Sudan Journal of Medical Sciences
Volume 12, Issue no. 3, DOI 10.18502/sjms.v12i3.934
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Research Article

Candida albicans and Napkin Dermatitis:
Relationship and Lesion Severity Correlation
Amani Hussein Ahmed Karsani1, Abdullateef Azolaibani1,2,
Yasser Farouq1, Khalid zedan1, Mohammed Mohsen Alotaibi1,3,
Ghada Bin Saif4, and Ibrahim H. Babikir1,3

1Department of Pediatrics, College of Medicine, Qassim University, Saudi Arabia
2Department of Dermatology, College of Medicine, Qassim University, Saudi Arabia
3Department of Pathology and Laboratory Medicine, College of Medicine, Qassim University,
Saudi Arabia
4Dermatology Department, College of Medicine, King Saud University

Abstract
Introduction: Napkin Dermatitis (ND) is a common problem in infancy that affects
almost every child during the early months and years of their lifetime. It is a skin
disease that becomes a challenge for both parents and physicians because of its
frequency and difficulty in eliminating all of the causative factors in diapered infants.
Usually Napkin dermatitis is self-limiting but when associated with Candida albicans
(C. albicans) seems to be moderate to severe. Aim: The aim of the present study was
to determine the colonization of C. albicans in children with Napkin dermatitis and
to correlate between intensity of C. albicans colonization and the severity of napkin
rash. Patients and Methods: This case-controlled study was conducted at Qassim
University pediatric outpatient clinics, during the period from August 2014 to July
2015. Sixty patients with diaper dermatitis and 33 healthy controls were enrolled to
this study. Sociodemographic and clinical data were obtained from the parents of
each participant using questionnaires Paired (stool and skin) samples were collected
from all cases and healthy control children. The samples were cultured on differential
and selective chromogenic medium for isolation and initial identification of candida
species. Identification confirmation of the isolates was determined by the Vitek 2
compact automated system. Results: Diaper dermatitis shows significant outcome to
washing diaper area (per day) (P = 0.001), History of diarrhea last 7 Days (P < 0.001),
skin lab results (+/-) for Candida albicans, (P < 0.001), skin colony count, (P < 0.001),
However, there is no correlation to age (P = 0.828), gender (P = 0.368) and feeding
style (P = 0.401). Conclusion: The severity score of napkin dermatitis was significantly
observed among cases with diaper dermatitis (p-value < 0.001) and control children
(p-value < 0.001) respectively.

Keywords: Candida albicans, Napkin dermatitis, Diaper dermatitis, Vitek 2 compact
system, Qassim

How to cite this article: Amani Hussein Ahmed Karsani, Abdullateef Azolaibani, Yasser Farouq, Khalid zedan, Mohammed Mohsen Alotaibi, Ghada
Bin Saif and Ibrahim H. Babikir, (2017) “Candida albicans and Napkin Dermatitis: Relationship and Lesion Severity Correlation,” Sudan Journal of
Medical Sciences, vol. 12 (2017), issue no. 3, 174–186. DOI 10.18502/sjms.v12i3.934

Page 174

Corresponding Author: Amani

Hussein Ahmed Karsani;

email: amanikarsani@

qumed.edu.sa

Received: 15 June 2017

Accepted: 1 July 2017

Published: 4 July 2017

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Amani Hussein Ahmed

Karsani et al. This article is

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Editor-in-Chief:

Prof. Mohammad A. M.

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Sudan Journal of Medical Sciences Amani Hussein Ahmed Karsani et al

1. Introduction

Napkin dermatitis (ND), also called diaper dermatitis (DD), diaper rash, and nappy
rash. ND is one of the most common skin diseases during infancy and in toddlers [1].
Prevalence of diaper dermatitis varying under the conditions of each country and the
most commonly used diaper. The prevalence for children has been reported in the
Japan, USA, UK, and Italy 87%, 75%, 25%, and 15% respectively [2]. Diaper dermatitis
was the reason for 20% of all visits to the dermatologist of children, usually starts
within the age of the third and 12th weeks and the peak of its incidence is the age
of 6-12 months [3–5], up to the age of 5 years [6]. The highest incidence in infants is
between 9 and 12 months of age [3–5].

Conditions of DD were first noticed in the 1940s, but diapers were initially considered
to be luxury items. Thereafter, diapers began to be used on a mass scale by 1960s
[7, 8]. By then diapers were ready-made containing many layers of cellulose, which
made them more absorbent and resistant. [7, 8]. The cellulose layers can also cause
acute DD and diaper rash, especially, when it is contaminated with urine and stool
substances. Most cases of DD clear up spontaneously in a day without treatment [7, 8],
exacerbation of persistent cases (that last in 3 days or more) may be associated with
different infections, especially Candida yeasts infections [8–10].

There are, however, many causes of DD, Irritant diaper dermatitis (IDD) it is a type
of irritant contact (eczema) regarded as a localized form of contact dermatitis caused
by several factors including warmth, prolonged contact with urine and feces, and over-
hydration of the upper portion of the skin (stratum cornueum) [1, 11]. Diaper dermatitis
affecting predominantly the convex surfaces in closest contact with wet or soiled
diapers. The buttocks, genitalia, lower abdomen, and upper thighs are usually the most
severely affected, but the distribution depends on the position in which the infant is
allowed to lie. The flexures are spared, particularly in the obese child. In the mildest
forms there is only erythema, but with increasing severity, papules, vesicles, small
erosions, and larger ulcers may occur. In chronic forms scaling is combined with glazed
erythema. Scaling may be conspicuous manifest particularly in the healing stages.
Diaper dermatitis may be graded according to severity into: (i) grade 1: slight erythema,
perhaps with scaling; (ii) grade 2: moderate to severe erythema, perhaps with scaling;
or few papules and some edema (iii) grade 3: moderate to severe erythema, perhaps
with scaling, moderate to severe edema and papules, or early ulceration; and (iv) grade
4: severe erythema, perhaps with scaling, or severe edema, papules, and ulceration
[12]. There is a challenge is Candida a causative factor or it is a secondary contami-
nant that flourishes in the moist warmth environment [13]. Many experts believe that
the presence of Candida infection plays a primary as well as a secondary role in the
development of this frequently and sometimes painful eruptions [11, 14]. Candidiasis

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and Candida diaper dermatitis often complicates non infectious diaper dermatitis and
occurs as an adverse effect of oral antibiotic treatment [15].

In general, Candida exists in 3 morphological forms one of them is the yeast cells.
The dimorphic yeasts of the genus Candida are ubiquitous in the environment, how-
ever, Candida albicans causes Candidiasis in children and although it is not part of the
indigenous skin flora, but it is a frequent transient on skin and may colonize the human
alimentary tract and vaginal as a saprophytic organism [16]. Certain environmental
conditions notably elevated temperature and humidity are associated with increased
frequency of isolation of C. albicans from skin. Many bacterial species inhibit the growth
of C. albicans and the use of antibiotics, conversely, alter the normal flora and may
promote over growth of the yeast [17]. some apparently healthy infants, although,
may reveal culture positive for Candida and other organisms without exhibiting any
symptoms [14], there seems to be a positive correlation between the severity of the
diaper rash noted and the likelihood of secondary involvement [14, 18]. C. albicans was
recovered from patients with diaper dermatitis more than from normal healthy control
groups in many researches [19–21]. Gastrointestinal carriage of C. albicans assists on its
isolation from stool, skin and rectum of patients with contact dermatitis [22, 23]. It has
also been demonstrated that bacterial infection does not play a substantial part in the
development of DD [11], however, can act in synergy with bacteria such as Escherichia
coli [8, 24] and S. aureus [8, 18].

This study aimed to determine the colonization of C. albicans in children with nap-
kin dermatitis and to correlate between intensity of C. albicans colonization and the
severity of napkin rash. The role of C. albicans in diaper dermatitis has been studied in
many countries but correspondingly this issue, to the best of our knowledge, was not
studied in this country and particularly in Qassim area.

2. Subjects and Methods

A case-control study was conducted at Qassim University pediatric outpatient clinics,
during the period from August 2014 to July 2015. Institutional review board approval
was obtained from the Research and Ethical Committee of the College of Medicine and
the Deanship of Scientific Research, Qassim University, Saudi Arabia. Informed consent
was obtained from all participants.

The inclusion criteria were included erythema with or without papules, vesicles,
bulla, scales, fissures or erosions only in napkin area. Severity grades was assigned for
all patients as mild, moderate or severe [12]. The exclusion criteria were excluded all
children with immune suppression and those who had exposure to local treatment in
the anogenital area in the past 7 days. The control group was selected from children
attending for their routine and scheduled vaccination. Stool samples and skin swab

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scrapping swabs has been collected from all individuals. Sociodemographic and clinical
data were obtained from the parents of each participant using structured pre-tested
questionnaires.

2.1. Collection and Processing Specimens

Paired specimen of stool and skin swabs were collected from each participant and
directly transferred to the laboratory. In the medical laboratory, all samples were pro-
cessed for wet preparation for microscopic exam, gram stain. Samples were then cul-
tured on selective and differential media and incubated for 24-72 hours. The identifi-
cation of isolates was done according to several laboratory techniques.

2.2. Laboratory Diagnosis

2.2.1. Processing of Stool Specimens

Stool samples were collected from all cases and controls directly or using a rectal swab
(swab is inserted into the rectum and rotated gently) and then withdrawn (replaced in
its container), carefully labeled and transferred to the laboratory within 30 minutes of
collection or refrigerated (4∘C) until the time of analysis (within 12 hrs). Initially, a 0.1
ml of stool or 0.1 gm of formed stools was diluted in 0.9 ml of sterile distilled water and
serial dilutions were prepared (103 up to 108). A volume of 0.1 ml of each dilution was
spread on SDA supplemented with (0.05mg/1ml) chloramphenicol (Oxoid UK, Code:
CM0041) and incubated at 37∘C for 24-48 hrs. Suspected colonies were streaked on
CHROMagar (Watin-Biolife Cat#2020, Riyadh, Saudi Arabia) to obtain pure colonies of
C. albicans and calculated in form of CFU/gm or CFU/ml. C. albicans overgrowth was
defined as growth of ≥105 CFU/ml or gram of stool. All faecal specimens were also
examined macroscopically for morphology, consistency, colour, pH, and microscopi-
cally for pus cells, red blood cells, and presence of parasitic infections (as worm, ova,
trophozoites and cysts).

2.2.2. Processing of Skin Swab Specimens

Samples were carefully scraped from the skin region covered by the diaper for all
controls (normal skin area) and cases (from lesion rash area) by using a swab moist-
ened with sterile distilled water. The skin swabs were collected from the affected
(inguinal/peri-anal) area, replaced in its container, carefully labeled and transferred
to the laboratory along with the stool swab. In the medical lab, the skin swabs were
cultured on to SDA supplemented with (0.05mg/1ml) chloramphenicol and incubated at

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37∘C for 24-72 hrs. The subcultures were seeded into CHROMagar media and incubated
at 35∘C for 48 hrs for presumptive identification and differentiation of Candida species
and to perform colony count in a form of CFU/ml.

2.2.3. Isolation and Identification of C. albicans

The Isolation and Identification (ID) of C. albicans was done based on a combina-
tion of morphological characteristics and automation technique. The morphological
characteristics were including gram stain, colonial morphology (shape, size, texture,
etc.) and yeast structures (shape, size, budding pattern, germ tube) [5, 7, 8]. The
automation technique was done by using the fully automated VITEK-2 Compact Sys-
tem. Prior application of Vitek system, clinically significant isolates were sub-cultured
for purity on SDA plates and incubated aerobically at 35-37∘C in 5% CO.2. Isolated yeasts
were differentiated according to their colonial morphology and the colour produced
on CHROMagar [25] in addition to gram stain. Then colonies were used to prepare a
standardized saline inoculum for the appropriate VITEK ID card. Special ID and sensi-
tivity (AST) cards (BioMérieux, France) were used for identification of yeasts (YST).
The automation methods were conducted as described by the manufacturers’ manual
and techniques also described elsewhere [26]. The VITEK-2 ID and AST cards were
logged and loaded into the VITEK-2 Compact system. The VITEK-2 Compact system
automatically reported the results through software 06.01

The study has been approved by the ethics committees of the College of Medicine
Research Ethics Review Board at Qassim University and informed consent was
obtained from parents/caregiver of children.

3. Statistics

SPSS for window (version 16) was used for analyses. Students’ t-test and Chi-Square
(𝜒2) were used to compare continuous (normally distributed) data and proportions
between the cases and controls, respectively. When data were not normally dis-
tributed the Nonparametric (𝜒2 and 2-independent samples) tests were used. Binary
logistic regression was performed where the Candidiasis was the dependent variables
and clinical parameters were the independent variables. Odds ratio and 95% CI were
calculated. P-values (P < 0.05) was considered statistically significant.

4. Results

Out of 123 children with diaper dermatitis, 28 (22.7%) had been excluded because they
had incomplete data, or, not enough samples. A total of 95 children were enrolled in

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Variables Control (n =
35)

Cases (n = 60) p

Gender Male 21(60) 38 (63.3) 0.828

Feeding Style Breast
Feeding

6 (17.1%) 13 (21.7%) 0.401

Bottle Feeding 31 (88.6%) 49 (81.7%)

Diaper changing
practices

3 times/day 13 (37.1%) 22 (63.9%) 0.460

4 times/day 27 (45%) 33 (55%)

Washing diaper
area (per day)

1 time/day 3 (8.6%) 4 (6.7%)

2 time/day 9 (25.7%) 22 (36.7%) 0.001

More Than 2
time/day

23 (65.7%) 34 (56.7%)

History of
Diarrhea

Last 7 Days 20 (33.3%) 0 (0.0%) 0.001

The presence of
oral thrush

2 (5.7%) 9 (15%) 0.172

Personal history
of dermatologic
conditions

1 (2.9%) 7 (11.7%) 0.136

Family history
of dermatologic
conditions

4 (11.4%) 17 (28.3%) 0.055

T 1: Comparing N(%) of control children and cases with napkin dermatitis.

Candida species Cases (n = 60) Controls (n = 35) p

Skin No Candida 23 (38.3%) 28 (80%) <0.001
C. albicans 21 (35%) 6 (17.1%)

Other species of candidiasis 16 (26.7%) 1 (2.9%)

Stool No Candida 25 (41.7%) 24 (68.6%) <0.001
C. albicans 23 (38.3%) 9 (25.7%)

Other species of candidiasis 12 (20%) 2 (5.7%)

T 2: Distribution of C. albicans and other species of isolated from stool and skin of children with napkin
dermatitis and control participants.

the study. The cases were 60 (63.2%) children of which 38 (40%) were males, where is
35 (38.8%) were apparently healthy counterparts as controls. There was no significant
difference between the case and controls in the mean (SD) of the age 7.31 (5.144) vs.
7.28 (5.636), (P < 0.828), gender, feeding style, diaper changing practice and feeding
practice. In comparison to the controls high number of cases had less times of changing
diaper area and had family history of dermatological lesion, table 1 and figure 1.

Significantly a higher number of candidiasis was detected in skin in the cases than
in the controls. There were 21 (35%) vs 6 (17.1%), 16 (26.7%) vs. 1 (2.9%) P < 0.001
of C. albicans and other species of candidiasis in the cases and controls, respectively,
table 2.

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Variables Skin Candidiasis Stool Candidiasis

OR 95, CI P OR 95, CI P

Age 1.037 0.93−1.14 0.485 1.01 0.91−1.11 0.824
Male gender 2.409 0.94−6.15 0.066 1.53 0.60−3.92 0.368
Feeding practice 0.862 0.53−1.39 0.543 0.77 0.47−1.25 0.297
Diaper changing
practice

1.028 0.42−2.48 0.951 0.76 0.31−1.85 0.546

Washing diaper area 1.245 0.58−2.66 0.572 0.93 0.41−2.07 0.865
Oral thrush 1.190 0.23−6.09 0.835 0.45 0.07−2.72 0.388
Personal history of
skin lesion

8.431 0.79−62.1 0.087 9.19 0.78−39.5 0.078

Family history of skin
lesion

0.446 0.12−1.62 0.220 0.32 0.08−1.29 0.111

Recent history of
diarrhoea

2.470 0.82−7.42 0.107 1.89 0.63−5.64 0.251

Cases vs. controls 7.86 2.51−24.8 <0.001 3.75 1.19−7.56 0.022

T 3: Binary regression for the risk factors for skin and stool candidiasis in children with napkin
dermatitis.

 

 

 

 

 

 

Females   

(n=22, 23.2%) 

Controls (n=35, 36.8%) 

Males  

(n=38, 40.0%) 

Females  

(n=14, 14.7%) 

Males 

 (n=21, 22. 1%) 

Cases (n=60, 63.2%) 

The enrolled subjects  

(n=95, 77.3%) 

The screen subjects (n=123) 

Not fulfilled the criteria, 

incomplete data, samples 

(n=28, 22.7%) 

Figure 1: Schematic diagram of the study design.

Likewise, there were 23 (38.3%) vs. 9 (25.7%) and 12 (20%) vs. 2 (5.7%), P < 0.001 C.
albicans and other species of candidiasis in the stool of cases and controls, respectively,
table 2.

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In binary regression, while age, gender, feeding style, diaper changing practice,
feeding practice were not associated with skin or stool candidiasis, the cases were
significantly associated with skin (OR = 7.8) and stool candidiasis (3.75), table 3.

5. Discussion

The main findings of the current study were; C. albicans colonization was detected in
the stool and skin in the diaper area of both healthy children and cases with diaper
dermatitis. Skin colonization by C. albicans among cases and control was 37 (61.7) and
six (17.1%) respectively.

This finding support the hypothesis that Candida, are not generally considered to be
primary colonizers, and colonization of the diaper with Candida species occurs secon-
darily as skin damage squally [27]. Similarly, the study by D. Forbes 2001 found that,
Candida species was predominantly isolates yeast, which were identified in the stools
of 43 children (39%) with diarrhea and 26 (36%) without diarrhea. The concentration
of Candida species was positively associated with recent antibiotic use and with the
presence of another enteric pathogen, but not with patient age, nutritional status,
feeding style or duration of diarrhea.

Our findings are in concurrence with recent reports [4, 8, 9] as well as with a study
done by Martins N., et al 2014, the main predisposing factors for ND from the diaper
area including C. albicans which has been isolated most frequently, regardless of the
underlying condition of the skin [3]..

Although, C. albicans, has been widely implicated and account (80-90 %) in
moderate-to-severe ND [3, 9, 28], in contrast, other organisms are not considered
causative factors for ND [3]. Similarly, Bilal J et al 2013, the study of atopic dermatitis
(AD) has recovered various bacterial flora from the skin of infants, S. aureus coloniza-
tion was the most frequently isolated bacteria of skin lesions and non-lesional skin of
37.5% to 15% respectively [29].

Based on the clinical findings, a ND of primary reaction to acute irritation (in 1-2 days)
was diagnosed in 20 (33.3%) of cases and candidiasis was found in 12 (60%) of them
(P≤0.001). Klunk C., and his colleagues reported that, materials that made the diapers
can cause a primary reaction to irritation acute DD (diaper rash), especially, when
become contaminated with urine and stool substances, however, most of cases clear
up spontaneously in a day without treatment [7, 8], exacerbation of persistent cases
(that last in 3 days or more) may be associated with different infections, especially
Candida yeasts infections [8].

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6. Conclusion

According to the findings of this study, comparing to the control group, the severity of
napkin dermatitis score was significantly observed among children cases with diaper
dermatitis. washing diaper area per day, personal history of dermatologic conditions
history of diarrhea last seven days were more vulnerable to candidiasis and Napkin
dermatitis. However, there were no relation to age, gender, family history of derma-
tologic conditions, the presence of oral thrush, and feeding style mode.

7. List of abbreviations

DD: Diaper dermatitis, IDD: Irritant diaper dermatitis, hr: hour, SDA: Sabouraud Dextrose
Agar, CHROMagar: differential and selective chromogenic medium, ID card: identifica-
tion card, YST card: Yeast card, AST card: Antimicrobial susceptibility cards, vs.: versus,

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8. Declarations

8.1. Ethics Approval and Consent to Participate

Institutional review board approval was obtained from the Deanship of Scientific
Research, Qassim University, Saudi Arabia. Informed consent was obtained from all
subjects.

8.2. Consent for Publication

Not applicable.

8.3. Availability of Data and Materials

All the data supporting our findings are contained within this work.

8.4. Competing Interests

The authors declare that they have no competing interests.

8.5. Funding

This study was supported by grants from the Deanship of Scientific Research, Qassim
University, Saudi Arabia.

8.6. Authors’ Contributions

Amani H. Karsani, Abdullateef A. Alzolibani, Yasser Farouq and Khalid zedan carried out
the study and participated in drafting the manuscript. Mohamed ElOtaiby and Ghada
Bin Saif participated in designing the study and participated in drafting the manuscript.
IH Babikir coordinated and participated in designing the study, statistical analysis and
drafting the manuscript. IH Babikir carried out the laboratory work. All the authors read
and approved the final version.

8.7. Acknowledgements

This study was funded by the Research Deanship of Qassim University, Saudi Arabia.
We would like to thank the Deanship of Scientific Research, Qassim University, for

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approving and funding this study. The authors are very grateful to all children and
their families for their contribution and participation in the study.

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	Introduction 
	Subjects and Methods
	Collection and Processing Specimens
	Laboratory Diagnosis
	Processing of Stool Specimens
	Processing of Skin Swab Specimens
	Isolation and Identification of C. albicans


	Statistics
	Results
	Discussion
	Conclusion
	List of abbreviations
	Declarations
	Ethics Approval and Consent to Participate
	Consent for Publication 
	Availability of Data and Materials
	Competing Interests
	Funding
	Authors' Contributions 
	Acknowledgements

	References