR were combined here. (3) Some drugs were withdrawn from the market in their early days and their AE reporting ratios were diluted. Compared with the 2010 study, 222 suspicious drug signals were newly detected in the current study, including drugs marketed before 2006, such as ganciclovir and amlodipine, and after 2006, such as vandetanib and gemtuzumab.
Anti-infectives, especially antibacterial drugs, are extensively applied, and their irrational use can cause hepatotoxicity. The immature liver function in children and increased hepatotoxicity caused by the concomitant administration of multiple antibacterial drugs make children more vulnerable to hepatic injury than adults. The results of anti-infectives for systemic use, as the most reported class in our study, were consistent with the published literature [39, 40]. Representative drugs included trimethoprim-sulfamethoxazole (TMP-SMX), ceftriaxone, fluconazole, and isoniazid.
TMP-SMX exerts its antimicrobial effect by blocking the metabolism of folic acid through a dual pathway and can cause DILI via allergic reactions (fever, rash, etc.) [41]. Bell et al. [42] reported a case of DILI induced by TMP-SMX; specifically, a 9-year-old boy with a community-acquired methicillin-resistant Staphylococcus aureus skin and soft tissue infection received TMP-SMX, and 14 days after administration, he developed fever, vomiting, and abdominal pain, with poor appetite and mentality. He was diagnosed with TMP-SMX-induced liver injury based on biochemical tests and the exclusion of other factors contributing to hepatic injury.
Ceftriaxone is a semi-synthetic, third-generation cephalosporin that mainly causes cholelithiasis or bile stasis [43]. One retrospective study showed that 3.2% of patients treated with ceftriaxone might develop liver injury [44]. Liver injury caused by ketoconazole in children mostly presents as elevated levels of direct bilirubin and liver enzymes [45]. Liver functions usually recover after drug cessation, but severe cases can also develop into liver failure [46, 47]. Animal studies have confirmed the dose-dependent liver injury induced by ketoconazole [48].
Isoniazid is a first-line anti-tuberculosis drug. Approximately 10–20% of patients administered isoniazid develop the transient elevation of alanine aminotransferase, and fewer than 1–3% develop severe liver injury or even liver failure [49, 50]. A greater risk of isoniazid- and rifampicin-related liver injury in children (6.9% in children and 2.7% in adults) was reported in a retrospective study [51]. In the US, the incidence of isoniazid-associated hepatotoxicity was determined to be 1% in children treated for latent tuberculosis infection, and there was a synergistic harmful effect on the liver when isoniazid and rifampin were used in one prescription [52, 53]. It is generally believed that isoniazid-induced liver injury is attributed to the toxicity of the metabolites acetylhydrazine and hydrazine [54]. Moreover, mitochondrial damage caused by isoniazid-induced oxidative stress and lipid peroxidation stimulated by isoniazid and its metabolites has also been discussed [55].
In this study, six signals were found to be disproportionally associated with pediatric liver injury for the first time, namely acetylcysteine, thiopental, temazepam, nefopam, primaquine, and pyrimethamine. Acetylcysteine (also known as N-acetylcysteine, NAC) was detected as a disproportional signal associated with pediatric hepatic injury (ROR, 3.0; 95%CI 1.9–4.8). None of these HAEs had been reported in either package inserts or the published literature since NAC was marketed. NAC is the only drug approved by the FDA for the treatment of DILI caused by acetaminophen (APAP) overdose and might prevent hepatic injury by restoring glutathione levels [56]. A dosage of NAC for children greater than 5 kg is set based on clinical practice; however, the safety and effectiveness of NAC have not been verified in adequate and well-controlled studies. The ACG Clinical Guideline: Diagnosis and Management of Idiosyncratic Drug-Induced Liver Injury suggests the use of NAC for children with ALF caused by severe DILI, as a significantly lower 1-year spontaneous survival rate was associated with the intravenous infusion of NAC in children with non-APAP ALF in a placebo-controlled clinical trial [2, 57]. In our study, we found that NAC was a secondary suspected or concomitant drug in most reports and a primary suspicious drug in one report where APAP was secondary. Therefore, as a disproportional signal, NAC is used to treat or prevent HAEs, especially APAP-induced HAEs. However, whether NAC has a negative effect on children with non-APAP ALF is unclear.
We also found an association between temazepam use and pediatric liver injury (ROR, 2.4; 95%CI, 1.2–4.7). No hepatotoxic risk is indicated in the prescribing information, and there is a lack of evidence to ensure the effectiveness and safety of temazepam among children. Temazepam is a benzodiazepine, and it is uncommon to observe elevated hepatic enzymes with benzodiazepine used and to report hepatoxic cases in practice. However, it has been reported that benzodiazepines (alprazolam, chlordiazepoxide, clonazepam, diazepam, flurazepam, and triazolam) are associated with rare cholestatic liver injuries [58, 59]. We have not retrieved any literature directly reporting temazepam-induced liver injury and postulated that this is due to its lower frequency of medication and shorter duration[2]. In addition, there is a possibility that cross-sensitivity to temazepam might occur with other benzodiazepines [58].
In our study, nefopam was disproportionally associated with liver injury in children (ROR, 18.7; 95%CI, 5.7–61.3]). It is unclear whether nefopam is effective and safe for children as a painkiller. In this study, we identified five nefopam-related pediatric hepatotoxic AEs. Four patients reported nefopam as a secondary suspected drug, and one reported nefopam as a concomitant drug. The primary suspected drugs in these reports were ketoprofen, esomeprazole, and pregabalin, all of which have adverse effects on the liver, as specified in the package inserts. Whether it is safe to use nefopam alone in children merits attention in clinical practice.
In this study, thiopental was detected as a disproportional signal (ROR, 3.5; 95%CI, 2.0–5.9). Thiopental is an intravenous anesthetic without hepatotoxic information provided in the inserts. In our findings, most reports of HAEs in children associated with thiopental recorded it as a concomitant drug, and the suspected drugs were mainly propofol, lamotrigine, phenytoin, propranolol, valproic acid, carbamazepine, lacosamide, and clonazepam, all of which have hepatotoxicity labeled in their package inserts. The risk of hepatotoxicity associated with this drug in children when applied alone is unclear. Bedir et al. indicated that oxidative stress and inflammation develop in the liver tissue of rats injected with thiopental alone, but further clinical studies are needed to explore this effect in humans [60].
Pyrimethamine was also detected as a disproportional signal (ROR, 3.5; 95%CI, 1.2–9.9). Four reports of pyrimethamine-associated hepatic injury in children have been identified. One patient recorded pyrimethamine as the primary suspected drug and sulfadiazine as the secondary drug, of which liver injury was a definite adverse effect. In the other three reports, the primary suspected drugs associated with liver injury were clindamycin, calcium folinate, and isotretinoin, all of which were reported to have a risk of hepatotoxicity. Pyrimethamine is typically combined with sulfonamides in practice. Many case reports of liver injury, such as granulomatous hepatitis, hypersensitivity to liver injury, and fatal hepatic necrosis, were determined to be induced by pyrimethamine-sulfadoxine [61–63]. Whether pyrimethamine alone can cause liver injury requires further investigation.
We found that primaquine is associated with pediatric HAEs (ROR, 14.0; 95%CI, 4.6–42.9). Among the five liver injury records associated with primaquine, one reported primaquine as the primary suspected drug, and four reported primaquine as a secondary suspected or concomitant drug, with chloroquine, tocilizumab, and malarone as the primary suspected drugs, all of which are toxic to the liver. The safety of primaquine when applied alone in children is not clear, as current studies have only presented an elevation of biochemical indicators of the liver when primaquine is used with chloroquine [64, 65].
Owing to their immature metabolic function, children are susceptible to liver injury. However, the limited sample size, unclear metabolic processes, and complicated ethical issues in children prevent pediatric studies on drug hepatotoxicity from further development and leave many gaps in this area. In this study, we analyzed pediatric HAEs based on a large sample size (~ 14,000 cases), spanning a long period (2004–2020) and incorporating advanced statistical tools and methods, and explored suspected drug–hepatotoxicity associations. Based on this, we recommend caution with the clinical administration of medication to children while providing a clue for future research in this vital area. However, there are several limitations owing to the features of FAERS itself. First, owing to the lack of compulsory requirements to assess causality when submitting reports to FAERS, some clinical data are missing, such as biochemical tests, liver biopsy data, drug doses, and exposure times. Therefore, we could not perform a causality assessment between a drug and HAEs, as is usually performed in a clinical case. Further, all of these findings represent a putative association detected using recommended pharmacovigilant methods to find disproportional signals, which requires caution when applying them to practice and are worth testing in either preclinical or clinical studies. Second, because of the various clinical manifestations of DILI, from elevated hepatic enzymes without symptoms to severe ALF, and passive surveillance with FAERS, HAEs in children could be under-reported. For example, potential hepatotoxic drugs might be ignored when the incidence of liver injury is low, clinical manifestations are not obvious, or they are concomitantly used with common hepatotoxic drugs. Third, caution should be exercised when extrapolating the findings to Asian populations given that the reports are mostly from Europe and North America.