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Review

Oral Manifestations in Children and Young Adults with Down Syndrome: A Systematic Review of the Literature

1
Multidisciplinary Department of Medical-Surgical and Dental Specialties, University of Campania Luigi Vanvitelli, Via Luigi de Crecchio 6, 80138 Naples, Italy
2
Interdisciplinary Department of Medicine, University of Bari “Aldo Moro”, 70121 Bari, Italy
3
Private Practice, Studio Odontoiatrico Dr. Scivetti, Via Bovio 49, Giovinazzo, 70054 Bari, Italy
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work as co-first authors.
Appl. Sci. 2021, 11(12), 5408; https://doi.org/10.3390/app11125408
Submission received: 18 May 2021 / Revised: 3 June 2021 / Accepted: 7 June 2021 / Published: 10 June 2021
(This article belongs to the Special Issue Oral Medicine, Theory, Methods and Applications)

Abstract

:

Featured Application

The identification of the oral mucosa findings and oral candidiasis in children/young adults with Down Syndrome could help paediatricians, dentists, and parents/caregivers to manage them in the more appropriate way.

Abstract

Down syndrome (DS) is an autosomal disorder associated with mental and physical involvement. The typical craniofacial phenotype and the dental anomalies in DS subjects have been widely described, but a systematic report on the manifestations affecting the oral mucosae in children with DS is still lacking. This systematic review aimed to establish the prevalence of oral mucosal manifestations in children/young adults with DS. Pubmed, Web of Science, and Scopus were investigated in September 2020. Documents in English on DS children/young adults (up to 25 years) reporting oral mucosal findings were considered. Study quality was assessed with ROBIN-I. Of the 150 references retrieved, 14 studies were considered eligible. The risk of bias ranged from low to unclear. Fissured tongue appeared to increase with age and was more prevalent in DS children than in the general population. Lip fissures and cheilitis were heterogeneously reported. Candida spp. carriage with and without active candidiasis was more frequent in DS children/young adults than in controls. C. albicans was the most prevalent species. Few other oral mucosal conditions have been reported sporadically. The heterogeneity of the works revealed the need for more appropriate oral examination to intercept the oral manifestations of oral mucosa and prevent recurrent candidiasis.

1. Introduction

Down syndrome (DS) is an autosomal congenital disorder caused by the presence of all or part of an extra 21st chromosome. DS is also called Trisomy 21, 95% of cases being caused by a numerical change of chromosome 21, with an extra copy that creates a chromosome count of 47; less frequently, DS is a consequence of the translocation of part of an extra chromosome 21 (3–4% of cases), or mosaicisms (1–2% of cases) [1]. DS is the most common trisomy compatible with life; its incidence is influenced by maternal age and ranges from 1 in 319 to 1000 live births worldwide [2].
Individuals with DS have mild to severe intellectual disability, growth retardation, and heart defects, and are more prone to be affected by hypertension, leukaemia, gastrointestinal problems, and early onset of Alzheimer’s disease [2]. Among the typical and immediately recognizable oro-facial features, the most common are brachycephaly, epicanthic fold, slanted eyes, narrowed eye slits, cataracts and strabismus, flat nasal bridge, delayed dental eruption, dental agenesis, and small chin with microstomia and macroglossia, giving the typical phenotype of protruding tongue and lip incompetence [2]. The most common dermatological manifestations include alopecia areata, premature hair greying and ageing, palmoplantar hyperkeratosis, and xerosis [3].
The most reported manifestations of the oral mucosa are cheilitis, geographic tongue, and fissured tongue [4]; furthermore, people with DS are more prone to be affected by periodontal diseases and orofacial candidiasis, due to immunological disturbances and concomitant metabolic diseases such as diabetes [5].
Despite their common occurrence and various systematic reviews mainly focusing on craniofacial and/or dental anomalies in DS in subjects of all ages [6], a detailed report on the peculiarity of the manifestations involving the oral mucosa in DS children has not yet been completed. Therefore, the present systematic review, performed by oral pathologists and paediatric dentists who interface with this type of affection every day, aimed to identify and synthesize the prevalence of oral manifestations of soft tissues in children and young adults with DS, to define future directions to support the practitioners involved in the care management of the DS children.

2. Materials and Methods

The present work was performed according to the Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA) checklist [7]. The protocol was registered on PROSPERO (reference CRD42021224207) and the research query was formulated according to the PICOS method (Participants, Intervention, Comparison, Outcomes, and Study): the participants were children and young adults (age range 0–25 years) affected by Down syndrome (DS); the intervention was the examination of the oral mucosa; the comparison was towards subjects not affected by DS; the outcomes included the incidence/prevalence of oral mucosal manifestations; and the study design was a systematic review.

2.1. Research Protocol

The research was conducted on 17 September 2020, and the MesHs terms used and combined by Boolean connectors are reported in Table 1.

2.2. Eligibility Criteria

All original papers reported randomized controlled clinical trials and all observational studies (cohort and case-control studies, cross-sectional investigations, case series, and single case reports) describing oral mucosal manifestations in children with DS were included. Reviews, proceedings, letters, editorials, theses, abstracts, and all studies written in a language other than English were not taken into consideration.
Studies involving subjects over 25 years of age or children with no DS or no manifestations at the oral mucosa were excluded, while those reporting stratified age groups from which data related to paediatric/young adult population could be extracted were considered just for the latter, as well studies that reported alterations of soft and hard tissues, in which only the former were considered.

2.3. Literature Search, Selection of Studies and Data Extraction

Pubmed, Web of Science (WoS), and Scopus were investigated with no limits of year of publishing, from the first available date until September 2020. The results of the three searches were imported and combined with Mendeley-Reference Management Software & Researcher Network (available at https://www.mendeley.com (access on 20 January 2021). After the duplicates were removed, two reviewers examined the titles and abstracts from the documents and excluded any papers that did not meet the inclusion criteria. If the abstract did not provide sufficient information to evaluate the eligibility of the paper, its full text was considered. Then, two reviewers thoroughly read the full texts of the remaining articles to assess the relevance of the content of each study and consider those suitable for qualitative synthesis. In both steps, a third author was consulted in cases of disagreement between the two reviewers.
Full texts of the studies deemed suitable for inclusion were obtained and the following data extracted from each work: type of study, sample size, age range and sex of the subjects, and oral mucosal manifestations reported in children with DS.

2.4. Risk of Bias (RoB) in Individual Studies

Every single study was independently evaluated by two authors (and by a third in case of disagreement between them) to assess the risk of bias (RoB), following the seven domains-based assessment described by Sterne et al. in the Risk of Bias in Non-Randomised Studies of Interventions (ROBINS-I) [8]: bias due to confounding, selection of participants, classification of interventions, deviations from intended interventions, missing data, measurement of outcomes, and selection of the reported results.
Using the ROBIN-I tool, each study was overall classified as follows: “low risk of bias”(LR) if all criteria were met and the study was comparable to a well-performed randomized trial; “moderate risk of bias” (MR) when the study appeared to be non-randomized study but could be considered comparable to a well-performed randomized trial; “serious risk of bias” (SR) if one or more criteria have not been met and one or more plausible bias have severely undermined confidence in the results; “critical risk of bias” (CR) for studies too problematic and reporting critical bias; and “unclear risk of bias” (UR) if one or more criteria were rated as unclear and/or a plausible bias raised some doubts about the results.

3. Results

In total, 223 articles were identified (Figure 1). After 73 duplicates were removed, the remaining 150 articles underwent the first selection based on inclusion/exclusion criteria and title/abstract. After screening for relevance, 128 articles were excluded, and the remaining 22 papers underwent full-text assessment for eligibility. At the end of this selection, 14 original papers were included for fulfilling the requirements and were analyzed for qualitative review (Table 2).

3.1. Characteristics of the Studies

An overview of the main characteristics retrieved from the 14 studies is shown in Table 2. Among the 14 studies considered, published in English between 1996 and 2020, two were performed in Turkey [9,10], one in Sweden [11], one in China [12], two in Spain [13,14] (one of which took place partly also in UK [13]), two in Brazil [15,16], one in Iran [3], two in India [17,18], one in Portugal [19], one in Yemen [20], and one in Poland [21]. In nine studies [3,9,10,11,12,14,15,19,20] the age range of all participants fell within the range considered (0–25 years) and in the remaining five studies [12,16,17,18,21] only data referring to subjects under the age of 25 were considered. Aside from one case report by Chow et al. [12], the remaining 13 studies were observational: six case-control studies on DS subjects and aged- and sex-matched healthy subjects [9,10,11,15,16,19], and seven cohort studies on subjects with DS [3,13,14,17,18,20,21].

3.2. Risk of Bias (RoB) Assessment

When assessed with ROBINS-I, (Table 3), three studies were graded as SR [16,18,19] and eleven as MR [3,9,10,11,12,13,14,15,17,20,21]. In details, being the DS phenotypically recognizable, no blinding observation was possible, and therefore the biases due to departures from intended interventions were all at moderate risk, while the biases due to confounding were always uninterpretable (UR). Regarding selection bias, one study [12] was a case report, and were therefore considered MR, three studies recruited only volunteers and were therefore considered SR [16,18,19], five studies that enrolled consecutive/random patients presented as LR [9,11,17,20,21], and in the remaining five studies [3,10,13,14,15] the recruitment selection was not clearly reported. The biases due to the missing data were related to the partial lack of stratification of the results according to the age groups considered, thus not allowing only the age groups of the inclusion criteria for those studies classified as MR to be considered. The biases in measurement outcomes were related to the examination performed by the same examiners (LR) or more than one (MR).

3.3. Outcome

Oral examination was performed by oral pathologists and/or dental practitioners in seven works, while in the remaining works it was performed by dermatologists, geneticists, and/or paediatricians. Fissured tongue and lip lesions/cheilitis were the most frequently reported and investigated oral mucosal findings, described in eight [3,9,10,12,14,17,18,20] and nine [3,9,10,13,14,15,17,18,20] studies, respectively; the geographic tongue was reported in three studies [3,9,10] and other lingual and/oral affections were variously reported in four studies [3,18,20,21]; five studies focused on oral candidiasis and/or Candida spp. carriage in children with DS [11,13,15,17,19].

3.3.1. Fissured Tongue

Fissured tongue (FT) is a benign, usually asymptomatic condition characterized by deep grooves on the dorsal surface and margins of the tongue [22]. Eight works investigated the prevalence of FT in groups of children with DS (Table 4): one case report [12], six cohort studies [3,9,14,17,18,20], and one age- and sex-matched case/control study [10]. The grouping by age of the subjects was heterogeneous among studies and details for each work have been summarized in Table 4, in the legend.
The prevalence of FT increased with age. In DS children aged 0–5 years, Ercis et al. [9] reported 10% in a total of 59 subjects, while Daneshpazhooh et al. [3] found no FT in the 8 DS children considered in their study. In children with DS aged 5–10 years, Daneshpazhooh et al. [3] found FT in 21% of 33 subjects and Al-Maweri et al. [20] reported a prevalence of 78% of 9 subjects. In DS subjects between 10 and 15 years of age, FT varied from 34% of 50 subjects analyzed by Daneshpazhooh et al. [3] to 67% in 21 children by Al-Maweri et al. [20], up to 75% on 12 children reported by Ercis et al. [9]. Chow et al. [12] reported a case of a 12-old girl with FT.
Regarding DS subjects over the age of 15, only the data from Daneshpazhooh et al. [3] and Al-Maweri et al. [20] could be considered, the maximum age of the subjects enrolled being within 20 [3] and 18 years [20], with the prevalence of FT of 44% and 90%, respectively. Bilgili et al. [10] reported a higher statistical prevalence of FT in 50 children of the DS group compared to 50 healthy controls (10% versus 0%, p-value = 0.018, age range 0–11 years).

3.3.2. Geographic Tongue

Geographic tongue (GT) was reported in two cohort studies [3,9] and one case-control study [10]. GT is a benign condition of uncertain aetiology affecting the dorsal tongue, its margins and, rarely, other oral sites [22]. The percentages of GT reported were: 11% of 71 DS subjects (age range 0.17–25 years) by Ercis et al. [9]; 4% out of 100 DS subjects (age range 3–20 years) by Daneshpazhooh et al. [3]; and 2% out of 50 DS subjects by Bilgili et al. [10] (age range 0–11 years). When data were stratified by age groups, Ercis et al. found GT in 8 out of 59 subjects (14%) in the 0–5 years age group and no cases were reported in the 12 remaining subjects 6–25 years of age. In contrast, Daneshpazhooh et al. found no cases of GT in the eight children 0–5 years and 4 cases out of 92 in the subjects 6–25 years (4%). Bilgili et al. [10] reported no statistically significant differences in the GT prevalence between the DS group and the healthy controls.

3.3.3. Lip Lesions (Lip Fissures and Cheilitis)

Eight papers reported various types of lip affections [3,9,10,13,14,17,18,20], mainly cheilitis and lip fissures (Table 5). The origin of cheilitis has not always been reported or associated with fungal/bacterial infections. The nonspecific definition of “cheilitis” was reported in five studies, and the one by Sureshbabu et al. [17] distinguished between “cheilitis” and “angular cheilitis”. As for FT, also in this case the studies have considered different age grouping and the details for each work have been summarized in Table 5, in legend. In the studies reporting lip lesions both in children than in adults over 25 years old, only the first ones have been considered.
Angular cheilitis was reported in 7% of 67 subjects by Sureshbabu et al. [17] and 73% of 15 subjects by Camacho et al. [14]: both works reported these rates in children aged 0–15 years. Shukla et al. [18] and Scully et al. [13] considered age groups between 0–40 and 0–>60, respectively, and it was not possible to extrapolate age-stratified data: the overall prevalence in these two studies was 22% out of 77 subjects and 25% of 24 subjects, respectively.
In the studies investigating “cheilitis”, it was lacking [3,17] or very low [9] in children with DS under the age of 5, while it increased in those aged 6 to 15 years. Scully et al. [13] considered an age range between 0–10 years and the prevalence of cheilitis was 27% out of 11 subjects. In DS subjects older than 5 years, Ercis et al. [9] reported a prevalence of 25% of 12 subjects between 6–25 years, Daneshpazhooh et al. [3] 14% of 92 subjects between 6–20 years, Sureshbabu et al. [17] reported 24% of 46 subjects aged 6–15, and Al-Maweri et al. [20] reported it in 14% of 50 subjects aged 6–18 years. Bilgili et al. [10] reported a higher statistical prevalence of cheilitis in the DS groups aged 0 to 11 years compared to heathy controls (6% versus 0%, p value = 0.009).
Lip fissures, also called cracked or fissured lips [13], have been reported in three papers [13,14,20]. Camacho et al. [14] found them in 20% of 15 DS subjects under the age of 16 and none in 57 other DS subjects aged between 2 and 29 years. Al-Maweri et al. [20] reported a rate of 64% in 50 subjects aged 6–18 years, while Scully et al. [13] reported a rate of 17% in 24 DS subjects aged 0–20 years.

3.3.4. Other Lingual/Oral Affections

A few other findings of the oral mucosa have been sporadically reported: one case of herpes labialis, one of cheek biting and two traumatic ulcerations in 50 DS children considered by Al-Maweri et al. [20] and recurrent aphthous stomatitis not significantly different between DS children with and without the coeliac disease (15 vs. 11%, respectively), reported by Szaflarska-Popławska et al. [21].

3.3.5. Oral Candidiasis and Candida spp. Carriage

Reports on Candida spp. carriage, species typing and associations with oral candidiasis in children with DS were extremely heterogeneous and, therefore, must be considered individually.
In 1996, Carlstedt et al. [11] reported oral carriage of Candida species in a case-control study enrolling 50 DS subjects aged 0.6–20.5 years and 50 age- and sex-matched healthy controls: in DS subjects, C. albicans colonization was significantly higher (69% vs. 35% of controls, p value < 0.001) and significantly higher at tongue and palate as well as oral signs of erythematous candidiasis (40% vs. 1.8% in healthy controls), while white pseudomembranous lesions did not statistically differ between groups. As for other Candida species, C. parapsilosis, C. guillermondii, and C. tropicalis were rarely found in both groups (0–1.8%) and did not differ significantly.
In 2002, Scully et al. [13] evaluated the relationships between angular cheilitis, lip fissures, and C. albicans in a series of 50 DS subjects aged between 0–60 years and stratified by age. C. albicans was isolated in 11 of 13 subjects (84.6%) aged 0–10 years and in 7 of 12 (58%) aged 11–20 years. The presence of C. albicans was very frequently associated with lip lesions (in 80% of DS subjects aged 0–10 years and in 100% of those aged 11–20 years).
Four years later, Ribeiro et al. [15] conducted a case-control study on morphotyping and enzymotyping of C. albicans in 35 children aged 0–10 years (25 with DS and 10 controls); results showed significantly higher levels of two fungal enzymes in DS compared to the control group, proteinase (96% in DS children vs. 40%) and phospholipase (88% vs. 80%).
In 2012, Areias et al. [19] published a case-control study to correlate relative frequencies of Streptococcus mutans, Lactobacilli, and Candida spp. in salivary samples from DS children and their healthy siblings closest in age. Although the work has focused on the synergistic effect of Candida spp. with Streptococci on the onset of caries, the work reported that the frequency of the Candida spp. carriage was higher in the control group than in the DS group, without reaching statistical significance, but according to the low caries rates reported in the DS subjects.
Camacho et al. [14] reported that C. albicans had been cultured twice frequently in those DS patients with lip lesions compared to those without lip lesions.
Recently, Maranhão et al. [16] identified Candida spp. in a case-control study on 80 DS (7.7 mean age) and 80 non-syndromic volunteers (12.8 mean age), finding a statistically significant higher percentage of Candida carriers among the case group than in the control group (57.5 vs. 12%). Of these, C. albicans was the most prevalent species in both groups (93% of the DS subjects and 60% of the controls); C. glabrata was found alone in 7% of DS children and associated with C. albicans in 35% of them, while it was reported as the first and only species in 20% of controls. C. tropicalis and C. krusei were both found in 1% of controls as the only isolated species, while in DS subjects they were found as second species in association with C. albicans in 15% (C. albicans + C. tropicalis) and 4% (C. albicans + C. krusei), respectively, but never alone. In the DS group, 49% referred to previous oral candidiasis on questionnaires and 21% of them presented active candidiasis at the oral examination; the relative percentages in the control groups were 63% (history of oral candidiasis) and 0% (active oral candidiasis at examination), respectively.

4. Discussion

Various syndromic genetic disorders can be associated with oral manifestations, and, while some of them are extremely rare [23,24,25,26,27], many others are commonly seen: this is the case with Down syndrome (DS). DS is well known and its phenotypic aspect has been extensively described, but there is no systematic report on the particular prevalence of oral mucosal manifestation in children with DS.
Therefore, the present work systematically investigated the scientific literature to establish the conditions of the oral mucosa reported in children and young adults (from 0 to 25 years of age) with DS. Among the 150 papers found, only 14 fulfilled the inclusion criteria for the qualitative review.
The most reported findings were fissured tongue and lip lesions/cheilitis. Fissured tongue is a relatively common condition, more frequent in adulthood than in childhood, with a prevalence of approximately 2–5% of the general population, and ranging between 10–95% in DS, regardless of age [28].
In the studies considered here, although a precise stratification of prevalence percentages by years of age was not always reported, due to the different grouping systems adopted by the various authors, it was observed that the average prevalence of fissured tongue increases with age, being on average reported in 35% of children between 0–15 years (very rare before 2 years of age) and 65% of subjects over 15 years of age. The highest prevalence of FT was found by Sureshbabu et al. [17] in 52% of 67 children younger than 15 years.
Geographic tongue (GT) is reported in 1–3% of the healthy population, with no difference between females and males and ages [22]. Our results reported higher percentages of GT in DS children, being, in all studies considered, higher than the average prevalence in the population without Down syndrome. However, discordant trends were observed by age groups, as GT was reported higher (14%) in 0–5 years of age compared to 6–25 years in one study [9] and the opposite by Daneshapazhooh et al. [3] (4% of DS subjects between 6–20 years).
Cheilitis was reported in eight studies, but the definitions of sites and origins were homogeneous and not always considered. In particular, in the works in which the examination was performed by dentists and/or oral pathologists; these data were generally more defined than those reported by dermatologists or other medical specialists.
Oral candidiasis, Candida spp. typing and carriages have been the subject of various studies considered. Active oral candidiasis at clinical examination was more common in children/young adults with DS than in controls, as was the carrier status with no clinical signs of infection. Only the work by Areias et al. [19] has countered this finding, as they reported the frequency of the Candida spp. carriage was higher in the control group than in the DS, without reaching statistical significance. This could explain the lower caries rates in children with DS compared to healthy controls, but it does not endorse their greater susceptibility to oral candidiasis, thus imputing greater responsibility towards immunological disorders and/or oral lesions co-occurring in DS than the simple load of Candida spp. [29,30,31]. This hypothesis is reinforced by the evidence that C. albicans was the most prevalent species in both healthy subjects and DS ones, as well as it was found twice as frequently in those DS patients with lip lesions compared to those without lip lesions [13,20]; thus supporting the role of immunity, hyposalivation, and oral lesions in the onset of frequent oral infections in children with DS. Lastly, the work by Maranhão et al. [16] highlighted the coexistence of other Candida species (non-albicans Candida, NAC) besides C. albicans in DS compared with controls.
Only sporadic reports have been found regarding other oral mucosal conditions, such as herpes labialis, ulcerative/traumatic lesions, and check biting.
Based on the reported results, it is possible to orient the practitioners dealing with DS children to the correct management of the manifestations affecting the oral mucosa of these subjects with special needs.
FT, being generally asymptomatic, usually does not require treatment. However, the furrows that characterize the fissured tongue can be a receptacle for food debris, bacterial plaque and fungi and, consequently, bad oral hygiene and infectious diseases may occur. To prevent the accumulation of dental plaque and/or the onset of fungal infections, it is recommended to educate parents and caregivers to perform the hygiene of the tongue of their DS child in addition to routine dental hygiene. For this purpose, the use of tongue scrapers and/or brush tongue cleaners can help to maintain acceptable levels of tongue hygiene.
When inflammation or mycosis have occurred, the treatment may consist of the removal of triggering factors and the use of topical and/or systemic antimycotic drugs.
While the usage of antifungal agents has been revised for the general pediatric population [32], literature about the antimycotic protocols specific for DS children is not yet reported. Pediatric subjects differ from adults in host biology, predisposing conditions and oral microbiome composition and the DS children are further different from the healthy ones, so that specific antifungal therapies are required. Hence, choosing the most appropriate antimycotic therapy in DS children is a serious challenge. The clinicians dealing with oral candidiasis in these subjects must consider the general health conditions of each subject, the presence of immunological defects that can reduce the responsiveness to drug therapy, and the possible side effects related to nephrotoxicity when a renal involvement is already present. Furthermore, the Candida typing in DS children have been revealed to differ from healthy non-syndromic children, and the risk of drug resistance and/or the lack of responsiveness of oral candidiasis sustained by NAC species is another factor to consider. For the elderly and denture wearers, some authors have recently reported the efficacy and safety of the use of probiotics on prophylaxis and treatment of oral candidiasis [33]; further studies in this direction on children with DS or other diseases associated with the onset of oral candidiasis could represent a potentially valid alternative to conventional drug therapies.
Last, it was reported that the onset of oral candidiasis in DS children was more frequently associated with lip lesions; another key strategy to prevent this further occurrence, is to re-establish the integrity of the lips, via the use of hydrating and healing topical products, based on the content of vitamin E, hyaluronic acids and similar occurrences is to re-establish the integrity of the lips, via the use of hydrating and healing topical products, based on the content of vitamin E, hyaluronic acids, and similar.

5. Conclusions

The scarcity and heterogeneity of works reporting manifestations that affect the oral mucosa of children with DS reveals a gap in our knowledge that should be filled with larger and more detailed studies accompanied by changes in the clinical practice. Greater attention to inspection of the oral mucosae of children with DS and, in general, of all those with special needs, is necessary.
Several benefits would be derived, as follows:
  • Reduction of the risk of underestimating the presence of oral mucosal pseudo-lesions;
  • Enhancement of the clinician’s ability to intercept early signs of fungal infections; and
  • Prevention of these infections and/or interruption of the vicious circle of recurrence in subjects in which systemic and local conditions can favor them.
The support of non-invasive adjunctive tools [34,35,36] and the involvement of paediatric dentists and oral pathologists in these processes is desirable, as these professionals are inclined to work on children and trained to identify in detail any anomaly of the oral mucosa, rather than the dental ones [37,38,39].
In conclusion, scientific investigation and a personalized approach could offer more appropriate information to parents/caregivers and specialists dealing with DS children, to intercept and define benignant conditions and to prevent recurrent candidiasis, the related repeated use of pharmacological therapies and the effects resulting from lip fissures.

Author Contributions

A.L. and R.S. (Rossella Santoro) conceived the ideas; A.R., F.L., M.C. and D.D.S. collected and analyzed the data; M.C., M.S. and F.D.V. led the writing; A.L., M.P. and R.S. (Rosario Serpico) supervised and reviewed the project. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

We would like to thank our librarian, Remo, for his precious support which made it possible for us to work continuously and efficiently for the realization of the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. El-Gilany, A.H.; Yahia, S.; Shoker, M.; El-Dahtory, F. Cytogenetic and comorbidity profile of Down syndrome in Mansoura University Children’s Hospital, Egypt. Indian J. Hum. Genet. 2011, 17, 157–163. [Google Scholar] [CrossRef] [Green Version]
  2. Asim, A.; Kumar, A.; Muthuswamy, S.; Jain, S.; Agarwal, S. Down syndrome: An insight of the disease. J. Biomed. Sci. 2015, 22, 41. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  3. Daneshpazhooh, M.; Nazemi, T.M.; Bigdeloo, L.; Yoosefi, M. Mucocutaneous findings in 100 children with Down syndrome. Pediatr. Derm. 2007, 24, 317–320. [Google Scholar] [CrossRef] [PubMed]
  4. Shore, S.; Lightfoot, T.; Ansell, P. Oral disease in children with Down syndrome: Causes and prevention. Community Pract. 2010, 83, 18–21. [Google Scholar] [PubMed]
  5. Moreau, M.; Benhaddou, S.; Dard, R.; Tolu, S.; Hamzé, R.; Vialard, F.; Movassat, J.; Janel, N. Metabolic diseases and Down syndrome: How are they linked together? Biomedicines 2021, 9, 221. [Google Scholar] [CrossRef]
  6. Kaczorowska, N.; Kaczorowski, K.; Laskowska, J.; Mikulewicz, M. Down syndrome as a cause of abnormalities in the craniofacial region: A systematic literature review. Adv. Clin. Exp. Med. 2019, 28, 1587–1592. [Google Scholar] [CrossRef] [Green Version]
  7. Moher, D.; Liberati, A.; Tetzlaff, J.; Altman, D.G. Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. Int. J. Surg. 2010, 8, 336–341. [Google Scholar] [CrossRef] [Green Version]
  8. Sterne, J.A.C.; Hernán, M.A.; Reeves, B.C.; Savović, J.; Berkman, N.D.; Henry, M.V.D.; Altman, D.G.; Ansari, M.T.; Boutron, I.; Carpenter, J.R.; et al. ROBINS-I: A tool for assessing risk of bias in non-randomised studies of interventions. BMJ 2016, 355, i4919. [Google Scholar] [CrossRef] [Green Version]
  9. Ercis, M.; Balci, S.; Atakan, N. Dermatological manifestations of 71 Down syndrome children admitted to a clinical genetics unit. Clin. Genet. 1996, 50, 317–320. [Google Scholar] [PubMed]
  10. Bilgili, S.G.; Akdeniz, N.; Karadag, A.S.; Akbayram, S.; Calka, O.; Ozkol, H.U. Mucocutaneous disorders in children with down syndrome: Case-controlled study. Genet. Couns. 2011, 22, 385–392. [Google Scholar]
  11. Carlstedt, K.; Krekmanova, L.; Dahllöf, G.; Ericsson, B.; Braathen, G.; Modéer, T. Oral carriage of Candida species in children and adolescents with Down’s syndrome. Int. J. Paediatr. Dent. 1996, 6, 95–100. [Google Scholar] [CrossRef]
  12. Chow, K.M.; O’Donnell, D. Concomitant occurrence of hypodontia and supernumerary teeth in a patient with Down syndrome. Spec. Care Dent. 1997, 17, 54–57. [Google Scholar] [CrossRef] [PubMed]
  13. Scully, C.; Van Bruggen, W.; Dios, P.D.; Casal, B.; Porter, S.; Davison, M.-F. Down syndrome: Lip lesions (angular stomatitis and fissures) and Candida albicans. Br. J. Derm. 2002, 147, 37–40. [Google Scholar] [CrossRef] [PubMed]
  14. Camacho, F.M.; Mazuecos, J.; Ferrándiz, L.; Cantalejo, C.; Cabello, Á. Phenotypical and dermatological findings of Down syndrome in Southern Spain. Eur. J. Pediat. Derm. 2014, 24, 7–12. [Google Scholar]
  15. Ribeiro, E.L.; Scroferneker, M.L.; Cavalhaes, M.S.; Campos, C.C.; Nagato, G.M.; Souza, N.A.; Ferreira, W.M.; Cardoso C., G.; Dias, S.M.S.; Pimenta, F.C.; et al. Phenotypic aspects of oral strains of Candida albicans in children with Down’s syndrome. Braz. J. Biol. 2006, 66, 939–944. [Google Scholar] [CrossRef] [Green Version]
  16. Maranhão, F.C.D.A.; Mendonça, N.M.; Teixeira, T.C.; Lages, G.A.D.C.S.; De Melo, J.A.; Porciuncula, C.G.G.; Filho, E.A.D.S.; Silva, D.M.W. Molecular Identification of Candida Species in the Oral Microbiota of Individuals with Down Syndrome: A Case-Control Study. Mycopathologia 2020, 185, 537–543. [Google Scholar]
  17. Sureshbabu, R.; Kumari, R.; Ranugha, S.; Sathyamoorthy, R.; Udayashankar, C.; Oudeacoumar, P. Phenotypic and dermatological manifestations in Down Syndrome. Derm. Online J. 2011, 17, 3. [Google Scholar]
  18. Shukla, D.; Bablani, D.; Chowdhry, A.; Thapar, R.; Gupta, P.; Mishra, S. Dentofacial and cranial changes in down syndrome. Osong Public Health Res. Perspect. 2014, 5, 339–344. [Google Scholar] [CrossRef] [Green Version]
  19. Areias, C.; Sampaio-Maia, B.; Pereira, M.D.L.; Azevedo, Álvaro; Melo, P.; Andrade, C.; Scully, C. Reduced salivary flow and colonization by mutans streptococci in children with Down syndrome. Clinics 2012, 67, 1007–1011. [Google Scholar] [CrossRef]
  20. Al-Maweri, S.-A.; Tarakji, B.; Al-Sufyani, G.A.; Al-Shamiri, H.M.; Gazal, G. Lip and oral lesions in children with Down syndrome. A controlled study. J. Clin. Exp. Dent. 2015, 7, e284–e288. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  21. Szaflarska-Popławska, A.; Soroczyńska-Wrzyszcz, A.; Barg, E.; Józefczuk, J.; Korczowski, B.; Grzybowska-Chlebowczyk, U.; Więcek, S.; Cukrowska, B. Assessment of coeliac disease prevalence in patients with Down syndrome in Poland—A multi-centre study. Prz. Gastroenterol. 2016, 11, 41–46. [Google Scholar] [CrossRef] [Green Version]
  22. Della Vella, F.; Lauritano, D.; Lajolo, C.; Lucchese, A.; Di Stasio, D.; Contaldo, M.; Serpico, R.; Petruzzi, M. The pseudolesions of the oral mucosa: Differential diagnosis and related systemic conditions. Appl. Sci. 2019, 9, 2412. [Google Scholar] [CrossRef] [Green Version]
  23. della Vella, F.; Contaldo, M.; Fucile, R.; Panza, F.; Dibello, V.; Kalemaj, Z.; Ninivaggi, R.; Petruzzi, M.; Serpico, R. ORO-dental manifestations in West Syndrome. Curr. Top. Med. Chem. 2019, 19, 2824–2828. [Google Scholar] [CrossRef] [PubMed]
  24. Romano, A.; Russo, D.; Contaldo, M.; Lauritano, D.; Della Vella, F.; Serpico, R.; Lucchese, A.; Di Stasio, D. Oral Manifestations in patients with glycogen storage disease: A systematic review of the literature. Appl. Sci. 2020, 10, 6720. [Google Scholar] [CrossRef]
  25. Barillari, M.R.; Karali, M.; Di Iorio, V.; Contaldo, M.; Piccolo, V.; Esposito, M.; Costa, G.; Argenziano, G.; Serpico, R.; Carotenuto, M.; et al. Mild form of Zellweger Spectrum Disorders (ZSD) due to variants in PEX1: Detailed clinical investigation in a 9-years-old female. Mol. Genet. Metab. Rep. 2020, 24, 100615. [Google Scholar] [CrossRef] [PubMed]
  26. Santoro, R.; Santoro, C.; Loffredo, F.; Romano, A.; Perrotta, S.; Serpico, R.; Lauritano, D.; Lucchese, A. Oral clinical manifestations of neurofibromatosis type 1 in children and adolescents. Appl. Sci. 2020, 10, 4687. [Google Scholar] [CrossRef]
  27. De Benedittis, M.; Petruzzi, M.; Favia, G.; Serpico, R. Oro-dental manifestations in Hallopeau-Siemens-type recessive dystrophic epidermolysis bullosa. Clin. Exp. Derm. 2004, 29, 128–132. [Google Scholar] [CrossRef]
  28. Barankin, B.; Guenther, L. Dermatological manifestations of Down’s syndrome. J. Cutan. Med. Surg. 2001, 5, 289–293. [Google Scholar] [CrossRef]
  29. CSupplement, D.; Contaldo, M.; Romano, A.; Mascitti, M.; Fiori, F.; della Vella, F.; Serpico, R.; Santarelli, A. Association between denture stomatitis, candida species and diabetic status. J. Biol. Regul. Homeost. Agents 2019, 33, 35–41. [Google Scholar]
  30. Paoletti, I.; Fusco, A.; Grimaldi, E.; Perillo, L.; Coretti, L.; Di Domenico, M.; Cozza, V.; Lucchese, A.; Contaldo, M.; Serpico, R.; et al. Assessment of host defence mechanisms induced by Candida species. Int. J. Immunopathol. Pharm. 2013, 26, 663–672. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  31. Contaldo, M.; Lucchese, A.; Lajolo, C.; Rupe, C.; Di Stasio, D.; Romano, A.; Petruzzi, M.; Serpico, R. The oral microbiota changes in orthodontic patients and effects on oral health: An overview. J. Clin. Med. 2021, 10, 780. [Google Scholar] [CrossRef] [PubMed]
  32. Groll, A.H.; Tragiannidis, A. Update on antifungal agents for paediatric patients. Clin. Microbiol. Infect. 2010, 16, 1343–1353. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Hu, L.; Zhou, M.; Young, A.; Zhao, W.; Yan, Z. In vivo effectiveness and safety of probiotics on prophylaxis and treatment of oral candidiasis: A systematic review and meta-analysis. BMC Oral Health 2019, 19, 140. [Google Scholar] [CrossRef]
  34. Contaldo, M.; Serpico, R.; Lucchese, A. In vivo imaging of enamel by reflectance confocal microscopy (RCM): Non-invasive analysis of dental surface. Odontology 2014, 102, 325–329. [Google Scholar] [CrossRef]
  35. Contaldo, M.; Lucchese, A.; Gentile, E.; Zulli, C.; Petruzzi, M.; Lauritano, D.; Amato, M.R.; Esposito, P.; Riegler, G.; Serpico, R. Evaluation of the intraepithelial papillary capillary loops in benign and malignant oral lesions by in vivo virtual chromoendoscopic magnification: A preliminary study. J. Biol. Regul. Homeost. Agents 2017, 31, 11–22. [Google Scholar]
  36. Contaldo, M.; Di Stasio, D.; della Vella, F.; Lauritano, D.; Serpico, R.; Santoro, R.; Lucchese, A. Real time in vivo confocal microscopic analysis of the enamel remineralization by casein phosphopeptide-amorphous calcium phosphate (CPP-ACP): A Clinical proof-of-concept study. Appl. Sci. 2020, 10, 4155. [Google Scholar] [CrossRef]
  37. Contaldo, M.; Della Vella, F.; Raimondo, E.; Minervini, G.; Buljubasic, M.; Ogodescu, A.; Sinescu, C.; Serpico, R. Early Childhood Oral Health Impact Scale (ECOHIS): Literature review and Italian validation. Int. J. Dent. Hyg. 2020, 18, 396–402. [Google Scholar] [CrossRef]
  38. Pastore, L.; de Benedittis, M.; Petruzzi, M.; Tatò, D.; Napoli, C.; Montagna, M.T.; Catassi, C.; Serpico, R. Importanza dei segni orali nella diagnosi di forme atipiche di malattia celiaca [Importance of oral signs in the diagnosis of atypical forms of celiac disease]. Recenti Prog. Med. 2004, 95, 482–490. [Google Scholar] [PubMed]
  39. Petruzzi, M.; Lucchese, A.; Campus, G.; Crincoli, V.; Lauritano, D.; Baldoni, E. Oral stigmatic lesions of gastroesophageal reflux disease (GERD). Rev. Med. Chile 2012, 140, 915–918. [Google Scholar] [CrossRef]
Figure 1. Flowchart summarizing the selection process.
Figure 1. Flowchart summarizing the selection process.
Applsci 11 05408 g001
Table 1. The MesHs terms used in the search and their combinations used Boolean connectors.
Table 1. The MesHs terms used in the search and their combinations used Boolean connectors.
Search TopicSearch Items (September 2020)
“Down syndrome”
OR
“21 trisomy”
ANDchildrenAND“oral diseases”
“candidiasis”
“trush”
“ulcerative lesions”
“erosive lesions”
vescicles
sores
aphtous
geographic tongue
glossitis
stomatitis
cheilitis
fissured tongue
Table 2. Main characteristics of the works included.
Table 2. Main characteristics of the works included.
First
Author, Year, Country
Type of Study OutcomeDS Diagnosis N. of
Patients Enrolled with DS
Mean Age (Range) YrSex F:M (%)Experts
Performing the Oral
Examinations
Fissured Tongue Geographic Tongue Other
Lingual/Oral Affections
Lip
Fissures, Cheilitiis
Oral Candidiadis/Candida spp. Carriage
1Ercis et al. (1996) [9], Turkeycohortmucocutaneous findings in DS childrenpartly clinical, partly chromosomal #712.83 (0.17–25)30:41 (42%:58%)dermatologistsyesyes yes
2Carlstedt et al. (1996) [11], Swedencase-controlOral carriage of Candida species
in DS children and adolescents
not specified 556.7 ± 5.3 (0.6–20.5)21:34 (38%:62%)dentist yes
3Chow et al. (1997) [12], Chinacase
report
dental and oral anomalies in one DS girlnot specified 112.5 1:0dentistyes
4Scully et al. (2002) [13], UK/Spaincohort lip lesions
and C.albicans in DS children and adults
chromosomal 77
(39 under 30 yr)
(0–>60)37:40dentist yesyes
5Ribeiro et al. (2006) [15], Brazilcase-control C.albicans phenotype in DS children chromosomal 25(0–10) dentist yesyes
6Daneshpazhooh et al. (2007) [3], Irancohort mucocutaneous findings in DS childrennot specified 10011.2
(3–20)
53:47dermatologistyesyeshypertrophy of tongue
papilla
yes
7Bilgili et al. (2011) [10], Turkeycase-controlmucocutaneous findings in DS children and healthy controlspartrly clinical, partly chromosomal501.08
(0–11)
22:28 (44%:56%)dermatologistsyesyes yes
8Sureshbabu et al. (2011) [17], Indiacohortmucocutaneous findings in DS childrenchromosomal 95 (67 up to 14 yr, 28 more than 14 yr11.97 ± 8.8
(0.5–40)
59:36dermatologist and paediatricianyes yesyes
9Arejas et al. (2012) [19], Portugalcase/controlmutans streptococci, lactobacilli and Candida
relative frequencies in saliva samples from DS children and controls
not specified 4512.7 ± 4.0 (6–18)23:22 (51%:49%)dentists Yes
10Camacho et al. (2014) [14], Spaincohortmucocutaneous findings in DS children and young adultsnot specified 5716.7
(2–29)
23:34 (39%:61%)dermatologistsyes yes
mucocutaneous findings in children with alopecia aerata and DSnot specified 1511.2
(7–16)
7:8 (47%:53%)yes yes
11Shukla et al. (2014) [18], India cohortdentofacial abnormalities in DS children and young adultsnot specified 77(6–40)7:70 (9%:91%)dentistsyes macroglossia, ankyloglossiayes
12Al-Maweri et al. (2015) [20], YemencohortLip and oral lesions in DS childrenkaryotyping5012.66
(6–18)
19:31 (38%:62%)dentistsyes herpes labialis, fibroma, traumatic ulcers yes
13Szaflarska-Popławska et al. (2016) [21], PolandcohortAphthous stomatitis and enamel hypoplasia in DS children and young adult with and without coeliac diseaseGenetic *301(1–34)137:164 (45.5%:54.5%)pediatricians aphthous stomatitis
14Maranhão et al. (2020) [16], Brazilcase-controlMolecular Identification of Candida Species in the Oral
Microbiota of Ds children and young adults
not specified8012.8 (0.5–34)31:49geneticists yes
# 9/71 (13%), clinically; 62/71(87%) chromosomal analysis (92% with trisomy-21; 6.4% with translocation type and 1.6% mosaicism). * 242 had diagnosed regular trisomy, 9 patients had translocation trisomy, in 10 patients genetic test showed mosaicism, and in 40 cases the patient’s guardians did not remember the result of the genetic test.
Table 3. Risk of bias assessment for individual studies.
Table 3. Risk of bias assessment for individual studies.
Observational StudiesBias Due to ConfoundingBias in
Participant Selection
Bias in
Classification of
Interventions
Bias Due to
Departures
from Intended
Interventions
Bias Due to
Missing Data
Bias in
Measurement
of Outcomes
Bias in
Selection of the Reported
Result
Overall Bias
Ercis et al. [9]URLRMRMRMRLRLRMR
Carlstedt et al. [11]URLRLRMRLRLRLRMR
Chow et al. [12]URMRMRMRLRLRSRMR
Scully et al. [13]URURLRMRMRLRLRMR
Ribeiro et al. [15]URURLRMRLRLRLRMR
Daneshpazhooh et al. [3]URURMRMRLRLRLRMR
Bilgili et al. [10]URURMRMRLRLRLRMR
Sureshbabu et al. [17]URLRMRMRLRLRLRMR
Arejas et al. [19]URSRLRMRLRLRLRSR
Camacho et al. [14]URURMRMRMRLRLRMR
Shukla et al. [18]URSRLRMRMRLRLRSR
Al-Maweri et al. [20]URLRLRMRMRLRLRMR
Szaflarska-Popławska et al. [21]URLRMRMRLRLRLRMR
Maranhão et al. [16]URSRSRMRMRMRLRSR
The Risk of Bias in non-randomized studies—of interventions (ROBINS-I) tool was used for observational studies. Each domain was classified as low risk (LR), moderate risk (MR), serious risk (SR), and critical risk (CR), or not interpretable (UR). An overall bias assessment was then made using the same scale.
Table 4. Fissured tongue: characteristics of the eight works investigating the prevalence of FT in children with DS, by age groups.
Table 4. Fissured tongue: characteristics of the eight works investigating the prevalence of FT in children with DS, by age groups.
Mean Age (Range) YrFissured Tongue
0–1 Years1–2 Years2–5 Years5–10 Years10–15 Years>15 YearsTotal
Ercis et al. [9]2.83 (0.17–25)1/28 (6%)0/16 (0%)5/15 (33%)9/12 (75%)15/71 (21%)
Chow et al. [12]12.5n.c.1/1 (100%)n.c.1/1 (100%)
Daneshpazhooh et al. [3]11.2 (3–20)0/8 (0%)7/33 (21%)17/50 (34%)4/9 (44%)28/100 (28%)
Bilgili et al. [10]1.08 (0–11)5/50 (10%)n.c.5/50 (10%)
Sureshbabu et al. [17]11.97 ± 8.8 (0.5–40)35/67 (52%)15/28 (60%)50/95 (53%)
Comacho et al. [14] $16.7 (2–29)n.c.40/57 (70%)44/72 (61%)
11.2 (7–16)n.c.4/15 (27%)n.c.
Shukla et al. [18] #(6–40)39/50 (78%)52/77 (68%)
Al-Maweri et al. [20]12.66 (6–18)n.c.7/9 (78%)14/21 (67%)18/20 (90%)39/50 (78%)
$—Comatcho et al. considered two groups: 57 DS subjects from 2 to 29 years, and 15 subjects with alopecia areata also affected by DS (age range 7–16). #—Shukla et al. considered 77 DS: 7 in the 1–10 years age range; 55 in the 11–20 years age range; and 15 aged between 21 and 40 years of age, but their results were not stratified by age groups. The prevalence of FT in children with DS, is reported according to the age groups considered in each study. In detail, Ercis et al. [9] considered the following age groups in years: 0–1, 1–2, 2–5, and 5–25; hence the last group of 12 subjects was aged between 5 and 25 years. Daneshpazhooh et al. [3] grouped the subjects by age as follows: 0–5, 5–10, 10–15, and 15–20 years; hence the first group of 8 subjects was aged between 0–5 years. Similarly, Bilgili et al. [10] considered a group of 50 subjects between 0–11 years; Sureshbabu et al. [17] grouped the 0–15 subjects and those >15 years; as well as Comacho et al. [14] which considered two groups of subjects between 2–29 and 7–16 years; Shukla et al. [18] did not consider results by age groups and Al-Maweri et al. [20] considered the following age groups: 5–10, 10–15, and 15–18 years. n.c.—“age groups not considered in the study”
Table 5. Lip lesions: characteristics of the eight works investigating the prevalence of lip lesions in children with DS, by age groups.
Table 5. Lip lesions: characteristics of the eight works investigating the prevalence of lip lesions in children with DS, by age groups.
CheilitisAngular CheilitisLip Fissures
Mean Age (Range) Yr0–1 Years1–2
Years
2–5 Years5–10 Years10–15 Years>15 YearsTotal0–15 Years>15 YearsTotal
Ercis et al. [9]2.83
(0.17–25)
0/28 (0%)1/16 (6.2%)0/15 (0%)3/12 (25%)4/71 (5.6%)n.c.n.c.
Daneshpazhooh et al. [3]11.2
(3–20)
0/8 (0%)6/33 (18%)6/50 (12%)1/9 (11%)13/100 (13%)n.c.n.c.
Bilgili et al. [10]1.08
(0–11)
6/50 (12%)n.c.6/50 (12%)n.c.n.c.
Sureshbabu et al. [17]11.97 ± 8.8
(0.5–40)
0/21 (0%)11/46 (24%)2/28 (7%)13/95 (14%)5/67 (7%)1/28 (3.6%)6/95 (6.3%)n.c.
Camacho et al. [14]16.7
(2–29)
n.c.16/57 (28%)27/72 (38%)0/57 (0%)
11.2
(7–16)
n.c.11/15 (73%)n.c.3/15 (20%)
Shukla et al. [18](6–40)n.c.17/77
(22%)
17/77
(22%)
n.c.
Al-Maweri et al. [20]12.66
(6–18)
n.c.7/50 (14%)7/50 (14%)n.c.32/50 (64%)
Scully et al. [13](0->60)3/11 (27%)18/66 (27%)21/77(27%)17/77
(22%)
6/24 (25%)4/24 (17%)
The prevalence of lip lesions in children with DS, is reported according to the age groups and type considered in each study. In detail, Ercis et al. [9] considered, under the term “cheilitis”, the following age groups in years: 0–1, 1–2, 2–5 and 5–25. Daneshpazhooh et al. [3] grouped the subjects with cheilitis in the following age groups: 0–5, 5–10, 10–15, and 15–20 years. Bilgili et al. [10] considered cheilitis in a group of 50 subjects between 0–11 years; Sureshbabu et al. [17] distinguished the findings of cheilitis and angular cheilitis in two groups of subjects aged 0–15 and >15 years; as well as Comacho et al. [14], that investigated angular cheilitis and lip fissures in two groups of subjects between 2–29 and 7–16 years; Shukla et al. [18] described angular cheilitis irrespective of age. Al-Maweri et al. [20] considered cheilitis in the following age groups: 5–10, 10–15, and 15–18 years. Data about angular cheilitis and lip fissures reported from Scully et al. [13] are related to 24 subjects aged between 0–20 years, grouped in 0–10 and 11–20 years, while, with regard to cheilitis, they considered 11 subjects 0–10 years and 66 between 10 and >60 years, without any further age classification. n.c.—“not considered in the study”.
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Contaldo, M.; Santoro, R.; Romano, A.; Loffredo, F.; Di Stasio, D.; Della Vella, F.; Scivetti, M.; Petruzzi, M.; Serpico, R.; Lucchese, A. Oral Manifestations in Children and Young Adults with Down Syndrome: A Systematic Review of the Literature. Appl. Sci. 2021, 11, 5408. https://doi.org/10.3390/app11125408

AMA Style

Contaldo M, Santoro R, Romano A, Loffredo F, Di Stasio D, Della Vella F, Scivetti M, Petruzzi M, Serpico R, Lucchese A. Oral Manifestations in Children and Young Adults with Down Syndrome: A Systematic Review of the Literature. Applied Sciences. 2021; 11(12):5408. https://doi.org/10.3390/app11125408

Chicago/Turabian Style

Contaldo, Maria, Rossella Santoro, Antonio Romano, Francesca Loffredo, Dario Di Stasio, Fedora Della Vella, Michele Scivetti, Massimo Petruzzi, Rosario Serpico, and Alberta Lucchese. 2021. "Oral Manifestations in Children and Young Adults with Down Syndrome: A Systematic Review of the Literature" Applied Sciences 11, no. 12: 5408. https://doi.org/10.3390/app11125408

APA Style

Contaldo, M., Santoro, R., Romano, A., Loffredo, F., Di Stasio, D., Della Vella, F., Scivetti, M., Petruzzi, M., Serpico, R., & Lucchese, A. (2021). Oral Manifestations in Children and Young Adults with Down Syndrome: A Systematic Review of the Literature. Applied Sciences, 11(12), 5408. https://doi.org/10.3390/app11125408

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