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Article

Fact-Finding Survey and Exploration of Preventive Drugs for Antineoplastic Drug-Induced Oral Mucositis Using the Japanese Adverse Drug Event Report Database

1
Department of Practical Pharmacy, Faculty of Pharmaceutical Sciences, Toho University, Chiba 274-8510, Japan
2
Clinical Development Department, Daiichi Sankyo Co., Ltd., Tokyo 140-8710, Japan
*
Author to whom correspondence should be addressed.
Sci. Pharm. 2024, 92(2), 34; https://doi.org/10.3390/scipharm92020034
Submission received: 21 March 2024 / Revised: 18 May 2024 / Accepted: 11 June 2024 / Published: 20 June 2024

Abstract

:
Oral mucositis (OM) is one of the most common adverse events associated with antineoplastic drug treatment. Studies on the risk of antineoplastic drug-induced OM and its prevention are limited. We, therefore, conducted a disproportionality analysis of antineoplastic drug-induced OM and explored candidate preventive drugs for OM using the Japanese Adverse Drug Event Report (JADER) database. The JADER database showed that between April 2004 and March 2022, antineoplastic drug-related adverse events were reported in 210,822 cases, of which 2922 were OM. Forty-two drugs appeared to be associated with OM. The weibull distribution showed different patterns of time-to-onset depending on the type of antineoplastic drug administered. Cluster analyses classified antineoplastic drugs according to the typical symptoms of OM. These findings suggest that antineoplastic drug-induced OM should be monitored based on expression patterns of symptoms. Upon analyzing the inverse association, several concomitant drugs, including lenalidomide hydrate and febuxostat, were expected to be candidate preventive drugs for antineoplastic drug-induced OM. Concomitant drugs that showed an inverse association with antineoplastic drug-induced OM differed within the Anatomical Therapeutic Chemical classification. These findings could serve as a reference when considering drugs that should be prioritized to validate their prophylactic effect against antineoplastic-induced OM in the future.

1. Introduction

Oral mucositis (OM) is an inflammatory disease of the oral cavity mucosa and is one of the most common adverse events (AEs) associated with antineoplastic drugs [1,2,3]. It affects the quality of life of patients and their ability to tolerate treatment. The main symptoms of OM include oral pain, hemorrhage, dryness, redness, swelling of the oral mucosa, restricted mouth opening, dysarthria, dysphagia, and taste disorders, which cause extreme pain interfering with oral ingestion in severe cases. The frequency of antineoplastic drug-induced OM varies according to the type of drug administered. For example, a frequency of 65% has been documented with alkylating drugs (e.g., cyclophosphamide), plant alkaloids and other natural products (e.g., docetaxel), cytotoxic antibiotics and related substances (e.g., doxorubicin) [4]; 14–35% with antimetabolites (e.g., fluorouracil) [4]; 67% with everolimus [5]; 5–33% with sorafenib [6]; 40.5% with bevacizumab [7]; and approximately 40% with platinum drugs [4]. Chemotherapy-induced OM generally occurs 3–4 days after administration, peaks approximately 2 weeks after administration, and improves almost 3 weeks after administration [8,9]. The onset of OM induced by protein kinase inhibitors and other molecularly targeted drugs varies; however, with everolimus and other mTOR inhibitors, OM occurs several days after administration, with a median time to onset of approximately 10 days, improving in approximately 1 week [10]. These results suggest that antineoplastic drug-induced OM should be monitored based on the expression pattern of symptoms. The primary sources of information for managing OM are package inserts of prescription drugs and clinical trials [11]. However, recent reports [12,13] have primarily included only certain antineoplastic drugs or investigated these based on meta-analyses [14]; thus, comprehensive reporting on OM induced by all antineoplastic drugs is lacking.
Effective drugs to prevent drug-induced OM are yet to be developed. In Japan, sodium gualenate hydrate, sodium bicarbonate, and other drugs are recommended by the Ministry of Health, Labor, and Welfare for prophylaxis against OM [15], but these do not include specialized drugs that can specifically prevent OM. Recent studies have reported potential preventive drugs against antineoplastic drug-induced OM. In a meta-analysis of 10,514 randomized subjects in 131 trials, aloe vera, amifostine, cryotherapy, granulocyte-colony stimulating factor, intravenous glutamine, honey, keratinocyte growth factor, laser, polymyxin/tobramycin/amphotericin antibiotic pastille/paste, and sucralfate provided significant prevention against OM [11]. There is also reported that composed herbal extract, applied in the form of a mouthwash and in the form for topical application with benzocaine content showed remission of oral mucositis [16]. In a multicenter, single-arm phase II study (SWISH study) of patients with breast cancer who received everolimus and exemestane, a dexamethasone mouthwash reduced the incidence of grade 2 or higher OM [12]. However, this evidence is based on limited interventions with specific antineoplastic drugs and is not universally applicable to all antineoplastic drugs. The number of reports regarding OM induced by new types of antineoplastic drugs, such as molecular targeted drugs and immune checkpoint inhibitors, has also increased [17,18,19]. Therefore, there is a growing need to develop drugs capable of preventing OM.
Currently, studies using pharmacovigilance databases are underway worldwide. These studies evaluate the association between drugs and AEs, identify the time from the onset of AE, and investigate drug repositioning [20]. The Japanese Adverse Drug Event Report (JADER) published by the Pharmaceuticals and Medical Devices Agency (PMDA) has been used to investigate the relationship between drugs and AEs [21,22].
For successful antineoplastic drug therapy, evaluating the risk of OM for each antineoplastic drug and identifying preventive drugs is crucial. In the current study, we aimed to measure the disproportionality of antineoplastic drug-induced OM and analyze the expression pattern of OM. The results suggest that antineoplastic drug-induced OM should be monitored based on the expression pattern of symptoms. These findings will provide useful reference information for the management of OM. We also explored candidate preventive drugs against OM using the JADER database. The result showed that several concomitant drugs, including lenalidomide hydrate and febuxostat, are potential candidates for antineoplastic-induced OM prevention. The findings serve as a reference when considering drugs that should be prioritized to validate their prophylactic effect against OM in patients treated with antineoplastic drugs.

2. Materials and Methods

2.1. Data Sources

JADER is the Adverse Drug Reaction Database provided by the PMDA, documenting case reports of adverse drug reactions. Adverse drug reaction reports, which can be downloaded and used freely, are updated monthly and published on the PMDA website (http://www.pmda.go.jp/; accessed on 15 July 2022). JADER data are divided into four tables: demographic information pertaining to the patient, sex, age, and reporting year (demo); drug information, including prescribed drug, dosage, route, the reason for use, and start and end dates of administration (drug); AE, including the type of AE, outcome, and date of onset (reac); and primary disease (hist). Each reported item could be associated with an identification number. Data was downloaded on 15 July 2022 and included data reported from April 2004 to March 2022. Drugs listed in the dataset table were classified into suspected, concomitant, or interacting drugs. Herein, we used all drug classifications to investigate the actual relevance of drugs and OM and to evaluate the inverse association between potentially preventive drugs and antineoplastic-induced OM. Overlapping drugs with the same case identification number (ID) were excluded from the analysis. In the “reac” table, the adverse drug reactions were registered based on the Preferred Terms of Medical Dictionary for Regulatory Activities/Japan version; MedDRA/J. OM-related AEs are listed in Supplementary Table S1 online. Data were extracted using MedDRA/J ver.25.1 (https://www.jmo.pmrj.jp/; accessed on 15 July 2022). Overlapping cases of OM with the same ID were excluded from the analysis.

2.2. Selection of Antineoplastic Drugs

We included antineoplastic drugs classified as antineoplastic drugs (L01) in the Anatomical Therapeutic Chemical (ATC) classification system (https://www.kegg.jp/brite/jp08303/A10BK02; accessed on 15 July 2022). From the following standardized MedDRA Querie (SMQ)s, we determined the antineoplastic indication using primary disease data [23]: malignancy-related conditions (SMQ 20000092), tumor markers (SMQ 20000094), malignant tumors including gastric, colorectal, lung, and hepatic cancers (SMQ 20000194), breast malignant tumors (SMQ 20000198), ovarian malignant tumors (SMQ 20000200), prostate malignant tumors (SMQ 20000202), skin malignant tumors (SMQ 20000204), uterine and fallopian tube malignant tumors (SMQ 20000206), and malignant lymphomas (SMQ 20000215).

2.3. Statistical Analysis

The reporting odds ratio (ROR) was calculated to evaluate the association between OM and antineoplastic drugs. The ROR was calculated using a two-by-two contingency table (Supplementary Figure S1 online), which is widely used as a signal indicator in the Adverse Drug Reaction Database [24]. The two-by-two contingency table cannot be calculated with zero cells, and the estimation becomes unstable when the cell frequency is small. Therefore, to correct this bias, 0.5 was added to all cells (Haldane-Anscombe 1/2 correction) [25,26]. In the current study, we determined the association between antineoplastic drugs and OM when the ROR showed a lower limit of 95% confidence interval (CI) > 1 and a p-value < 0.05, as determined by Fisher’s exact test [24]. We also created a volcano plot using the natural logarithm of the ROR (ln ROR) and the normal logarithm of the p-value (−log[p]) to visually evaluate the association between OM and antineoplastic drugs [23,27].
For the time to onset analysis, distinct from the other analysis, we extracted the “suspected drug” from the “drug” table. The start date of administration was defined as the date of the first administration before the onset of OM. The number of days until the appearance of OM was calculated as follows: [(onset date)−(start date of administration)] plus 1 day. If the number of days to the onset was greater than 365, it was calculated as 365 days. Additionally, the pattern of onset time was classified using the shape parameter β of the Weibull distribution. Weibull parameters were used for the time-to-onset analysis to investigate the time-course hazards of AEs. When β is equal to 1 (random failure type), the hazard is estimated to remain constant over time. When β < 1 and the 95% CI of β excluded the value 1 (early failure type), the hazard is estimated to decrease over time. When β > 1 and the 95% CI of β excluded the value of 1 (wear-out failure type), the hazard is estimated to increase over time [28].
Hierarchical cluster analyses were performed to classify OM-related AEs induced by antineoplastic drugs. We examined 42 antineoplastic drugs with OM and 11 OM-related AEs with ≥10 cases reported. OM-related AEs with <10 cases were excluded for the cluster analysis. We calculated the ROR from two contingency tables for 11 AEs and 42 drugs. We then created a dendrogram based on the presence or absence of disproportionality and evaluated the distribution of drugs that showed disproportionality to each AE using the Ward method with Euclidean distance [29].
Among drugs administered concomitantly with antineoplastic drugs, we examined those with total reports of ≥100 AEs. The ROR and p-values were calculated for each drug using Fisher’s exact test to establish a volcano plot. Herein, we defined an inverse association between concomitant drugs and antineoplastic-induced OM when the ROR showed an upper limit of 95% CI < 1 and a p-value < 0.05, according to Fisher’s exact test [24].
All statistical analyses were performed using JMP Pro17 software (SAS Institute Inc., Cary, NC, USA).

3. Results

The total number of cases registered in JADER between April 2004 and March 2022 was 775,555. In total, 210,822 cases involved antineoplastic drug-induced AEs, of which 2922 were OM (Figure 1).
The characteristics of the patients treated with antineoplastic drugs are shown in Supplementary Table S2 (online). The sex distribution was as follows: 40.3% were females, 54.6% were males, and 5.1% were unknown. Regarding age, 29.1%, of patients were 70–79 years of age, and 28.0% were 60–69 years of age. According to the ATC classification, monoclonal antibodies and antibody-drug conjugates (L01F) were the most prevalent (36.3%). Among the patients with OM, 47.1% were females, 49.9% were males, and 3.1% were others or unknown. Regarding age, 29.1% of patients were 60–69 years of age, and 28.9% were 70–79 years of age. According to the ATC classification, antimetabolites (L01B) were the most prevalent (51.2%).
The number of cases and ROR for antineoplastic drug-induced OM are shown in Table 1. Figure 2 presents a volcano plot of the association between OM and antineoplastic drugs. As shown in Table 1 and Figure 2, 42 drugs were associated with OM. The most frequently reported drugs with OM were tegafur/gimeracil/oteracil potassium (523 reports; 17.9%), fluorouracil (333 reports; 11.4%), cisplatin (305 reports; 10.4%), everolimus (264 reports; 9.0%), capecitabine (222 reports; 7.6%), and oxaliplatin (209 reports; 7.2%).
Among the 42 antineoplastic drugs associated with OM, 39 drugs with two or more usable data points for both the starting date of administration and the onset date of AEs were included in the time-to-onset analysis. Figure 3 presents box plots of the time to onset. Table 2 shows the median time to onset and pattern of OM classified using the Weibull distribution. The median time to OM onset ranged from approximately 7.0 days to 23.0 days. Considering the Weibull distribution, tegafur/gimeracil/oteracil potassium, fluorouracil, capecitabine, methotrexate, tegafur and uracil, pralatrexate, irinotecan, erlotinib, bevacizumab, trastuzumab, cisplatin, and eribulin were estimated to be early failures. Melphalan, thiotepa, ranimustine, dactinomycin, palbociclib, and avelumab were considered wear-out failures.
Figure 4 presents the hierarchical cluster analyses classifying antineoplastic drugs based on the presence or absence of disproportionality of OM-related AEs. Based on the dendrogram, the clusters were divided into four types. Association with stomatitis was observed in all clusters. The first cluster included fluorouracil and other drugs, and the second cluster included docetaxel and other drugs. Among alkylating agents, cyclophosphamide was included in the first cluster, and other agents were included in the second cluster. All drugs classified as cytotoxic antibiotics and related substances were included in the third cluster. These clusters showed association with pharyngeal ulceration and mouth ulceration. The fourth cluster mainly included protein kinase inhibitors (e.g., afatinib). These clusters were associated with lip erosion, stomatitis, hemorrhagic, and glossitis.
Treatment with concomitantly administered drugs showing an inverse association with antineoplastic-induced OM are summarized in Table 3. Twelve drug combination treatments showed inverse associations with all antineoplastic drug-induced OM. Figure 5a presents a volcano plot of the association between concomitantly administered drugs and antineoplastic drug-induced OM. Dexamethasone, prednisolone, methylprednisolone, sulfamethoxazole/trimethoprim, voriconazole, febuxostat, and lenalidomide hydrate exhibited inverse associations. However, drugs such as sodium gualenate hydrate, which is used to prevent or treat OM, did not display an inverse association with OM. Figure 5b–h present volcano plots showing the associations between concomitant medications and antineoplastic-induced OM by ATC classification. Lenalidomide hydrate showed an inverse association with OM induced by monoclonal antibodies, antibody-drug conjugates, and other antineoplastic drugs. Febuxostat showed an inverse association with OM induced by antimetabolites and other antineoplastic drugs. Dexamethasone showed an inverse association with OM induced by other antineoplastic drugs, and prednisolone showed an inverse association with OM induced by alkylating drugs, plant alkaloids, and other natural products, and cytotoxic antibiotics and related substances.

4. Discussion

In the present study, 42 drugs were associated with OM. All the 42 drugs associated with OM has been reported that they are likely to cause OM in the package inserts of prescription drugs or textbook. The most frequently reported drugs associated with OM were tegafur/gimeracil/oteracil potassium, fluorouracil, cisplatin, everolimus, capecitabine, and oxaliplatin. These drugs are known to have a high incidence of OM in previous clinical trials [4,30,31,32]; hence, these antineoplastic drugs may have a high potential to induce OM. Cytotoxic antineoplastic drugs, such as alkylating drugs and antimetabolites, inhibit the growth of actively dividing cells with abundant blood flow [33]. Cells in the oral mucosa are believed to be susceptible to the cytotoxic effects of antineoplastic drugs because they are actively dividing. Molecularly targeted drugs, such as protein kinase inhibitors, are likely to have a lower incidence of OM than cytotoxic anticancer drugs, as they act only on specific target molecules in cancer cells [34]; however, everolimus and other mTOR inhibitors, which act on tumor growth, are associated with a higher incidence of OM than other molecularly targeted drugs [10].
In the present study, the median time to onset ranged from approximately 7.0 days to 23.0 days. This finding is consistent with that of previous studies, which showed that antineoplastic drug-induced OM occurs between a few days and 2–3 weeks after administration [35]. The Weibull distribution suggested that OM expression patterns may differ for each type of antineoplastic drug. Early failure was estimated for antimetabolites (e.g., tegafur/gimeracil/oteracil potassium), monoclonal antibodies, and antibody-drug conjugates (e.g., bevacizumab). Wear-out failure was estimated for alkylating drugs (e.g., melphalan). Antineoplastic drug-induced OM is caused via direct effects, such as destruction of the oral mucosa, inflammation, and secondary infections in the oral cavity associated with bone marrow suppression, including leukopenia. OM caused by secondary infections develops later than that caused by the direct action of antineoplastic drugs [36]. These findings explain why more than one drug exhibited wear-out failure among the alkylating drugs in this study. The Weibull distribution could be valuable in establishing the specific safety monitoring period for AEs based on expression patterns of OM. Therefore, OM attributed to antineoplastic drugs that exhibit wear-out failure of use may require longer-term monitoring than other antineoplastic drugs. However, the use of avelumab should be carefully considered owing to the lack of data (n = 2).
Hierarchical cluster analysis classified antineoplastic drugs into four clusters based on the presence or absence of disproportionality of OM-related AEs. Stomatitis was associated with all clusters; therefore, it was expected to be associated with all antineoplastic drugs. The third cluster, which included all drugs classified as cytotoxic antibiotics and related substances, was associated with pharyngeal ulceration and mouth ulceration; this cluster also included dactinomycin, everolimus, and methotrexate. These drugs are known to be associated with mouth ulceration [6,37,38]. Therefore, the risk of mouth ulceration with these drugs needs to be carefully considered. The fourth cluster, which included protein kinase inhibitors such as afatinib, lapatinib, and dacomitinib, was associated with lip erosion, hemorrhagic stomatitis, and glossitis. The incidence of lip erosion and glossitis was less than 10% or unknown on the package inserts of these drugs. However, molecularly targeted drugs, such as protein kinase inhibitors, are known to induce aphthous OM, and aphthous OM localized in non-excursion and keratinized mucosal areas are typical because these areas can be difficult to stimulate physically [19,39]. Further investigations are needed to evaluate the correlation between protein kinase inhibitors and these AEs.
Twelve of the concomitantly administered drugs were inversely associated with antineoplastic drug-induced OM by all antineoplastic drugs. In clinical trials, dexamethasone [12], prednisolone [40], and methylprednisolone [41] were shown to prevent OM. Lenalidomide hydrate, a thalidomide analog, improves aphthous OM [42]. Considering other drugs, evidence from clinical trials is lacking; however, febuxostat was found to exert antioxidant and anti-inflammatory effects [43,44,45]. In a study using a rat model, pretreatment with febuxostat reduced parotid salivary gland injury induced by 5-fluorouracil through potent antioxidant effects and inhibition of interleukin (IL)-1β and tumor necrosis factor (TNF)-α activity [46]. Cytotoxic drugs directly inhibit DNA synthesis and cellular biochemical metabolic pathways, leading to the production of inflammatory cytokines such as reactive oxygen species and TNF-α, tissue damage in the oral mucosa, and induction of apoptosis [47]. These findings indicate that febuxostat might reduce OM by exerting antioxidant effects and inhibiting IL-1β and TNF-α. Moreover, antineoplastic-induced OM can occur via secondary infection due to bone marrow suppression. Sulfamethoxazole/trimethoprim [48] and voriconazole [49] exert preventive effects against infections; hence, these drugs may prevent secondary OM induced by antineoplastic drugs. In Japan, sodium gualenate hydrate is recommended as a prophylactic drug for OM [15]. However, in the current study, a combination of the drugs showed an association with OM, which could be attributed to the fact that these drugs were used for patients at high risk of OM, and the number of cases was higher than expected. Furthermore, some other drugs that lacked an inverse association with OM were found to afford notable preventative effects against OM [11]. Hence, drugs that did not exhibit disproportionality could be candidates for OM prevention. Herein, concomitantly administered drugs displaying an inverse association with antineoplastic drug-induced mucositis differed within the ATC classification. Accordingly, it is important to determine the prophylactic effect against antineoplastic-induced OM by drug or ATC classification. Recently, the pathobiology of mucositis has been explored, and potential druggable targets that inhibit mucositis have been identified [50]. Our findings on drugs that showed an inverse association with OM could provide insights for further basic research elucidating the mechanisms of action leading to drug repositioning. The findings of this study could serve as a guide when considering drugs that should be prioritized when validating their prophylactic effect against antineoplastic-induced OM.
This study had several limitations. First, because the JADER database is a spontaneous reporting database, it lacks denominator information, and the frequency of AEs cannot be calculated. Second, in studies that utilize spontaneous reporting databases for adverse drug reactions, such as JADER, mild and well-known adverse reactions are less likely to be reported, and severe adverse reactions are more frequently reported, which may result in reporting biases [51]. Third, the data retrieved from the JADER database included inadequate information, such as blank data and the start date of administration; therefore, these data were excluded from the analysis. Fourth, for recently launched drugs, the number of cases is limited but occasionally higher than expected owing to aggressive reporting, a phenomenon known as the Weber effect [52]. Fifth, it was not possible to eliminate the impact of concomitantly administered medications on our evaluation [53,54]. Reportedly, concomitant therapy of antineoplastic drugs is associated with a higher incidence of OM than monotherapy [1,55]. In the current study, we did not investigate the incidence of OM by monotherapy and combination regimens. Therefore, the signal indicators observed in the current study must be interpreted carefully, considering the effects of concomitant use. Sixth, spontaneous reports may lack information on concomitant medications, especially in terms of common AEs [56]. Moreover, AEs will decrease if appropriate medical care is afforded in clinical settings, which may provide signals that oppose the pharmacological basis [57]. This may affect the signals detected with and without concomitant medication. Finally, only the JADER database was used in this study. AEs reported in the JADER and FDA Adverse Event Reporting System FAERS databases are known to differ [58]. Therefore, we hope that the gaps caused by these limitations will be addressed in future research using other methods, such as a combination of database-based studies of patients with certain adverse reactions.

5. Conclusions

We investigated the disproportionality of OM caused by antineoplastic drugs using the JADER database and potential concomitant drug treatment to prevent OM. In total, 42 drugs were associated with OM. The Weibull distribution showed a distinctive time-to-onset pattern depending on the type of antineoplastic drug administered, which could be valuable in monitoring OM. Cluster analyses classified antineoplastic drugs according to the typical symptoms of OM. These findings suggest that antineoplastic drug-induced OM should be monitored based on expression patterns. Considering the inverse association analysis, several concomitant drugs were expected to be the candidate drugs for preventing antineoplastic drug-induced OM. Additional investigations are required to validate the preventive mechanisms and clinical evaluation of OM.

Supplementary Materials

The following supporting information can be downloaded at https://www.mdpi.com/article/10.3390/scipharm92020034/s1, Figure S1: Two-by-two contingency table for calculating the reporting odds ratio and 95% confidence interval of oral mucositis; Table S1: Definition of oral mucositis; Table S2: Characteristics of antineoplastic drugs-treated case population.

Author Contributions

Conceptualization, H.M. and H.T.; methodology, H.M. and H.T.; software, H.M.; validation, H.T., T.O. and H.M.; formal analysis, K.E. and H.M.; investigation, H.M.; resources, K.E. and H.M.; data curation, H.M; writing—original draft preparation, H.M.; writing—review and editing, H.T., T.O. and T.I.; visualization, H.M.; supervision, H.T. and H.M.; project administration, H.T. and H.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

This was a database-related observational study with no direct access to any research subjects; thus, no ethical approval was sought. All results in this study were obtained from data from the JADER database. All data from JADER were fully anonymized by the relevant regulatory authorities prior to access.

Informed Consent Statement

Not applicable.

Data Availability Statement

The datasets generated and/or analyzed in the current study are available in the JADER database. (https://www.pmda.go.jp/safety/info-services/drugs/adr-info/suspected-adr/0004.html; accessed on 15 July 2022).

Conflicts of Interest

Hajime Matsuo is an employee in Daiichi Sankyo Co., Ltd. (Tokyo, Japan) and has received personal fees from it. Daiichi Sankyo Co., Ltd. had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

References

  1. Sonis, S.T.; Elting, L.S.; Keefe, D.; Peterson, D.E.; Schubert, M.; Hauer-Jensen, M.; Bekele, B.N.; Raber-Durlacher, J.; Donnelly, J.P.; Rubenstein, E.B.; et al. Perspectives on cancer therapy-induced mucosal injury: Pathogenesis, measurement, epidemiology, and consequences for patients. Cancer 2004, 100, 1995–2025. [Google Scholar] [CrossRef]
  2. Elting, L.; Cooksley, C.; Chambers, M.; Cantor, S.; Manzullo, E.; Rubenstein, E. The burdens of cancer therapy: Clinical and economic outcomes of chemotherapy-induced mucositis. Cancer 2003, 98, 1531–1539. [Google Scholar] [CrossRef]
  3. Krishna, S.G.; Zhao, W.; Grazziutti, M.L.; Sanathkumar, N.; Barlogie, B.; Anaissie, E.J. Incidence and risk factors for lower alimentary tract mucositis after 1529 courses of chemotherapy in a homogenous population of oncology patients: Clinical and research implications. Cancer 2011, 117, 648–655. [Google Scholar] [CrossRef]
  4. Jones, J.A.; Avritscher, E.B.; Cooksley, C.D.; Michelet, M.; Bekele, B.N.; Elting, L.S. Epidemiology of treatment-associated mucosal injury after treatment with newer regimens for lymphoma, breast, lung, or colorectal cancer. Support. Care Cancer 2006, 14, 505–515. [Google Scholar] [CrossRef]
  5. Rugo, H.S.; Hortobagyi, G.N.; Yao, J.; Pavel, M.; Ravaud, A.; Franz, D.; Ringeisen, F.; Gallo, J.; Rouyrre, N.; Anak, O.; et al. Meta-analysis of stomatitis in clinical studies of everolimus: Incidence and relationship with efficacy. Ann. Oncol. 2016, 27, 519–525. [Google Scholar] [CrossRef]
  6. Abdel-Rahman, O.; Fouad, M. Risk of mucocutaneous toxicities in patients with solid tumors treated with sorafenib: An updated systematic review and meta-analysis. Expert Rev. Anticancer Ther. 2014, 14, 751–760. [Google Scholar] [CrossRef]
  7. Watanabe, J.; Muro, K.; Shitara, K.; Yamazaki, K.; Shiozawa, M.; Ohori, H.; Takashima, A.; Yokota, M.; Makiyama, A.; Akazawa, N.; et al. Panitumumab vs bevacizumab added to standard first-line chemotherapy and overall survival among patients with RAS wild-type, left-sided metastatic colorectal cancer: A randomized clinical trial. JAMA 2023, 329, 1271–1282. [Google Scholar] [CrossRef]
  8. Sonis, S.T. Mucositis: The impact, biology and therapeutic opportunities of oral mucositis. Oral Oncol. 2009, 45, 1015–1020. [Google Scholar] [CrossRef]
  9. Cinausero, M.; Aprile, G.; Ermacora, P.; Basile, D.; Vitale, M.G.; Fanotto, V.; Parisi, G.; Calvetti, L.; Sonis, S.T. New frontiers in the pathobiology and treatment of cancer regimen-related mucosal injury. Front. Pharmacol. 2017, 8, 354. [Google Scholar] [CrossRef]
  10. Martins, F.; de Oliveira, M.A.; Wang, Q.; Sonis, S.; Gallottini, M.; George, S.; Treister, N. A review of oral toxicity associated with mTOR inhibitor therapy in cancer patients. Oral Oncol. 2013, 49, 293–298. [Google Scholar] [CrossRef]
  11. Worthington, H.V.; Clarkson, J.E.; Bryan, G.; Furness, S.; Glenny, A.M.; Littlewood, A.; McCabe, M.G.; Meyer, S.; Khalid, T. Interventions for preventing oral mucositis for patients with cancer receiving treatment. Cochrane Database Syst. Rev. 2011, 13, CD000978. [Google Scholar]
  12. Rugo, H.S.; Seneviratne, L.; Beck, J.T.; Glaspy, J.A.; Peguero, J.A.; Pluard, T.J.; Dhillon, N.; Hwang, L.C.; Nangia, C.; Mayer, I.A.; et al. Prevention of everolimus-related stomatitis in women with hormone receptor-positive, HER2-negative metastatic breast cancer using dexamethasone mouthwash (SWISH): A single-arm, phase 2 trial. Lancet Oncol. 2017, 18, 654–662. [Google Scholar] [CrossRef]
  13. Niikura, N.; Nakatukasa, K.; Amemiya, T.; Watanabe, K.; Hata, H.; Kikawa, Y.; Taniike, N.; Yamanaka, T.; Mitsunaga, S.; Nakagami, K.; et al. Oral Care Evaluation to Prevent Oral Mucositis in Estrogen Receptor-Positive Metastatic Breast Cancer Patients Treated with Everolimus (Oral Care-BC): A Randomized Controlled Phase III Trial. Oncologist 2020, 25, e223–e230. [Google Scholar] [CrossRef] [PubMed]
  14. Stokman, M.A.; Spijkervet, F.K.; Boezen, H.M.; Schouten, J.P.; Roodenburg, J.L.; deVries, E.G. Preventive intervention possibilities in radiotherapy- and chemotherapy-induced oral mucositis: Results of meta-analyses. J. Dent. Res. 2006, 85, 690–700. [Google Scholar] [CrossRef]
  15. Ministry of Health, Labour and Welfare. Oral Mucositis by Anticancer Drugs in Manuals for Treatment of Serious Adverse Drug Reactions, 2009 (Revised in April 2023). Available online: https://www.mhlw.go.jp/topics/2006/11/dl/tp1122-1l09-r05.pdf (accessed on 30 April 2023).
  16. Schönknecht, K.; Surdacka, A.; Rudenko, L. Effectiveness of composed herbal extract in the treatment of gingivitis and oral and pharyngeal mucosa—Review of studies. Wiad. Lek. 2021, 74, 1737–1749. [Google Scholar] [CrossRef]
  17. Singer, S.; Tan, S.Y.; Dewan, A.K.; Davids, M.; LaCasce, A.S.; Treon, S.P.; LeBoeuf, N.R. Cutaneous eruptions from ibrutinib resembling epidermal growth factor receptor inhibitor-induced dermatologic adverse events. J. Am. Acad. Dermatol. 2023, 88, 1271–1281. [Google Scholar] [CrossRef]
  18. Yuan, A.; Kurtz, S.L.; Barysauskas, C.M.; Pilotte, A.P.; Wagner, A.J.; Treister, N.S. Oral adverse events in cancer patients treated with VEGFR-directed multitargeted tyrosine kinase inhibitors. Oral Oncol. 2015, 51, 1026–1033. [Google Scholar] [CrossRef] [PubMed]
  19. Vigarios, E.; Epstein, J.B.; Sibaud, V. Oral mucosal changes induced by anticancer targeted therapies and immune checkpoint inhibitors. Support. Care Cancer 2017, 25, 1713–1739. [Google Scholar] [CrossRef]
  20. Kiryu, Y. Potential for big data analysis using AI in the field of clinical pharmacy. Yakugaku Zasshi 2021, 141, 179–185. [Google Scholar] [CrossRef]
  21. Hosomi, K.; Fujimoto, M.; Ushio, K.; Mao, L.; Kato, J.; Takada, M. An integrative approach using real-world data to identify alternative therapeutic uses of existing drugs. PLoS ONE 2018, 13, e0204648. [Google Scholar] [CrossRef]
  22. Imai, T.; Hazama, K.; Kosuge, Y.; Suzuki, S.; Ootsuka, S. Preventive effect of rebamipide on NSAID-induced lower gastrointestinal tract injury using FAERS and JADER. Sci. Rep. 2022, 12, 2631. [Google Scholar] [CrossRef] [PubMed]
  23. Sugawara, H.; Uchida, M.; Suzuki, S.; Suga, Y.; Uesawa, Y.; Nakagawa, T.; Takase, H. Analyses of respiratory depression associated with opioids in cancer patients based on the Japanese adverse drug event report database. Biol. Pharm. Bull. 2019, 42, 1185–1191. [Google Scholar] [CrossRef]
  24. Van Puijenbroek, E.P.; Bate, A.; Leufkens, H.G.; Lindquist, M.; Orre, R.; Egberts, A.C. A comparison of measures of disproportionality for signal detection in spontaneous reporting systems for adverse drug reactions. Pharmacoepidemiol. Drug Saf. 2002, 11, 3–10. [Google Scholar] [CrossRef] [PubMed]
  25. Watanabe, H.; Matsushita, Y.; Watanabe, A.; Maeda, T.; Nukui, K.; Ogawa, Y.; Sawa, J.; Maeda, H. Early detection of important safety information. Jpn. J. Biomet 2004, 25, 37–60. [Google Scholar] [CrossRef]
  26. Ohyama, K.; Sugiura, M. Evaluation of the association between topical prostaglandin F2α analogs and asthma using the JADER database: Comparison with β-blockers. Yakugaku Zasshi 2018, 138, 559–564. [Google Scholar] [CrossRef] [PubMed]
  27. Chen, J.J.; Wang, S.J.; Tsai, C.A.; Lin, C.J. Selection of differentially expressed genes in microarray data analysis. Pharmacogenomics J. 2007, 7, 212–220. [Google Scholar] [CrossRef] [PubMed]
  28. Leroy, F.; Dauxois, J.Y.; Théophile, H.; Haramburu, F.; Tubert-Bitter, P. Estimating time-to-onset of adverse drug reactions from spontaneous reporting databases. BMC Med. Res. Methodol. 2014, 14, 17. [Google Scholar] [CrossRef]
  29. Everitt, B.S.; Landau, S.; Leese, M.; Stahl, D. Cluster Analysis, 5th ed.; John Wiley & Sons: Hoboken, NJ, USA, 2011; ISBN 978-0-470-74991-3. [Google Scholar]
  30. Textbook for the National Cancer Medical and Dental Collaboration Seminar, Second Edition. Available online: https://ganjoho.jp/med_pro/cancer_control/medical_treatment/dental/koshukai_text2.html (accessed on 13 February 2023).
  31. Kinoshita, T.; Nashimoto, A.; Yamamura, Y.; Okamura, T.; Sasako, M.; Sakamoto, J.; Kojima, H.; Hiratsuka, M.; Arai, K.; Sairenji, M.; et al. Feasibility study of adjuvant chemotherapy with S-1 (TS-1; tegafur, gimeracil, oteracil potassium) for gastric cancer. Gastric Cancer 2004, 7, 104–109. [Google Scholar] [CrossRef] [PubMed]
  32. Wu, Z.; Zhang, X.; Zhang, C.; Lin, Y. Meta-Analysis of capecitabine versus 5-fluorouracil in Advanced Gastric Cancer. Evid. Based Complement. Alternat. Med. 2023, 2023, 4946642. [Google Scholar] [CrossRef]
  33. Weber, G.F. DNA Damaging drugs. Mol. Ther. Cancer 2014, 9–112. [Google Scholar] [CrossRef]
  34. Boers-Doets, C.B.; Epstein, J.B.; Raber-Durlacher, J.E.; Ouwerkerk, J.; Logan, R.M.; Brakenhoff, J.A.; Lacouture, M.E.; Gelderblom, H. Oral adverse events associated with tyrosine kinase and mammalian target of rapamycin inhibitors in renal cell carcinoma: A structured literature review. Oncologist 2012, 17, 135–144. [Google Scholar] [CrossRef] [PubMed]
  35. Pico, J.L.; Avila-Garavito, A.; Naccache, P. Mucositis: Its occurrence, consequences, and treatment in the oncology setting. Oncologist 1998, 3, 446–451. [Google Scholar] [CrossRef] [PubMed]
  36. Singh, V.; Singh, A.K. Oral mucositis. Natl J. Maxillofac. Surg. 2020, 11, 159–168. [Google Scholar] [CrossRef] [PubMed]
  37. Deeming, G.M.J.; Collingwood, J.; Pemberton, M.N. Methotrexate and oral ulceration. Br. Dent. J. 2005, 198, 83–85. [Google Scholar] [CrossRef] [PubMed]
  38. Limpongsanurak, S. Prophylactic actinomycin D for high-risk complete hydatidiform mole. J. Reprod. Med. 2001, 46, 110–116. [Google Scholar] [PubMed]
  39. Peterson, D.E.; O’Shaughnessy, J.A.; Rugo, H.S.; Elad, S.; Schubert, M.M.; Viet, C.T.; Campbell-Baird, C.; Hronek, J.; Seery, V.; Divers, J.; et al. Oral mucosal injury caused by mammalian target of rapamycin inhibitors: Emerging perspectives on pathobiology and impact on clinical practice. Cancer Med. 2016, 5, 1897–1907. [Google Scholar] [CrossRef]
  40. Jones, V.E.; McIntyre, K.J.; Paul, D.; Wilks, S.T.; Ondreyco, S.M.; Sedlacek, S.; Melnyk, A.; Oommen, S.P.; Wang, Y.; Peck, S.R.; et al. Evaluation of miracle mouthwash plus hydrocortisone versus prednisolone mouth rinses as prophylaxis for everolimus-associated stomatitis: A randomized Phase II study. Oncologist 2019, 24, 1153–1158. [Google Scholar] [CrossRef] [PubMed]
  41. Pascual, M.J.; Maldonado, J. Extramedullary toxicity in bone marrow transplantation using busulfan and cyclophosphamide conditioning. Sangre 1995, 40, 191–197. [Google Scholar] [PubMed]
  42. Ossorio-García, L.; Jiménez-Gallo, D.; de la Varga-Martínez, R.; Linares-Barrios, M. Lenalidomide for treatment of recurrent oral aphthae in Adamantiades-Behçet’s disease. J. Dtsch. Dermatol. Ges. 2018, 16, 1029–1031. [Google Scholar] [CrossRef]
  43. Sun, Y.; Birnbaumer, L.; Singh, B.B. TRPC1 regulates calcium-activated chloride channels in salivary gland cells. J. Cell. Physiol. 2015, 230, 2848–2856. [Google Scholar] [CrossRef]
  44. Mohamed, M.Z.; Baky, M.A.E.; Hassan, O.A.; Mohammed, H.H.; Abdel-Aziz, A.M. PTEN/PI3K/VEGF signaling pathway involved in the protective effect of xanthine oxidase inhibitor febuxostat against endometrial hyperplasia in rats. Hum. Exp. Toxicol. 2020, 39, 1224–1234. [Google Scholar] [CrossRef] [PubMed]
  45. Nessa, N.; Kobara, M.; Toba, H.; Adachi, T.; Yamamoto, T.; Kanamura, N.; Pezzotti, G.; Nakata, T. Febuxostat attenuates the progression of periodontitis in rats. Pharmacology 2021, 106, 294–304. [Google Scholar] [CrossRef] [PubMed]
  46. Abdelzaher, W.Y.; Nassan, M.A.; Ahmed, S.M.; Welson, N.N.; El-Saber Batiha, G.; Khalaf, H.M. Xanthine oxidase inhibitor, febuxostat is effective against 5-fluorouracil-induced parotid salivary gland injury in rats via inhibition of oxidative stress, inflammation and targeting TRPC1/CHOP signalling pathway. Pharmaceuticals 2022, 15, 232. [Google Scholar] [CrossRef] [PubMed]
  47. Arnhold, J. Host-Derived Cytotoxic Agents in Chronic Inflammation and Disease Progression. Int. J. Mol. Sci. 2023, 24, 3016. [Google Scholar] [CrossRef]
  48. Panchanadikar, N.; Balasubramanian, S.; Nirmal, L.; Haridoss, S.; Muthu, M.S. Management of oral mucosal lesions in salicylate sensitive Stevens-Johnson syndrome—A case report. Indian J. Dent. Res. 2021, 32, 537–540. [Google Scholar] [CrossRef] [PubMed]
  49. Link, H. Antimicrobial prophylaxis and therapy in neutropenia. Mycoses 2003, 46 (Suppl. S2), 21–32. [Google Scholar]
  50. Sonis, S.T. Treatment for oral mucositis—Current options and an update of small molecules under development. Curr. Treat. Options Oncol. 2021, 22, 25. [Google Scholar] [CrossRef]
  51. Sakai, T. Role and applicability of spontaneous reporting databases in medical big data. Yakugaku Zasshi 2021, 141, 165–168. [Google Scholar] [CrossRef] [PubMed]
  52. Weber, J. Epidemiology of adverse reactions to nonsteroidal anti-inflammatory drugs. Adv. Inflam. Res. 1984, 6, 1–7. [Google Scholar]
  53. Pariente, A.; Avillach, P.; Salvo, F.; Thiessard, F.; Miremont-Salamé, G.; Fourrier-Reglat, A.; Haramburu, F.; Bégaud, B.; Moore, N.; Association Française des Centres Régionaux de Pharmacovigilance (CRPV). Effect of competition bias in safety signal generation: Analysis of a research database of spontaneous reports in France. Drug Saf. 2012, 35, 855–864. [Google Scholar] [CrossRef]
  54. Avillach, P.; Salvo, F.; Thiessard, F.; Miremont-Salamé, G.; Fourrier-Reglat, A.; Haramburu, F.; Bégaud, B.; Moore, N.; Pariente, A.; l‘Association des Centres Régionaux de Pharmacovigilance. Pilot evaluation of an automated method to decrease false-positive signals induced by co-prescriptions in spontaneous reporting databases. Pharmacoepidemiol. Drug Saf. 2014, 23, 186–194. [Google Scholar] [CrossRef] [PubMed]
  55. Curra, M.; Gabriel, A.F.; Ferreira, M.B.C.; Martins, M.A.T.; Brunetto, A.T.; Gregianin, L.J.; Martins, M.D. Incidence and risk factors for oral mucositis in pediatric patients receiving chemotherapy. Support. Care Cancer 2021, 29, 6243–6251. [Google Scholar] [CrossRef] [PubMed]
  56. Urushihara, H. Basic dos and don’ts in applying signal detection methods to spontaneous reporting systems databases. Jpn. J. Drug Inform. 2020, 21, 135–141. [Google Scholar]
  57. Noguchi, Y.; Tachi, T.; Teramachi, H. Detection algorithms and attentive points of safety signal using spontaneous reporting systems as a clinical data source. Brief. Bioinform. 2021, 22, bbab347. [Google Scholar] [CrossRef]
  58. Nomura, K.; Takahashi, K.; Hinomura, Y.; Kawaguchi, G.; Matsushita, Y.; Marui, H.; Anzai, T.; Hashiguchi, M.; Mochizuki, M. Effect of database profile variation on drug safety assessment: An analysis of spontaneous adverse event reports of Japanese cases. Drug Des. Devel. Ther. 2015, 9, 3031–3041. [Google Scholar] [CrossRef]
Figure 1. Flowchart of case selection. JADER: Japanese Adverse Drug Event Report. ATC: Anatomical Therapeutic Chemical.
Figure 1. Flowchart of case selection. JADER: Japanese Adverse Drug Event Report. ATC: Anatomical Therapeutic Chemical.
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Figure 2. Antineoplastic drugs associated with oral mucositis-related adverse events. The X-axis shows the natural logarithm of the reported odds ratios (ln ROR), and the y-axis shows the common logarithm of the inverse p-value (−log (p-value)) from Fisher’s exact test. The dotted line on the y-axis represents p = 0.05. The plot colors represent the number of reports in the ATC category. Plot size indicates the total number of reports. As the RORs became more positive, the tendency toward AEs increased; decreasing p-values indicated greater statistical significance. The upper-right portion of the plot shows the antineoplastic drugs associated with oral mucositis-related AEs. AEs, adverse events; ROR, reporting odds ratio.
Figure 2. Antineoplastic drugs associated with oral mucositis-related adverse events. The X-axis shows the natural logarithm of the reported odds ratios (ln ROR), and the y-axis shows the common logarithm of the inverse p-value (−log (p-value)) from Fisher’s exact test. The dotted line on the y-axis represents p = 0.05. The plot colors represent the number of reports in the ATC category. Plot size indicates the total number of reports. As the RORs became more positive, the tendency toward AEs increased; decreasing p-values indicated greater statistical significance. The upper-right portion of the plot shows the antineoplastic drugs associated with oral mucositis-related AEs. AEs, adverse events; ROR, reporting odds ratio.
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Figure 3. Box plot for time-to-onset of antineoplastic drugs associated with oral mucositis. Box plots show the 25th and 75th percentiles and medians. The whiskers present the maximum and minimum values within 1.5 times the inner quartile point’s length. The values outside the box represent outliers. All data for which the number of days until the onset of oral mucositis exceeded 365 days were calculated as 365 days.
Figure 3. Box plot for time-to-onset of antineoplastic drugs associated with oral mucositis. Box plots show the 25th and 75th percentiles and medians. The whiskers present the maximum and minimum values within 1.5 times the inner quartile point’s length. The values outside the box represent outliers. All data for which the number of days until the onset of oral mucositis exceeded 365 days were calculated as 365 days.
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Figure 4. Classification of oral mucositis-related AEs by hierarchical cluster analysis. The dendrogram shows the relationships between 11 types of oral mucositis-related AEs. The dotted line indicates cluster separation. The color map shows the presence or absence of associated signals with AEs. Red implies “presence” and blue implies “absence”. AEs, adverse events.
Figure 4. Classification of oral mucositis-related AEs by hierarchical cluster analysis. The dendrogram shows the relationships between 11 types of oral mucositis-related AEs. The dotted line indicates cluster separation. The color map shows the presence or absence of associated signals with AEs. Red implies “presence” and blue implies “absence”. AEs, adverse events.
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Figure 5. Drugs associated with oral mucositis-related AEs when combined with antineoplastic drugs. Combination with (a) all antineoplastic drugs, (b) alkylating drugs, (c) antimetabolites, (d) with plant alkaloids and other natural products, (e) with cytotoxic antibiotics and related substances, (f) protein kinase inhibitors, (g) monoclonal antibodies and antibody-drug conjugates, and (h) other antineoplastic drugs. The X-axis shows the natural logarithm of the reporting odds ratios (ln ROR), and the y-axis shows the common logarithm of the inverse p-value (−log (p-value)) from Fisher’s exact test. The dotted line on the y-axis represents p = 0.05. The plot colors represent the total number of reports. As the RORs became more negative, the tendency toward AEs decreased, and decreasing p-values indicated greater statistical significance. The upper-left portion of the plot shows the concomitant drugs that are less frequently associated with oral mucositis-related AEs. AEs, adverse events; ROR, reporting odds ratio.
Figure 5. Drugs associated with oral mucositis-related AEs when combined with antineoplastic drugs. Combination with (a) all antineoplastic drugs, (b) alkylating drugs, (c) antimetabolites, (d) with plant alkaloids and other natural products, (e) with cytotoxic antibiotics and related substances, (f) protein kinase inhibitors, (g) monoclonal antibodies and antibody-drug conjugates, and (h) other antineoplastic drugs. The X-axis shows the natural logarithm of the reporting odds ratios (ln ROR), and the y-axis shows the common logarithm of the inverse p-value (−log (p-value)) from Fisher’s exact test. The dotted line on the y-axis represents p = 0.05. The plot colors represent the total number of reports. As the RORs became more negative, the tendency toward AEs decreased, and decreasing p-values indicated greater statistical significance. The upper-left portion of the plot shows the concomitant drugs that are less frequently associated with oral mucositis-related AEs. AEs, adverse events; ROR, reporting odds ratio.
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Table 1. Number of reports and reporting odds ratios for oral mucositis.
Table 1. Number of reports and reporting odds ratios for oral mucositis.
ATC a Category (ATC a Code)Antineoplastic AgentsCase (n)Total (n)ROR b (95% CI c)p-Value
Total 2922210,822
Alkylating agents (L01A)Melphalan *13333706.99 (5.86–8.33)<0.0001
Busulfan *118187911.39 (9.43–13.75)<0.0001
Cyclophosphamide *8583071.73 (1.40–2.15)<0.0001
Thiotepa *2836014.25 (9.71–20.92)<0.0001
Bendamustine1926651.22 (0.78–1.91)0.4490
Ranimustine *124984.26 (2.43–7.47)0.0001
Ifosfamide916830.94 (0.50–1.78)0.8740
Temozolomide716780.74 (0.36–1.52)0.4270
Streptozocin21361.12 (0.88–10.75)0.1970
Dacarbazine0954
Carmustine0538
Nimustine0489
Larotrectinib05
Carboquone05
Antimetabolites (L01B)Tegafur/gimeracil/oteracil potassium *523987210.30 (9.39–11.31)<0.0001
Fluorouracil *33318,6613.16 (2.83–3.54)<0.0001
Capecitabine *22261826.43 (5.61–7.38)<0.0001
Methotrexate *19840918.76 (7.57–10.13)<0.0001
Tegafur and uracil *9022856.93 (5.61–8.57)<0.0001
Fludarabine *8331104.63 (3.71–5.76)<0.0001
Cytarabine *7749712.65 (2.11–3.32)<0.0001
Pralatrexate *7323874.60 (56.59–98.33)<0.0001
Gemcitabine4468891.08 (0.80–1.45)0.6390
Pemetrexed2652900.83 (0.57–1.22)0.3710
Azacitidine1126510.72 (0.40–1.28)0.2560
Clofarabine *92955.49 (2.88–10.49)0.0001
Mercaptopurine *53023.06 (1.32–7.11)0.0370
Trifluridine and tipiracil hydrochloride36660.87 (0.30–2.49)0.8040
Nelarabine32022.90 (1.02–8.35) *0.1230
Cladribine11711.45 (0.29–7.26)1.0000
Tegafur1514.91 (0.97–24.93)0.2650
Carmofur08
Decitabine01
Plant alkaloids and other natural products (L01C)Irinotecan *17310,2532.92 (2.50–3.40)<0.0001
Docetaxel *17010,4412.81 (2.41–3.28)<0.0001
Etoposide *12375832.78 (2.33–3.33)<0.0001
Paclitaxel8111,9971.13 (0.91–1.41)0.2840
Vincristine4773531.08 (0.81–1.43)0.6490
Vinorelbine1312231.85 (1.08–3.16)0.0592
Vinblastine47580.99 (0.39–2.49)1.0000
Topotecan0482
Vindesine0482
Trabectedin0258
Cabazitaxel02
Cytotoxic antibiotics and related substances (L01D)Doxorubicin *18787153.75 (3.23–4.34)<0.0001
Dactinomycin *2739812.31 (8.35–18.15)<0.0001
Epirubicin1626581.03 (0.64–1.68)0.9000
Amrubicin1013641.28 (0.70–2.36)0.4810
Idarubicin97882.02 (1.06–3.83)0.0602
Mitoxantrone *85822.45 (1.24–4.82)0.0262
Pirarubicin615500.70 (0.32–1.50)0.4060
Mitomycin55551.65 (0.71–3.83)0.3970
Daunorubicin411500.65 (0.26–1.64)0.3400
Bleomycin27910.52 (0.15–1.81)0.3480
Aclarubicin0360
Protein kinase inhibitors (L01E)Everolimus *264362313.74 (12.08–15.63)<0.0001
Sunitinib *11144254.35 (3.60–5.27)<0.0001
Palbociclib *7324665.14 (4.07–6.50)<0.0001
Lapatinib *7086514.86 (11.63–19.00)<0.0001
Sorafenib *6960311.94 (1.53–2.46)<0.0001
Erlotinib *6333783.20 (2.49–4.10)<0.0001
Afatinib *4410207.60 (5.62–10.28)<0.0001
Axitinib *3719193.31 (2.39–4.58)<0.0001
Temsirolimus *297267.03 (4.86–10.18)<0.0001
Gefitinib2131791.13 (0.74–1.72)0.6440
Lenvatinib1825961.19 (0.75–1.88)0.5230
Imatinib1648210.57 (0.35–0.92)0.0114
Osimertinib1226990.77 (0.44–1.34)0.3800
Regorafenib1122800.84 (0.47–1.50)0.5860
Pazopanib1120790.92 (0.51–1.64)0.7770
Cabozantinib1111641.65 (0.92–2.95)0.1270
Ibrutinib55741.60 (0.69–3.70)0.4050
Nilotinib323160.25 (0.09–0.71)0.0010
Dasatinib320830.28 (0.10–0.79)0.0026
Trametinib35831.00 (0.35–2.85)1.0000
Crizotinib212720.33 (0.09–1.12)0.0421
Gilteritinib27340.56 (0.16–1.95)0.3400
Dabrafenib25700.73 (0.21–2.52)0.7810
Lorlatinib23171.31 (0.38–4.55)0.7160
Dacomitinib *23014.51 (3.98–52.89)0.0140
Nintedanib19180.27 (0.05–1.33)0.0516
Ponatinib17930.31 (0.06–1.55)0.1020
Cediranib1514.91 (0.97–24.93)0.2650
Ruxolitinib01417
Abemaciclib0624
Bosutinib0527
Alectinib0473
Ceritinib0379
Encorafenib0341
Binimetinib0319
Brigatinib0141
Vemurafenib0136
Entrectinib0123
Tepotinib072
Vandetanib071
Quizartinib050
Capmatinib022
Acalabrutinib013
Selpercatinib010
Pemigatinib06
Monoclonal antibodies and antibody-drug conjugates (L01F)Bevacizumab *16914,8341.95 (1.67–2.27)<0.0001
Cetuximab *12639735.56 (4.65–6.65)<0.0001
Panitumumab *9123876.70 (5.43–8.27)<0.0001
Trastuzumab *6443832.49 (1.94–3.19)<0.0001
Nivolumab6116,3780.62 (0.48–0.80)0.0001
Ramucirumab *5335622.54 (1.93–3.33)<0.0001
Rituximab4882400.98 (0.74–1.30)0.8860
Pembrolizumab4396280.75 (0.55–1.01)0.0465
Atezolizumab2741801.10 (0.75–1.60)0.6870
Ipilimumab2075070.45 (0.29–0.70)<0.0001
Pertuzumab1115481.24 (0.69–2.21)0.5100
Mogamulizumab87042.02 (1.03–3.97)0.0797
Avelumab *73773.35 (1.63–6.91)0.0084
Gemtuzumab ozogamicin57391.24 (0.54–2.87)0.6360
Obinutuzumab49050.83 (0.33–2.08)0.8270
Polatuzumab vedotin35271.10 (0.39–3.16)1.0000
Necitumumab *31025.82 (2.00–16.91)0.0240
Enfortumab vedotin21762.37 (0.68–8.26)0.2860
Durvalumab122440.11 (0.02–0.55)<0.0001
Daratumumab113420.18 (0.04–0.92)0.0067
Blinatumomab16440.39 (0.08–1.91)0.1980
Inotuzumab ozogamicin12740.91 (0.18–4.51)1.0000
Brentuximab vedotin01493
Elotuzumab01089
Trastuzumab emtansine0619
Trastuzumab deruxtecan0310
Isatuximab0251
Ofatumumab0107
Dinutuximab beta017
Olaratumab01
Other antineoplastic agents (L01X)Cisplatin *30514,3083.79 (3.37–4.26)<0.0001
Oxaliplatin *20913,6432.65 (2.31–3.05)<0.0001
Carboplatin *11814,2831.39 (1.16–1.67)0.0008
Eribulin *4512386.36 (4.72–8.56)<0.0001
Asparaginase913191.20 (0.63–2.27)0.5940
Niraparib67011.55 (0.71–3.35)0.3250
Hydroxycarbamide511650.78 (0.34–1.81)0.5700
Procarbazine34651.25 (0.44–3.58)0.7610
Tretinoin33621.61 (0.56–4.62)0.4840
Bortezomib240880.10 (0.03–0.35)<0.0001
Olaparib214420.29 (0.08–0.99)0.0156
Mitotane21442.90 (0.83–10.14)0.2150
Ixazomib114590.17 (0.03–0.84)0.0032
Estramustine16790.37 (0.07–1.81)0.2040
Arsenic trioxide14770.52 (0.10–2.59)0.5420
Vorinostat11032.42 (0.48–12.14)0.4630
Carfilzomib01182
Venetoclax0599
Panobinostat0578
Anagrelide0357
Romidepsin0232
Aminolevulinic acid0159
Bexarotene0118
Tisagenlecleucel078
Aflibercept049
Pentostatin024
Denileukin diftitox020
Porfimer sodium016
Veliparib02
Glasdegib01
a ATC: Anatomical Therapeutic Chemical. b ROR: Reporting odds ratio. c CI: Confidence interval. * Significant ROR (ROR ≥ 1, Lower limit of the 95% CI corresponding to the ROR ≥ 1, and p-value < 0.05.).
Table 2. Median values and Weibull parameters of antineoplastic drug-induced oral mucositis.
Table 2. Median values and Weibull parameters of antineoplastic drug-induced oral mucositis.
Antineoplastic Agents (ATC a Code)CaseMedian
(25–75%) (Day)
Scale Parameter, α (95% CI b)Shape Parameter, β (95% CI b)Pattern
Alkylating agents (L01A)
Melphalan899.0 (6.0–11.0)9.90 (8.97–10.90)2.28 (1.94–2.63)Wear out failure
Busulfan6313.0 (11.0–15.0)17.85 (13.61–23.36)0.98 (0.85–1.12)Random failure
Cyclophosphamide3113.0 (9.0–53.0)31.80 (21.47–46.21)1.00 (0.76–1.28)Random failure
Thiotepa1211.5 (10.25–14.0)13.79 (10.45–17.96)2.37 (1.49–3.40)Wear out failure
Ranimustine313.0 (8.0–13.0)12.26 (9.19–16.31)6.58 (1.91–16.24)Wear out failure
Antimetabolites (L01B)
Tegafur/gimeracil/oteracil potassium41612.0 (9.0–18.0)23.98 (21.49–26.74)0.94 (0.88–0.999)Early failure
Fluorouracil12618.0 (9.0–49.0)37.45 (30.23–46.16)0.88 (0.77–0.996)Early failure
Capecitabine15014.0 (8.75–32.25)30.66 (25.01–37.43)0.85 (0.76–0.95)Early failure
Methotrexate2613.0 (6.0–20.25)30.24 (16.49–53.99)0.71 (0.53–0.91)Early failure
Tegafur and uracil5917.0 (9.0–32.0)39.45 (27.50–55.92)0.78 (0.64–0.92)Early failure
Fludarabine2513.0 (10.0–15.0)17.12 (11.86–24.45)1.18 (0.90–1.48)Random failure
Cytarabine2212.5 (9.0–33.75)30.49 (17.99–50.36)0.90 (0.65–1.17)Random failure
Pralatrexate558.0 (6.0–15.0)17.67 (12.39–24.99)0.81 (0.68–0.95)Early failure
Clofarabine620.0 (6.0–65.5)36.54 (11.54–108.38)0.89 (0.44–1.50)Random failure
Plant alkaloids and other natural products (L01C)
Irinotecan10415.0 (9.0–29.0)33.08 (25.18–43.18)0.76 (0.67–0.87)Early failure
Docetaxel708.0 (7.0–21.25)17.06 (13.48–21.42)1.09 (0.91–1.28)Random failure
Etoposide4310.0 (8.0–15.0)21.83 (15.36–30.66)0.94 (0.75–1.14)Random failure
Cytotoxic antibiotics and related substances (L01D)
Doxorubicin11516.0 (12.0–47.0)32.26 (26.69–38.83)1.04 (0.91–1.18)Random failure
Dactinomycin99.0 (8.0–15.5)14.27 (9.53–20.89)1.95 (1.13–2.95)Wear out failure
Mitoxantrone27.0 (5.0–9.0)7.76 (4.06–15.31)4.08 (0.89–11.02)Random failure
Protein kinase inhibitors (L01E)
Everolimus11715.0 (10.0–23.5)25.11 (20.75–30.28)1.02 (0.90–1.15)Random failure
Sunitinib2518.0 (14.5–57.0)42.33 (27.80–63.05)1.05 (0.77–1.38)Random failure
Palbociclib1922.0 (15.0–30.0)30.72 (22.34–41.57)1.61 (1.13–2.15)Wear out failure
Lapatinib6117.0 (8.0–51.5)38.23 (27.62–52.30)0.85 (0.70–1.01)Random failure
Sorafenib2415.5 (9.25–26.0)28.34 (18.00–43.63)0.99 (0.72–1.30)Random failure
Erlotinib728.0 (5.25–28.75)23.42 (16.57–32.77)0.73 (0.61–0.85)Early failure
Afatinib459.0 (6.0–20.5)19.23 (13.23–27.66)0.86 (0.70–1.02)Random failure
Axitinib1253.0 (15.75–92.75)57.70 (32.54–99.11)1.18 (0.69–1.83)Random failure
Temsirolimus2215.0 (7.75–36.0)24.73 (16.92–35.38)1.25 (0.88–1.70)Random failure
Monoclonal antibodies and antibody-drug conjugates (L01F)
Bevacizumab7523.0 (11.0–58.0)47.36 (35.01–63.47)0.82 (0.69–0.96)Early failure
Cetuximab7822.0 (13.75–35.0)30.93 (24.42–38.99)1.02 (0.87–1.17)Random failure
Panitumumab5613.5 (8.25–31.5)30.16 (21.66–41.59)0.87 (0.72–1.02)Random failure
Trastuzumab1819.5 (6.5–89.25)51.66 (23.62–107.87)0.68 (0.46–0.94)Early failure
Ramucirumab2010.0 (7.0–22.0)20.85 (12.30–34.46)0.94 (0.67–1.24)Random failure
Avelumab216.5 (15.0–18.0)17.19 (14.06–21.22)13.16 (2.88–35.52)Wear out failure
Other antineoplastic agents (L01X)
Cisplatin11011.0 (6.0–26.25)25.06 (19.23–32.46)0.76 (0.67–0.87)Early failure
Oxaliplatin9016.0 (9.0–39.25)33.58 (26.38–42.47)0.93 (0.80–1.07)Random failure
Carboplatin5310.0 (8.0–13.5)16.32 (12.57–21.02)1.13 (0.93–1.34)Random failure
Eribulin388.0 (6.75–16.75)20.58 (13.23–31.49)0.80 (0.63–0.98)Early failure
a ATC: Anatomical Therapeutic Chemical. b CI: Confidence interval.
Table 3. Number of reports and reporting odds ratios for concomitant drugs with antineoplastic drugs that show a low association with oral mucositis.
Table 3. Number of reports and reporting odds ratios for concomitant drugs with antineoplastic drugs that show a low association with oral mucositis.
ATC a Category
(ATC Code)
Concomitant DrugsCase (n)Total (n)ROR b (95% CI c)p-Value
All antineoplastic agentsDexamethasone16914,5120.83 (0.71–0.97)0.0168
Prednisolone14213,4070.75 (0.63–0.89)0.0006
Sulfamethoxazole/trimethoprim10292950.79 (0.64–0.96)0.0142
Esomeprazole magnesium hydrate3545850.55 (0.39–0.77)0.0001
Mycophenolate mofetil1721700.58 (0.36–0.92)0.0125
Febuxostat1327980.34 (0.20–0.58)<0.0001
Methylprednisolone915790.43 (0.23–0.81)0.0033
Voriconazole812850.47 (0.24–0.93)0.0159
Edoxaban tosilate hydrate59280.42 (0.18–0.98)0.0231
Azilsartan37890.32 (0.11–0.90)0.0089
Basiliximab37200.35 (0.12–0.99)0.0233
Lenalidomide hydrate246020.04 (0.01–0.13)<0.0001
Alkylating agents (L01A)Prednisolone4445360.55 (0.40–0.76)0.0001
Palonosetron hydrochloride14900.19 (0.04–0.93)0.0055
Antimetabolites (L01B)Calcium levofolinate18712,6290.47 (0.46–0.63)<0.0001
Levofloxacin hydrate3017820.68 (0.47–0.98)0.0296
Panvitan® powder for prescription *2117870.47 (0.31–0.73)0.0001
Betamethasone173890.15 (0.03–0.76)0.0211
Esomeprazole magnesium hydrate1510850.57 (0.34–0.94)0.0173
Voriconazole87050.48 (0.24–0.94)0.0194
Febuxostat45570.32 (0.13–0.81)0.0036
Sodium chloride44860.37 (0.14–0.93)0.0122
Carbazochrome sodium sulfonate hydrate34020.34 (0.12–0.99)0.0221
Hydroxocobalamin acetate24530.22 (0.06–0.76)0.0020
Plant alkaloids and other natural products (L01C)Prednisolone4358350.57 (0.42–0.78)0.0002
Sodium chloride16460.19 (0.04–0.92)0.0059
Cytotoxic antibiotics and related substances (L01D)Prednisolone2646360.30 (0.20–0.45)<0.0001
Sulfamethoxazole/trimethoprim1113390.53 (0.30–0.97)0.0270
Protein kinase inhibitors (L01E)Sulfamethoxazole/trimethoprim311620.20 (0.07–0.58)<0.0001
Monoclonal antibodies and antibody-drug conjugates (L01F)Lenalidomide hydrate118620.09 (0.02–0.43)<0.0001
Mycophenolate mofetil514850.40 (0.17–0.94)0.0170
Other antineoplastic agents (L01X)Dexamethasone5581530.52 (0.40–0.69)<0.0001
Famotidine2331970.59 (0.39–0.89)0.0075
Panvitan® powder for prescription *914750.52 (0.28–0.99)0.0293
Acyclovir716300.37 (0.18–0.76)0.0017
Pregabalin511970.37 (0.16–0.86)0.0070
Diphenhydramine hydrochloride39570.30 (0.10–0.85)0.0064
Lenalidomide hydrate128730.04 (0.01–0.20)<0.0001
Febuxostat18920.14 (0.03–0.67)0.0005
* Panvitan® powder for prescription: Retinol palmitate, thiamine nitrate, riboflavin, pyridoxine hydrochloride, cyanocobalamin, ascorbic acid, ergocalciferol, tocopherol acetate, calcium pantothenate, nicotinamide and folic acid. a ATC: Anatomical Therapeutic Chemical. b ROR: Reporting odds ratio. c CI: Confidence interval.
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Matsuo, H.; Endo, K.; Tanaka, H.; Onoda, T.; Ishii, T. Fact-Finding Survey and Exploration of Preventive Drugs for Antineoplastic Drug-Induced Oral Mucositis Using the Japanese Adverse Drug Event Report Database. Sci. Pharm. 2024, 92, 34. https://doi.org/10.3390/scipharm92020034

AMA Style

Matsuo H, Endo K, Tanaka H, Onoda T, Ishii T. Fact-Finding Survey and Exploration of Preventive Drugs for Antineoplastic Drug-Induced Oral Mucositis Using the Japanese Adverse Drug Event Report Database. Scientia Pharmaceutica. 2024; 92(2):34. https://doi.org/10.3390/scipharm92020034

Chicago/Turabian Style

Matsuo, Hajime, Kiri Endo, Hiroyuki Tanaka, Toshihisa Onoda, and Toshihiro Ishii. 2024. "Fact-Finding Survey and Exploration of Preventive Drugs for Antineoplastic Drug-Induced Oral Mucositis Using the Japanese Adverse Drug Event Report Database" Scientia Pharmaceutica 92, no. 2: 34. https://doi.org/10.3390/scipharm92020034

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