1. Introduction
Hirschsprung’s disease (HSCR), or congenital aganglionic megacolon, occurs in approximately 1 in 5000 of all live-born infants. This disease occurrs because of the absence of the ganglion plexus in the large intestine, which causes the large bowel to lose its ability for dilation or peristalsis resulting in intestinal obstruction [
1].
Patients with HSCR could develop obstructive symptoms days after birth such as the delayed passage of meconium (failure to pass first meconium within 48 h of life), abdominal distention, constipation, bilious vomiting, failure to thrive, and absence of flatus. Some studies [
2,
3] define common clinical manifestations as a “classic triad” including delayed passage of meconium, abdominal distention, and vomiting. Physical examination shows signs of malnutrition such as low height and weight. Increased rectal tone and explosive stool after rectal examination are characteristic of HSCR. In some cases, HSCR could have severe complications such as Hirschsprung-associated enterocolitis, resulting in intestinal perforation and sepsis as a presentation.
The diagnosis of HSCR comprised of clinical presentations, physical examination together with other investigations such as abdominal plain film, contrast enema, anorectal manometry, and a rectal biopsy. A contrast enema is commonly used for initiating investigations in HSCR-suspected patients due to its high sensitivity and its availability in most healthcare centers. However, there are various sensitivities and specificities of contrast enema in other studies; thus, further investigations must be performed to give a diagnosis [
4,
5,
6]. Anorectal manometry usually needs special instrument to be performed. The sensitivity and specificity are also not as high as a rectal biopsy.
Rectal biopsy is the most specific and representative in diagnosis of HSCR. Two biopsy techniques are commonly performed. The first one is a full-thickness rectal biopsy, which could be performed in a surgical setting and is an acceptable reference standard test to diagnose HSCR. The second newer and less invasive technique, rectal suction biopsy (RSB), can be interpreted if there is an adequate specimen. According to the European Reference Network for rare inherited and congenital digestive disorders (ERNICA) guideline, rectal histology is required for diagnosis. Both techniques are accurate if adequate submucosal tissue is included [
7]. The less invasive procedure, which is rectal suction biopsy, should be considered first. A diagnosis of HSCR is given if the specimen shows an absence of ganglion cells in the hematoxylin and eosin stain or a special immunohistochemistry study, such as acetylcholine esterase or calretinin stain, which shows an aganglionic segment [
8]. Some studies [
3,
9] proposed performing a rectal biopsy in patients with signs of abdominal obstruction including the following: delayed passage of meconium, abdominal distention, and vomiting, along with positive findings from other investigations to avoid unnecessary invasive procedures. On the other hand, some studies [
10,
11] recommended performing a rectal biopsy in every patient with suspected HSCR despite a high rate of negative results, because many HSCR patients presented with only one symptom and late diagnosis could increase the risk of developing life-threatening complications.
However, without the results from a rectal biopsy, it could be difficult to diagnose HSCR, because some intestinal obstructive conditions manifest similarly to HSCR, such as meconium plug syndrome, anorectal malformation, malrotation, intestinal atresia, and meconium ileus associated with cystic fibrosis [
2]. In addition, some non-obstructive conditions, such as allergic proctitis [
12,
13], lactase deficiency, celiac disease [
2,
13,
14], cow’s milk allergy [
2,
13], hypothyroidism [
2,
15], and enterocolitis, could also mimic HSCR.
The other group of conditions, called variants or allied disorders of Hirschsprung’s disease [
16], show a close resemblance to HSCR in terms of clinical presentations and findings from the investigations, although the ganglion cells are present in the biopsy. The examples are intestinal neuronal dysplasia, intestinal ganglioneuromatosis, isolated hypoganglionosis, immature ganglia, absence of the argyrophilic plexus, internal anal sphincter achalasia, and megacystis microcolon intestinal hypoperistalsis syndrome.
In our study, the diagnosis of HSCR was still challenging in the remote hospital with no complete investigation options. There was no specific protocol to refer suspected HSCR patients for further investigation. Either delayed diagnosis or over-investigation could occur. The mode of diagnosis was comprised of clinical evaluation, plain abdominal radiography, contrast enema, and rectal biopsy. This study aimed to help the remote hospital to screen the clinical presentation for diagnosing HSCR and for the early referral of the suspected patient to the center that could perform further investigation.
2. Materials and Methods
This study was designed as a retrospective cohort study with approval from the Research Ethics Committee, Faculty of Medicine, Chiang Mai University (Study code: SUR-2563-07500) with an exemption from patient informed consent due to the full retrospective study.
2.1. Participants
The data were collected from patients with suspected HSCR in Chiang Mai University Hospital that were presented from 2006 to 2020 and recorded in the database. Clinically suspected HSCR in this study included abdominal distension, constipation, vomiting, or plain abdominal radiography that showed large bowel dilation with no gas presented in rectum. The participants included patients with clinically suspected HSCR less than 15 years old at the date of consultation. The participants needed to have at least one clinical presentation suggesting HSCR and underwent either contrast enema, rectal biopsy, or curative surgery.
Patients diagnosed with HSCR with a colostomy from the previous hospital lacked initial clinical presentations of HSCR; thus, these patients were excluded from this study. Patients with an anorectal malformation, which is congenital anatomical anomalies that also cause bowel obstruction symptoms, except for anal stenosis, were excluded from this study because HSCR could simply be ruled out by physical examination. Patients lost to follow-up during the procedure were also excluded due to an unknown final diagnosis.
2.2. Outcome
The participants were diagnosed with HSCR if results from operative specimens, assessed by experienced pathologists, showed the absence of ganglion cells in the distal bowel. The non-Hirschsprung’s disease group (non-HSCR) consisted of participants whose ganglion cells were present or calretinin positive in the rectal biopsy specimen with no recurrence of clinical presentations after six months of follow-up. Some participants who underwent surgery in the early years of the study and had ganglion cells present in operative specimens were included in the non-HSCR group because of inadequate evidence to be HSCR.
2.3. Predictors
Parameters recorded in this study were categorized into the following three groups: general information, clinical presentations, and physical examinations.
The general information group consisted of age, prematurity, gender, and Down’s syndrome. Participants defined as term had a gestational age more than or equal 37 weeks [
17].
Clinical presentations of patients included the history of delayed passage of meconium at 48 h, abdominal distention, constipation, history of enterocolitis, and vomiting.
The physical examination group consisted of weight and results of per-rectal examinations including increased rectal sphincter tone and explosive stool after the examination. Weight was converted to weight-for-age percentile according to the World Health Organization growth standard [
18]. Failure to thrive was defined by the patient’s weight being less than the 5th weight-for-age percentile [
19]. However, the cut-off point of the weight-for-age percentile in the predictive models was determined later on the basis of the power of prediction.
2.4. Sample Size
The sample size was calculated on the basis of the sensitivity of the statistically significant parameter, which was 81.1% of the parameter age less than three years old, as provided from the previous study [
20]. With the significance level (α) of 0.05 and the maximum marginal error (d) of 0.05, the number of approximate sample sizes in this study was 421.
2.5. Missing Data
The multiple imputation methods were used for the imputation of the missing listed parameters, which were term, history of delayed passage of meconium at 48 h, and history of enterocolitis (missing at 102, 175, and 300 out of 483 participants, respectively).
2.6. Additional Data
The additional investigations consisted of results from contrast enema, rectal suction biopsy, and full-thickness biopsy specimen. As anorectal manometry was only recently available in the institution, the result of anorectal manometry was not included in this study. Transitional zone [
21], jejunization, saw-tooth appearance, reverse rectosigmoid ratio (<1), and delayed evacuation in 24 h were collected as contrast enema signs. The contrast enema result was assessed by a radiologist to determine whether the results suggested HSCR. The outcome of the rectal suction biopsy was pathologic results with the addition of calretinin marker. In addition, some of the investigations were not performed but the data were also included in this study. This information was added in this study to compare the result with the developmental predictive model.
2.7. Statistical Analysis
Statistical analysis was performed with commercial statistical software (STATA 16.0; StataCorp LP, College Station, TX, USA). Categorical descriptive statistics were presented by count and percentage. Continuous descriptive statistics were presented by the mean and standard deviation or median and interquartile range (IQR) according to data distribution. Categorical analytic statistics were calculated from Fisher’s exact test. Continuous analytic statistics were calculated from Student’s t-test or Mann–Whitney U Test. The significance level in this study was 0.05.
Multivariable analysis was done by logistic regression reported by diagnostic odds ratio (dOR). Various combinations of significant clinical parameters listed above that had a univariable p-value < 0.01 were selected in the model and removed by the stepwise method to retrieve all significant predictive parameters in the developed model.
Total of 5 parameters were used in the reduced model. The assigned score was done by transforming the regression coefficient of dOR. Total score of 1–7 was derived from the model with the cut-off point of 4 to achieve the high true positive rate (sensitivity) to promote active referrals of the suspected patient. The likelihood ratio of positive values for diagnosing HSCR was presented.
The receiver operating characteristic (ROC) curve, and area under the ROC curve (AuROC) were calculated to derive the discriminative potential of the model. Hosmer–Lemeshow goodness of fit statistics and a calibration plot comparing the agreement of the observed and expected score values were also presented. The bootstrapping procedure with 200 replicates was executed for internal validation of the model.
The diagnostic indices of the predictive model, contrast enema, and rectal suction biopsy were calculated including sensitivity, specificity, negative predictive value (NPV), and positive predictive value (PPV). The AuROC of the combination of the model with the investigation was presented.
3. Results
First, data on 765 participants with suspected HSCR were collected. Then, 483 were included in the final analysis, as shown in
Figure 1. Of the included participants, 194 (40.2%) were female and 289 (59.8%) were male. The median age of presentation was 37 days (IQR = 20.0–112.0). Overall, 314 out of 381 (82.4%) patients were term. Additionally, 13 (3.7%) out of 349 participants had down’s syndrome.
The participants were divided into two groups including 207 (42.86%) patients diagnosed as HSCR and 276 (51.14%) patients categorized in the non-HSCR group. There were seven patients diagnosed with total colonic aganglionosis within the HSCR group.
In the non-HSCR group, definitive diagnoses were identified in 110 out of 276 participants. The majority were constipation (63, 57.3%), anal stenosis (9, 8.2%), enterocolitis (5, 4.5%), hypothyroidism (2, 1.8%), and other diagnoses (31, 28.2%). Some other diagnoses identified were meconium plug syndrome, intestinal atresia, lactase deficiency, malrotation, inguinal or umbilical hernia, and overfeeding. The remainder had an uncertain diagnosis.
The general characteristics of the participants were shown in
Table 1. The parameters that showed univariable statistical significance for diagnosing HSCR were age, term, percentile weight for age, male gender, and history of delayed passage of meconium. The number of the participants that provided the univariable data are also presented in
Table 1.
Multivariable logistic regression was done. Parameters were selected in the model as defined in method. The regression coefficient, diagnostics odds ratio (dOR), and 95% confidence interval (CI) are shown in
Table 2. An age less than 1 month, male gender, term, history of delayed meconium passage, and history of enterocolitis were included in the model. The item scoring scheme for diagnostic parameters for HSCR derived from coefficients is shown in
Table 3. The assigned score ranged from 0 to 7 points, which categorized the patients into two risk groups with a cut-off point of 4, as shown in
Table 4. The score of low-risk group for being HSCR was 0 to 3 points, while patients with 4 to 7 points were likely to be HSCR. The ROC curve of the clinical score model is shown in
Figure 2, which shows the performance of the model. The area under the receiver operating characteristics curve (AuROC) of the clinical score model showed a prediction affinity of 72%, while the full model with five parameters achieved a prediction affinity of 76%.
The Hosmer–Lemeshow goodness of fit statistics test was done for the five parameters model and the clinical score model without statistically significant results (p-value = 0.056 and 0.790 respectively). The clinical score model was fit for diagnostic prediction of HSCR in this dataset.
The calibration of the model is shown in
Figure 3, which compared the observed risk with the score predicted risk of HSCR diagnosis. The score of 4 and more was likely to diagnose of HSCR, and promptly, a referral was suggested to screen the patient to further investigate. The investigations for HSCR, which were contrast enema and rectal suction biopsy, are shown in
Table 5.
Internal validation was done by the bootstrapping method, which showed a consistent AuROC 0.763 ± 0.021 with model optimism at 0.008 (range from −0.041 to 0.068).
By the added value concept, the ROC curves with AuROC of the three models are shown in
Figure 4. The ability to predict HSCR of clinical score model was 72%. With the addition of contrast enema, the predictive model’s ability to predict HSCR was increased by 15%. Further addition of contrast enema plus rectal suction biopsy made the predictive model’s ability to predict HSCR further improved by 25%, thereby creating a predictive model with a 97% ability to predict HSCR.
Diagnostic values of each parameter are shown in
Table 6. Among the clinical score model, contrast enema, and rectal suction biopsy, the parameter that showed the highest sensitivity for diagnosing HSCR was contrast enema and the highest specificity for diagnosing HSCR was the rectal suction biopsy. The clinical score model, which used a cut-off point of 4, was used as a tool for screening with a sensitivity of 80.7% and a specificity of 51.8%. Promptly referring patients for further investigation was advised to avoid delayed diagnosis from clinical observation. However, the patients who were classified as low risk of HSCR should still be monitored and referred when no clinical improvement is seen.
4. Discussion
Many conditions could mimic HSCR and confuse clinical practice with a high number of clinically suspected HSCR patients. To make the diagnosis, clinical presentation, physical examinations, and investigations were needed. In the remote hospital, the diagnostic tools available were limited. Some areas have no option for contrast enema or rectal suction biopsy. For this reason, we aspired to find diagnostic clinical parameters for predicting HSCR. In some situations, performing a rectal biopsy in every case might be an over-investigation, as the result from this study showed that more than half of suspected HSCR patients were not diagnosed with HSCR. However, under-investigation could lead to serious complications.
Patients with suspected HSCR were likely to be presented during the neonatal period [
22,
23,
24]. Furthermore, the onset of clinical presentation may vary in the individual through the age of five years old. In this study, the age cut-off point of being lower than one month old can predict HSCR, as patients older than one month usually presented because of other conditions. In our study, these conditions were constipation, anal stenosis, and enterocolitis. However, in patients younger than one month, lactase intolerance was also possible. On the contrary, a previous study [
19] of the diagnostic tests for HSCR used a cut-off age at three years old. The pathophysiology of HSCR is congenital in origin. The earliest age from the analysis was chosen, so the cut-off point of age at one month was reasonably considered as our predictor and aid for the early treatment.
The number of male HSCR patients was more than females with a male-to-female ratio of 2.63:1 in our study, which was slightly lower than the normal ratio of HSCR that was 3:1 to 4:1 [
23,
25,
26]. The results from data analysis showed male gender as one of the predictors, which was consistent with the theory.
The weight-for-age percentile in HSCR patients was significantly low compared to non-HSCR patients, as the symptoms of bowel obstruction in HSCR could interrupt growth development and cause insufficient weight gain. However, past studies [
27,
28] seldom mentioned the weight-for-age percentile as the parameter representing growth in HSCR patients. Moreover, the currently favored definition of failure to thrive, which was weight-for-age less than P5, might not be an appropriate parameter to diagnose HSCR, as HSCR patients were likely to present during the neonatal period when growth was not affected as much.
The proportion of HSCR patients who had a history of delayed passage of meconium at 48 h was significantly higher than non-HSCR patients, which is the same as the results of most studies. Hence, a history of delayed passage of meconium is one of the classic triad symptoms to diagnose HSCR [
1,
3,
7,
29]. With the highest specificity (81.5%) among clinical parameters, the history of delayed passage of meconium was an important factor to consider for further investigation. However, there were still a few non-HSCR patients with a history of delayed passage of meconium.
Most of the reports have shown that HSCR patients were likely to occur in term infants. In 2018, the study in California reported the median gestational age at birth was 38 weeks and 6 days [
30]. In our study, term infants had very high sensitivity with non-specific parameters for the diagnosis of HSCR.
Enterocolitis was also a presentation and postoperative unfavorable outcome of HSCR. The presence of preoperative enterocolitis was associated with the longer segment and inadequate rectal irrigation [
31]. In our study, the presence of enterocolitis was shown as the highest effect size parameter with a dOR of 2.42. However, there was a limitation of missing data. Some of the infants with enterocolitis might not be associated with HSCR.
The results from the contrast enema in this study were consistent with some previous studies [
20,
21,
29], with a sensitivity of 89.00% (83.82–92.98%) and specificity of 72.32% (66.59–77.57%). All the contrast enema signs included in this study showed statistical significance in diagnosing HSCR except jejunization, which can be correlated to the infection. The most common sign in HSCR patients was transitional zone (75.4%), which is the finest clue to diagnose HSCR from contrast enema results [
6].
The sensitivity and specificity of RSB were 87.50% (67.64–97.34%) and 98% (89.35–99.95%), respectively, which was consistent with other studies [
32,
33]. Therefore, RSB is the investigation that can be performed without anesthesia and no rectal scarring left while performing a definite operation, which could be helpful and cost-effective to the patient. However, the RSB needs the equipment and specialized pathologist to interpret the results. So, the clinical diagnosis is still important.
There was a previous clinical prediction model for diagnosis of HSCR [
20]. In 2013, the previous score was combined between the clinical risk factors (delayed passage of meconium, age less than 3 years, and male gender) and the investigations that were anorectal manometry, contrast enema, and rectal biopsy. In our clinical score model, we added two more factors that were term infant and previous history of enterocolitis. The age in our study was less than 1 month with the reason stated above. We also obtained a sensitivity of 80.7% without the investigations, which were not available in some areas. This is the screening score to help in early referrals with a shortened time of clinical observation.
The results from data analysis in this study showed high sensitivity of the contrast enema and high specificity of the rectal suction biopsy. Therefore, contrast enema was more appropriate to be used in screening. The result from the contrast enema was also helpful in further surgery to locate the transitional zone. However, due to the high false-positive rate (75/471; 27.7%) and false-negative rate (22/471; 11.0%), subsequently confirming the HSCR diagnosis with rectal suction biopsy was needed. In our study, the addition of contrast enema and rectal suction biopsy improved the area under the ROC curve of clinical parameters only in combination, from 72% to 87% and 97%, respectively. Therefore, the recommendation for the management of patients with suspected HSCR was to screen with clinical parameters first, followed by contrast enema and rectal suction biopsy.
Because this study was retrospective, there were limitations in controlling factors and data collection. The data analysis did not include results from the other two frequently used investigations, which were abdominal plain film and anorectal manometry. The abdominal plain film result was not included because nearly all participants showed bowel dilatation and absence of air in the rectum as the study domain of this study, as well as some of the clinical features such as abdominal distension and vomiting. Anorectal manometry was not included because of recent availability, which also made it difficult to diagnose ultrashort HSCR. A rectal suction biopsy was available in our institute three years ago. Before that, diagnosing HSCR mostly depended on clinical presentations and contrast enema, so some patients had ganglion cells in operative specimens. In the early years, there was also difficulty in differentiating variants of HSCR because of the pathologic understanding of the spectrum of disease.