Etiologies and characteristics of children with chief complaint of short stature

Article information

Ann Pediatr Endocrinol Metab. 2015;20(1):34-39
Publication date (electronic) : 2015 March 31
doi : https://doi.org/10.6065/apem.2015.20.1.34
1Department of Pediatrics, Severance Children's Hospital, Yonsei University College of Medicine, Seoul, Korea.
2Sowha Chidren's Hospital, Seoul, Korea.
Address for correspondence: Ho-Seong Kim, MD, PhD. Department of Pediatrics, Severance Children's Hospital, Yonsei University College of Medicine, 50 Yonsei-ro, Seodaemun-gu, Seoul 120-752, Korea. Tel: +82-2-2228-2050, Fax: +82-2-393-9118, kimho@yuhs.ac
Received 2014 September 26; Revised 2014 October 14; Accepted 2014 October 21.

Abstract

Purpose

Short stature is a very common reason for visits to pediatric endocrine clinics. It could be the first sign of an underlying disease. The purpose of this study is to investigate the etiologies and general characteristics of subjects who visited an outpatient clinic due to short stature.

Methods

We retrospectively reviewed the medical records of 3,371 patients who visited Severance Children's Hospital with the chief complaint of short stature from 2010 to 2012. Medical history, auxological data, and laboratory tests including bone age were collected and analyzed. Chromosome studies or combined pituitary function tests were performed if needed.

Results

Approximately 89.4% of the subjects with the chief complaint of short stature who visited the outpatient clinic were of normal height, and only 10.6% of subjects were identified as having short stature. Of the subject of short stature, 44.7% were classified as having normal variant short stature; that is, familial short stature (23.0%), constitutional delay in growth (17.7%), and mixed form (3.9%). Pathological short stature was found in 193 subjects (54.2%). Among pathological short stature, most common etiology was growth hormone deficiency (GHD) (38.9%).

Conclusion

A majority of children had a normal height. Among children with short stature, pathological short stature and normal variants occupied a similar percentage. GHD was the most common cause of pathological short stature and found in about 20% of the children with short stature. In pathological short stature, the height, height velocity, and IGF-1 level were lower than in normal variants.

Introduction

Short stature is defined as a height below the third percentile or more than two standard deviations below the corresponding mean height for those of the same age, sex, and race. Short stature is one of the most common causes of referral to a pediatric endocrinologist. In fact, a large number of children have visited pediatric endocrinology clinic due to short stature. This trend is based on the belief that tall men are associated with the qualities expected of successful people1). Previous studies reported that physical height and self-esteem correlated significantly, therefore, those in high-status jobs are generally believed to be taller than those in low-status jobs2). Moreover, many reports indicated that children with short stature were academically and socially handicapped2,3,4). In contrast, other studies suggested that the psychological adaptation of individuals who were shorter than average was largely indistinguishable from that of others5,6). Despite there is no evidence that short stature is associated with psychosocial stress, psychological adaption, or academic performance, social stereotype of height, such as positive attributes being linked to tallness and negative attributes to shortness, still exist. Such popular stereotypical concepts about height in our society lead to hospital visits for short stature in children7).

Short stature may be the first clinical manifestation of an underlying pathological disease, such as growth hormone deficiency (GHD), chronic diseases, or clinically defined syndromes; thus, a precise evaluation of short stature is crucial. Although most children with short stature are assessed as being healthy even after evaluation, careful monitoring of growth status (e.g., measurement of height, weight, and growth velocity) over time is essential for child healthcare. Short stature is a result of various etiologies, which are categorized as pathological causes and normal variants. Normal variant short stature consists of familial short stature (FSS) and constitutional growth delay (CGD), while pathological causes are subdivided into endocrine diseases, clinically defined syndromes, chronic diseases, metabolic diseases and others8). Recently, clinicians have classified normal variant short stature as one type of idiopathic short stature (ISS), of which a diagnosis can be made after excluding the evidence of systemic, endocrine, nutritional, or chromosomal abnormalities. In addition, proper classification and precise diagnosis of short stature are essential to determine whether growth hormone (GH) treatment is needed or not.

The aim of this study is to determine the etiological profile and distribution of the patients who visited an outpatient clinic to evaluate short stature.

Materials and methods

1. Subjects

This study is based on the retrospective analysis of the data of 3,664 children who were evaluated for short stature at the Department of Pediatrics, Severance Children's Hospital, Yonsei University College of Medicine, from January 2010 to December 2012. Patients who had a follow-up period less than 1 year were excluded. Accordingly, 293 patients were excluded and 3,371 patients were analyzed.

2. Methods

Short stature was defined as a height below the third percentile for the corresponding age and gender in a Korean growth chart that was revised in 2007, and etiological categorization was based on Ranke MB's classification8). We collected data on the patients' medical history (age, sex, intrauterine period, birth weight, yearly growth rate (YGR), midparental height (MPH), medication history, admission history, and outpatient history), physical findings (height, weight, upper/lower ratio, Tanner staging, and any abnormal findings), and laboratory tests. Primary screening tests including complete blood count, routine chemistry, T3, free T4, thyroid-stimulating hormone, insulin-like growth factor-I (IGF-I), insulin-like growth factor binding protein-3 (IGFBP-3), and urine analysis were performed. Bone age was estimated through left hand X-rays using the Greulich-Pyle method9) performed by the same observer. Predicted adult height (PAH) was estimated using the Bayley-Pinneau method10). In subjects whose heights was below the third percentile for the same age and sex and growth velocity was attenuated, combined pituitary function tests and brain magnetic resonance imagings were performed. Additionally, chromosome studies were done in female patients with short stature below the third percentile.

FSS was attributed to a patient with a normal birth height and weight, a MPH below tenth percentile, a normal YGR, and a bone age appropriate for their chronologic age. CGD was attributed to a patient with a normal birth height and weight, a MPH above tenth percentile, a normal YGR, and a delayed bone age one to two years. GHD attributed to a patient whose GH levels were less than 10 ng/mL after stimulation in two kinds of GH provocation tests, such as insulin tolerance test and L-dopa test8). Diagnosis of ISS was made after evidence of systemic, endocrine, nutritional or genetic abnormalities was not found.

3. Statistical analysis

Statistical analysis of the results was performed using IBM SPSS Statistics ver. 20.0 (IBM Co., Armonk, NY, USA). All data was expressed as mean±standard deviation. Chi-square and t-test distributions were performed for between-pairs comparisons, and comparisons among groups were performed using analyses of variances. Differences were regarded as significant when P<0.05.

Results

1. Frequency of children with chief complaints of short stature

Among 3,371 subjects, 3,015 (89.4%) had a normal height and 356 (10.6%) had short stature below the third percentile in the growth chart (Table 1). Of those with short stature, 159 (44.7%) were normal variants, 193 (54.2%) had pathological short stature, and 4 patients (1.1%) were uncategorized (Table 2). In the group of normal variants, there were 82 patients (23.0%) with FSS, 63 patients (17.7%) with CGD, and 14 patients (3.9%) who had both. In the uncategorized group, 2 patients were suspected of having GHD because of attenuated growth and low levels of IGF-I and IGFBP-3 (patient 1: -0.6 SDS IGF-I, -1.3 SDS IGFBP-3; patient 2: -0.5 SDS IGF-I, -1.1 SDS IGFBP-3). While follow-ups without GH provocation tests, these cases were missing.

Frequency of children with chief complaints of short stature

Frequency of the various diagnoses of the children with short stature

Fig. 1 showed the distribution curve of the children's height. Of the children with normal heights, 1,196 (39.7%) had a SDS of -2 to -1, and 1,015 (33.7%) had a SDS of -1 to 0. These findings suggest that most children with normal heights (73.3%) who visited the hospital due to short stature had heights less than the average, with a SDS of -2 to 0.

Fig. 1

Distribution of height standard deviation score (SDS) of the children with chief complaint of short stature.

2. Frequency of the various diagnoses of the children with pathological short stature

Of the patients with pathological short stature, the most common cause was GHD (38.9%), followed by ISS (23.2%), small for gestational age (11.3%), and Turner syndrome (9.3%) (Table 3). The others (12.4%) were considered to have diverse etiologies, such as clinically defined syndromes, skeletal dysplasias, metabolic disorders, and chronic renal failures. GHD was diagnosed in approximately 20% of children with short stature.

Frequency of the various diagnoses of the children with pathological short stature

3. Causes of short stature in patients with GHD

Of the patients with GHD, 21 patients (28.0%) had morphological brain abnormalities or underlying diseases, and 54 patients (72.0%) had no specific brain lesions (Table 4). Of the 21 patients with organic GHD, Rathke's cleft cyst (9.3%) and hypoxic brain damage (9.3%) were the most common causes, followed by small pituitary glands (4.0%), pituitary tumors (2.7%), microcephaly (1.3%), and Arnold-Chiari malformation (1.3%).

Table 4. Causes of short stature in patients with growth hormone deficiency (GHD)

4. Auxological characteristics of the patients with FSS, CGD and pathological short stature

Children with FSS showed the least bone age (BA) delay, the lowest MPH SDS, normal growth velocity and the highest IGF-1 level, whereas CGD children had the lowest BMI, the most BA delay, normal growth velocity, and the highest PAH SDS. Children with pathological short stature were significantly shorter, and had the lowest height velocity, height velocity SDS and IGF-I level (Table 5).

Auxological characteristics of children with normal variant and pathological short stature

5. Frequency of the various diagnoses according to severity of short stature

The patients were categorized according to the severity of their short stature in two groups, that is those with a height SDS of ≤-3 and those with a height SDS of >-3. A total of 101 (43 boys and 58 girls) (28.4%) presented very short stature; that is, their height SDS was ≤-3, and 255 patients (129 boys and 126 girls) (71.6%) presented less severe short stature; that is, a height SDS of >-3. Even though it was not significant statistically, the most common diagnosis in the very short children was GHD (20.8%), whereas the most common diagnosis in the less severely short children was FSS (25.1%). CGD is more common in less severely short children than in very short children, while clinically defined syndromes are significantly more common in very short children than in less severely short children (Table 6).

Diagnosis according to severity of short stature

Discussion

In this study, we presented auxological characteristics and distributions of various diagnoses of short stature in children who visited a pediatric endocrinology clinic due to short stature in a 3-year period. The majority of the children who visited the outpatient clinic had normal heights, while only 10.6% of the children were identified as having short stature. The percentage of patients with normal heights in this study (89.4%) was higher than in a previous Korean report by Kim and Yoo11) (62.2%). This finding suggests that more children who visited hospital with normal heights, which may suggest that the popular stereotypical preference for tall statures has intensified, or simply reflect the differences in hospital characteristics or locations, even though both involved the same tertiary hospital. In fact, 76.1% of the patients with normal heights were below the 50th percentile, suggesting that shorter patients within the normal range tended to visit outpatient clinics more often.

In the short stature group in our study, the percentage of patients with pathological short stature (54.2%) was higher than that of patients with normal variants (44.7%).Previous studies 11,12,13,14,15) have demonstrated that most children with short stature are normal variants, and may constitute more than 65% of short stature children. The reason for the discrepancy between this study and others is unclear, however, there is a possibility of referral bias in tertiary hospitals.

In the pathological short stature group in this study, GHD was the most common cause of short stature (38.9%), followed by ISS (23.2%), small for gestational age (11.3%), Turner syndrome (9.3%), and others. High prevalence of GHD as a cause of short stature has been reported in almost all previous studies. In our study, GHD was diagnosed in approximately 20% of the children with short stature, which is similar to the 22.8% in Zargar et al.15). and the 23.4% in Moayeri and Aghighi16). In contrast, other studies11,12,13) showed GHD occurred in 11.1%-13.0% of short stature cases, which is less than in our study. Even though most GHD is idiopathic, 28% of GHD cases revealed organic abnormalities, such as Rathke's cleft cysts17), small-sized pituitary glands, pituitary tumors or other anatomic abnormalities, suggesting that comprehensive evaluations for combined morbidities or anatomical abnormalities are required for patients with GHD.

As expected, the comparison of the auxological characteristics of FSS, CGD, and pathological short stature confirmed these findings: (1) The height velocity and height velocity SDS are lowest in pathological short stature; (2) the bone age delay is lowest in FSS; (3) the MPH SDS is lowest in FSS; (4) the PAH SDS is normal in CGD; (5) the IGF-I level is lowest in pathological short stature.

The heights of those with pathological short stature were shorter than those for normal variants; therefore, physicians should evaluate the possibility of pathologic diseases more carefully when the patients have lower height SDS within the short stature group. In our study, children with a very short stature (that is, height SDSs of ≤-3) were more likely to have pathological short stature. Normal variants were present in about 49.4% of children with less severe short stature (that is, height SDSs of >-3), while in only 32.6% of the very short children. These results are comparable with a previous report by Papadimitriou et al.13) that also showed there were more normal variants in less severe groups than in very short stature ones.

In conclusion, a careful monitoring of growth and a precise evaluation of short stature are very important to discover the pathologic causes and determine whether GH treatment is needed18). Our data shows that only 10.6% of the children with chief complaint of short stature were identified as having short stature. Approximately 54% of children of short stature presented pathological short stature, whereas normal variants were diagnosed in about 45% of the short children. GHD was the most common cause of pathological short stature, and was found in approximately 20% of the children with short stature.

Notes

Conflict of interest: No potential conflict of interest relevant to this article was reported.

References

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Article information Continued

Fig. 1

Distribution of height standard deviation score (SDS) of the children with chief complaint of short stature.

Table 1.

Frequency of children with chief complaints of short stature

Category No. of subjects (%)
Normal (>3 percentile) 3,015 (89.4)
Short stature (<3 percentile) 356 (10.6)
Total 3,371 (100)

Table 2.

Frequency of the various diagnoses of the children with short stature

Diagnosis No. of subjects (%)
Normal variants 159 (44.7)
Familial short stature 82 (23.0)
CGD 63 (17.7)
Familial short stature and CGD 14 (3.9)
Pathological short stature 193 (54.2)
Uncategorized 4 (1.1)
Total 356 (100)

CGD, constitutional delay in growth.

Table 3.

Frequency of the various diagnoses of the children with pathological short stature

Diagnosis No. of subjects (%)
Growth hormone deficiency 75 (38.9)
Idiopathic short stature 45 (23.2)
Small for gestational age 22 (11.3)
Turner syndrome 18 (9.3)
Congenital heart disease 6 (3.1)
Noonan syndrome 4 (2.1)
Anemia 4 (2.1)
Hypochondroplasia 3 (1.5)
Rickets 3 (1.5)
Russel-Silver syndrome 2 (1.0)
Cancer 2 (1.0)
Precocious puberty 2 (1.0)
Scoliosis 1 (0.5)
Skeletal dysplasia 1 (0.5)
Mitochondrial cytopathy 1 (0.5)
Chronic renal failure 1 (0.5)
Hypothyroidism 1 (0.5)
DM 1 (05)
Choledochal cyst 1 (0.5)
Total 193 (100)

DM, diabetes mellitus.

Table 4.

Table 4. Causes of short stature in patients with growth hormone deficiency (GHD)

Diagnosis No. of subjects (%)
Idiopathic GHD 54 (72.0)
Organic GHD 21 (28.0)
Rathke’s cleft cyst 7 (9.3)
Hypoxic brain damage 7 (9.3)
Small size of pituitary gland 3 (4.0)
Pituitary tumor 2 (2.7)
Microcephaly 1 (1.3)
Arnold chiari malformation 1 (1.3)
Total 75 (100)

GHD, growth hormone deficiency.

Table 5.

Auxological characteristics of children with normal variant and pathological short stature

Variable FSS (n=82) CGD (n=63) Pathologic SS (n=193) P-value
Age (yr) 10.21±5.28 8.23±3.63 7.42±3.90 <0.001
Sex, male/female 24/58 38/25 103/90 <0.001
Height SDS –2.66±0.58 –2.51±0.45 –2.92±0.85 <0.001
Body mass index (kg/m2) 18.01±3.39 15.75±2.64 16.33±2.86 <0.001
Bone age delay (yr) 0.50±0.88 1.80±0.72 1.73±3.12 <0.001
Height velocity (cm/yr) 4.47±2.51 4.78±1.27 3.92±1.83 0.006
Height velocity SDS 0.07±1.70 –0.32±1.49 –1.14±1.70 <0.001
MPH SDS –2.09±0.39 –0.57±0.64 –0.67±0.97 <0.001
PAH SDS –3.38±5.40 –0.78±1.13 –2.56±0.37 0.004
IGF-I (ng/mL) 208.38±17.97 161.30±82.92 135.23±83.21 <0.001
IGFBP-3 (μg/mL) 2.24±0.58 2.15±0.65 2.02±0.70 0.086

Values are presented as mean±standard deviation.

FSS, familial short stature; CGD, constitutional delay in growth; SS, short stature; SDS, standard deviation score; MPH, midparental height; PAH, predicted adult height.

Table 6.

Diagnosis according to severity of short stature

Diagnosis Height SDS≤–3 Height SDS>–3 P-value
Familial short stature 18 (17.8) 64 (25.1) 0.142
CGD 9 (8.9) 54 (21.2) 0.006
Familial short stature + CGD 6 (5.9) 8 (3.1) 0.220
Growth hormone deficiency 21 (20.8) 54 (21.2) 0.936
Idiopathic short stature 15 (14.9) 30 (11.8) 0.429
Clinically defined syndromes 15 (14.9) 9 (3.5) <0.001
Small for gestational age 8 (7.9) 14 (5.5) 0.391
Disorders in specific systems 2 (2.0) 12 (4.7) 0.365
Skeletal dysplasias 4 (4.0) 4 (1.6) 0.230
Endocrine disorders (non-GHD) 1 (1.0) 3 (1.2) 1.000
Others 2 (2.0) 3 (1.2) 0.625
Total 101 (100) 255 (100)

Values are presented as number (%).

SDS, standard deviation score; CGD, constitutional delay in growth; GHD, growth hormone deficiency.