The role of oral microbiota in the development of oral mucositis in pediatric oncology patients treated with antineoplastic drugs: a systematic review

The PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) guidelines were used to develop the protocol for this research. The Patient-Intervention-Comparison-Outcome (PICO) question was employed to formulate a clear study aim: Patients under 18 years of age, of any gender and ethnicity, at diagnosis of any type of childhood cancer (P = Patient); oral health assessment at the time of neoplasm diagnosis before and during chemotherapy (I = intervention); not considered (C = Comparison); assessment of quantitative and qualitative change in the oral microbiota; evaluation of oral mucositis’s incidence (O = outcome).

A bibliographic search was conducted upon three different scientific digital databases, namely MEDLINE, WOS and SCOPUS. For this research, the following algorithm was established: (child OR pediatrics OR pediatric OR infant) AND (neoplasms OR neoplasia OR neoplasias OR tumor OR malignancy OR malignancies OR cancer) (stomatitis OR oromucositis OR oromucositides OR mucositis) AND (chemotherapy OR antineoplastic treatments).

All original articles, case reports and case series, with no restrictions regarding year of publication and type of study meeting the following inclusion criteria were included:

Exclusion criteria were defined as follows:

The team conducted study selection by reviewing the titles and abstracts obtained by the digital research and only those that met the eligibility requirements were evaluated. The remaining articles were then thoroughly read, and the unselected articles were discarded. Abstracts of reviews obtained by the digital research, described above, were also examined. From those included in the first step selection, citations of articles related to the topic were extracted. The abstracts of these articles were then subjected to the same analysis as all the other ones. Article selection process was always performed independently by two reviewers, and a third reviewer’s opinion was claimed if disagreement among the two reviewers occurred. Data extraction was performed on included articles in order to create a database with all the variables accessible on each article that were pertinent to the study. When available, the following details were taken from each chosen study: type of study, number of patients, age range of patients, number of test group, characteristics of test group, number of control group, characteristics of control group, type of antineoplastic therapy, mucositis diagnosis criteria, mucositis preventive intervention, mucositis treatment intervention, timing of clinical evaluation, timing of microbiological evaluation, type and site of microbiological evaluation, mucositis prevalence and microbiological evaluation results.

A quality assessment of observational epidemiological studies was performed independently by two of the review authors by means of the ROBINS-E—Risk of Bias In Nonrandomized Studies—of Exposure (Higgins J. et al., 2022); the risk was defined as very high, high, generating some concerns and low. It is based on the analysis of 7 domains: (D1) risk of bias due to confounding factors, (D2) risk of bias from exposure measurement, (D3) risk of bias in selection of study participants (or analyses), (D4) risk of bias due to postexposure interventions, (D5) risk of bias due to missing data, (D6) risk of bias from outcome measurements, and (D7) risk of bias in selection of reported outcomes. The risk was defined as follows:

Case series were differently analyzed by means of specific quality assessment tools developed by the National Institutes of Health (NIH) in 2013.

The quality of each study was rated as “good,” “sufficient,” or “poor” after answering the following 9 questions: a) was the study question or objective clearly stated?; b) was the study population clearly and fully described, including a case definition?; (c) were the cases consecutive?; (d) were the subjects comparable?; (e) was the intervention clearly described?; (f) were the outcome measurements clearly defined, valid, reliable, and implemented consistently across all study participants?; (g) was the length of follow-up adequate?; (h) were the statistical methods well described?; (i) were the results well described? The possible answers to the questions were: yes, no, cannot determine/not applicable/not reported.

Case reports were evaluated using the critical appraisal checklist (JBI critical appraisal checklist, 2017 version) developed by the Joanna Briggs Institute. The overall assessment led to “inclusion” or “exclusion” of a study in the systematic review or even the possible “need to seek further information” to make a judgment. Judgment is made after answering the following 8 questions: 1. Were the patient’s demographic characteristics clearly described?, 2. Was the patient’s history clearly described and presented as a timeline?, 3. Was the patient’s current clinical condition clearly described? 4. Have the diagnostic tests or assessment methods and results been clearly described?, 5. Have the interventions or treatment procedures been clearly described?, 6. Has the postintervention clinical condition been clearly described?, 7. have adverse events (harms) or unexpected events been identified and described?, 8. does the case report provide take-home messages? The 4 possible response options were “yes”, “no”, “unclear”, “not applicable”.

Other possible sources of bias were not considered.

The overall mean prevalence of mucositis was calculated as weighted mean of prevalence values of mucositis expressed in each study. Whenever the prevalence assessment was performed at different times of therapy or through a clusterization of the study population, a mean value of prevalence values obtained from each study was considered.

Case series and case reports were excluded from the weighted mean calculation.

Studies by Anirudhan (2008), Olczak-Kowalczyk (2012), and Bardellini (2017) reported microbiological data obtained through direct sampling of sites with lesions (Table 7) [29, 30, 37]. Coagulase-negative Staphylococci and Streptococcus viridans were found with a relative high percentage in both Olczak-Kowalczyk’s (2012) and Anirudhan’s (2008) studies [29, 37].

Six studies reported data regarding clinical and/or microbiological detection of herpetic and/or fungal lesions from direct sampling of oral lesions [27, 33‐35, 37, 38]. Among these, three detected Herpes simplex and Candida, while the others only detected Candida. The prevalence of Candida albicans was high (50–60%) in both the studies by Anirudhan (2008) and Olczak-Kowalczyk (2012), which performed microbiological testing on the specimens, with an overall percentage among the studies ranging from 16,1% to 78% (Table 8) [29, 37].

HSV infection was less frequent, with a range between 3 and 9,7% of the population.

Studies by Sixou et al. (1998) and Ye et al. (2013) evaluated the variation in the complexity of the oral bacterial flora and the percentage variation of certain bacterial species during chemotherapy treatment [39, 41].

The study by Sixou et al. (1998) showed how healthy patients have a consistently greater complexity of microbial flora in comparison to oncology patients undergoing chemotherapy on days 0, 7, 14, and 21 of chemotherapy treatment [39].

Oncology patients, however, showed a non-significant microbiological variation during therapy.

Meanwhile, in the study by Ye et al. (2013), the UniFrac distance, calculated from the diagnosis of neoplasia to the end of chemotherapy treatment, was higher in patients who developed mucositis (> 0.4 UniFrac distance) compared to those in whom it did not occur (< 0.4 UniFrac distance) [41].

UniFrac measures the distance between microbial communities based on the phylogeny of the operational taxonomic unit (OTU) [42]. It considers the presence or absence of an OTU in a community, rather than its abundance.

Regarding the percentage variation of different bacterial species detected in the oral cavity, in the total count of viable anaerobes before and after chemotherapy both studies analyzed the abundance of Capnocytophaga spp.

In the study by Sixou, the percentage of Capnocytophaga spp. was higher in healthy patients than in sick patients, whilst in sick patients there was no significant variation of the percentage during chemotherapy treatment [39].

In the study by Ye, a higher concentration of Capnocytophaga spp. was observed at the time of neoplasia diagnosis in patients who developed mucositis after chemotherapy than in those who did not develop mucositis [41].

The comparison of the frequency of different microorganisms in patients undergoing chemotherapy, following sampling from non-lesion sites of the oral cavity, is described in Table 9. Coagulase-negative Staphylococci had frequency percentages ranging from 25 to 80%, regardless of mucositis, after starting chemotherapy. Higher percentages were observed in patients with mucositis. Candida albicans, regardless of mucositis, ranged from 15 to 60%, with higher percentages in patients with mucositis. HSV, according to Mendoca 2012, showed a decrease in percentage from Day 14 to Day 56 of antineoplastic treatment [36]. Viridans streptococci and Capnocytophaga showed alternating trends between Day 0 and Day 21 of chemotherapy, with an increase in Viridans streptococci and a decrease in Capnocytophaga at the end of the treatment.