Pituitary Morphology and Function in 43 Children with Central Diabetes Insipidus

Liu, Wendong; Wang, Limin; Liu, Minghua; Li, Guimei

doi:https://doi.org/10.1155/2016/6365830

International Journal of Endocrinology

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Abstract Introduction Materials and Methods Results Discussion References Copyright Related Articles

Research Article | Open Access

Volume 2016 | Article ID 6365830 | https://doi.org/10.1155/2016/6365830

Pituitary Morphology and Function in 43 Children with Central Diabetes Insipidus

Wendong Liu,^1,2Limin Wang,²Minghua Liu,³and Guimei Li¹

Academic Editor: Sabrina Corbetta

Received07 Dec 2015

Revised25 Jan 2016

Accepted28 Feb 2016

Published29 Mar 2016

Abstract

Objective. In pediatric central diabetes insipidus (CDI), etiology diagnosis and pituitary function monitoring are usually delayed. This study aimed to illustrate the importance of regular follow-up and pituitary function monitoring in pediatric CDI. Methods. The clinical, hormonal, and neuroradiological characteristics of children with CDI at diagnosis and during 1.5–2-year follow-up were collected and analyzed. Results. The study included 43 CDI patients. The mean interval between initial manifestation and diagnosis was 22.29 ± 3.67 months (range: 2–108 months). The most common complaint was polyuria/polydipsia. Causes included Langerhans cell histiocytosis, germinoma, and craniopharyngioma in 2, 5, and 4 patients; the remaining were idiopathic. No significant changes were found during the 1.5–2 years after CDI diagnosis. Twenty-three of the 43 cases (53.5%) had ≥1 anterior pituitary hormone deficiency. Isolated growth hormone deficiency was the most frequent abnormality (37.5%) and was not associated with pituitary stalk diameter. Multiple pituitary hormone deficiencies were found in 8 cases with pituitary stalk diameter > 4.5 mm. Conclusion. Diagnosis of CDI is usually delayed. CDI with a pituitary stalk diameter > 4.5 mm carries a higher risk of multiple pituitary hormone deficiencies. Long-term MRI and pituitary function follow-ups are necessary for children with idiopathic CDI.

1. Introduction

Central diabetes insipidus (CDI) results from deficiency synthesis, release of arginine vasopressin (AVP), or both. Polyuria and polydipsia are important clues to the diagnosis; nonetheless, approximately 40% of the patients have symptoms other than polyuria and polydipsia at presentation [1]. Manifestations can be affected by age, cause, or other dysfunctions. Infants may have fever, vomiting, or failure to thrive rather than polyuria and polydipsia. CDI may be a consequence of surgery or a component of multiple pituitary hormone deficiencies (MPHDs). Polyuria can be masked by adrenocorticotrophic hormone (ACTH) deficiency [2]. Water deprivation tests and a DDAVP (1-desamino-8-D-arginine-vasopressin) trial remain the diagnostic gold standard of CDI, often confirmed by direct measurements of serum AVP and copeptin [3–5].

The etiology of childhood CDI is heterogeneous. It can be familial (i.e., a genetic defect of AVP synthesis) or secondary to diseases that affect the hypothalamic-pituitary system, such as Langerhans cell histiocytosis (LCH), germinoma, craniopharyngioma, trauma related to surgery or accident, or cranial malformations. Hypothalamic magnetic resonance imaging (MRI) is necessary because it not only may lead to a diagnosis of CDI by lack of posterior pituitary bright spot on T1-weighted imaging, but also can reveal intracranial tumor or LCH with a thickened pituitary stalk. However, 20–50% of cases are considered idiopathic [1], either with normal or with thickened pituitary stalk. There may be a delay in the diagnosis of pituitary hormone deficiency, isolated growth hormone deficiency, or MPHD. However, the delay in diagnosis of diabetes insipidus did not affect survival rates significantly [6]. Furthermore, the underlying cause of pituitary stalk thickening associated with MPHD in idiopathic CDI is not completely understood.

To date, diagnosis and differential diagnosis of childhood CDI in China are daunting, with lack of systematic follow-up. In our study, we analyzed the clinical, hormonal, and neuroradiological data at diagnosis and follow-up to illustrate the importance of regular follow-up and monitoring of pituitary function.

2. Materials and Methods

2.1. Subjects

From 2012 to 2014, 43 patients (23 boys and 20 girls) ranging in age from 1.9 to 11.5 y were diagnosed with CDI at the Pediatric Endocrinology Department of Shandong Provincial Hospital. A family history, chief complaints, physical examinations, and laboratory and radiological evaluation were obtained at presentation. Diagnosis of CDI was based on a history of polyuria and polydipsia (urine volume > 1500 mL/kg/d at birth, 100–110 mL/kg/d at 2 y, and 40–50 mL/kg/d after 2 y [7]), with a consistent urine osmolality < 300 mOsm/kg in the 24 h urine specimen. All patients underwent an in-patient water deprivation test and then a desmopressin trial. Patients were treated with oral desmopressin acetate after confirmation of CDI, 2 or 3 times daily.

2.2. Water Deprivation Test and DDAVP Trial

The water deprivation test lasted 4 to 7 hours, in accordance with the standard protocol previously reported [9]. Blood pressure, pulse rate, and weight were monitored at baseline and hourly during the test. Urine samples were also collected hourly for the measurement of urine osmolality and specific gravity. Blood samples for measurement of serum sodium and plasma osmolality were obtained at the beginning and end of the water deprivation test.

After the water deprivation test, DDAVP was administrated by subcutaneous injection (0.1 μg/kg, maximum 4 μg) as a trial. Urine was collected hourly for osmolality and specific gravity. Serum sodium and osmolality were measured again 2 hours after DDAVP administration.

Complete CDI was defined as urine osmolality < 300 mOsm/kg after the water deprivation test with a >50% increase in response to DDAVP. Partial CDI and partial nephrogenic diabetes insipidus and defined as maximum urine osmolality between 300 and 800 mOsm/kg during the water deprivation test and <50% increase in response to DDAVP. Complete CDI, partial CDI, and partial nephrogenic diabetes insipidus were distinguished by abolishment of thirst, polyuria, and polydipsia, without development of hyponatremia, in response to a therapeutic trial with a standard dose of desmopressin [10].

2.3. Anterior Pituitary Function

Growth hormone deficiency was confirmed by provocative tests in all patients. Blood samples to measure growth hormone levels were obtained at baseline and at 30, 60, 90, and 120 min after the administration of arginine (0.5 g/kg, given intravenously over a period of 30 min) and levodopa (10 mg/kg, maximum 500 mg, given orally). Growth hormone deficiency was defined as growth hormone peak level < 10 ng/mL combined with a subnormal IG-1 (insulin-like growth factor 1) level for chronological age.

Thyroid-stimulating hormone (TSH) deficiency was defined as free thyroxine (FT4) < 12.0 pmol/L with a low or low-to-normal serum concentration of TSH.

Plasma ACTH and serum cortisol were measured in the morning (08:00 a.m.). ACTH deficiency was defined by either a morning serum cortisol concentration < 138 nmol/L or a peak serum cortisol concentration < 550 nmol/L during insulin-induced hypoglycemia, in concert with an inappropriately low plasma ACTH concentration.

Follicle-stimulating hormone/luteinizing hormone (FSH/LH) deficiency was diagnosed in 2 patients who had absent/delayed pubertal development. Serum FSH and LH were measured at 0 minutes and 30, 60, and 90 min after administration of gonadotropin-releasing hormone. Low serum testosterone in boys or estradiol in girls, combined with a blunted LH/FSH response to gonadotropin-releasing hormone, was diagnostic for FSH/LH deficiency.

2.4. MRI

All patients underwent hypothalamic-pituitary MRI scans, without and then with contrast agent, using a 3.0 T magnetic resonance scanning machine (Siemens & Co., Germany), in accordance with standard protocol (3.0 mm slice thickness, coronal and sagittal orientation, 256 × 256 matrix size, T1-weighted imaging without and then with contrast agent). The contrast agent was intravenous gadolinium-diethylenetriamine pentaacetic acid (Gd-DTPA), 0.1 mmol/kg.

Images were interpreted by 2 independent observers without prior knowledge of the patients, noting posterior pituitary bright spot, pituitary height, and thickness of the pituitary stalk. Pituitary height was compared to the normal value for age, gender, and development [11]. A thickened stalk was defined as a diameter > 3 mm in at least one of its 3 portions (proximal, median, and distal) [12].

The thickness of the pituitary stalk was characterized as mild (3.0–4.5 mm), moderate (4.6–6.5 mm), or severe (>6.5 mm) [1]. The height of the pituitary gland was compared to the gender and age reference established by Argyropoulou et al. [8].

Based on the hypothalamic-pituitary MRI, patients were considered TPS⁻ or TPS⁺ (diameter of pituitary stalk ≤ 3 mm or >3 mm, resp.).

2.5. Other Studies

To rule out LCH, 27 patients with thickened pituitary stalk underwent skeletal surveys, lung computed tomography (CT) scan, whole-body nuclear medicine bone scanning, and skin histopathological test. To detect secretary germinoma, alpha-fetoprotein (AFP) and β-human chorionic gonadotropin (β-HCG) levels in the blood and spinal fluid were also analyzed.

2.6. Follow-Up

During a 1.5-to-2 y follow-up, patients with idiopathic conditions were seen at 3–6-month intervals and given physical examination and tested for anterior and posterior pituitary function and also tumor markers (serum AFP and β-HCG). Hypothalamic MRI was repeated every 6–12 months. In those patients with a confirmed etiology, follow-up was conducted by phone or clinic.

2.7. Statistical Analysis

IBM SPSS Statistics ver. 20.0 (SPSS, Armonk, NY, USA) software was used for all statistical analyses. Student’s unpaired -test was performed for univariate comparisons between groups. Pearson’s chi-squared test and Fisher’s exact test were applied to compare proportions between groups. Statistical significance was set at .

3. Results

3.1. Baseline Clinical Data

There were 16 and 27 patients in the TPS⁻ and TPS⁺ groups, respectively. Of these 43 patients (23 boys, gender ratio: 1.15), the median age at CDI diagnosis was y (range: 1.9–11.5 y). The mean interval between the initial manifestation and diagnosis was (range: 2–108 months). There were no significant differences between the 2 groups (Table 1).

The most common symptoms or signs were polyuria/polydipsia (, 90.6%), nocturia (, 41.9%), short stature (, 39.5%), anorexia (, 23.3%), headache (, 6.9%), mental retardation (, 4.7%), emesis (, 2.3%), and rash (). There were 5 patients with a normal pituitary stalk and 12 with abnormal pituitary stalk accompanied by short stature, with heights of standard deviation of and , respectively.

Two patients with mental retardation had comorbidity including hydronephrosis and ureterectasia; their intervals between presentation and diagnoses were 72 months and 108 months. Both had a poor response to DDAVP therapy.

None of the subjects had a familial etiology, nor a history of surgery, infection, or trauma. All TPS⁻ cases were idiopathic, whereas 11 TPS⁺ patients were etiologically diagnosed with germinoma (), craniopharyngioma (), and LCH (; Table 2). Short stature, defined as individual height > 2 standard deviations below the corresponding mean height for a given age, gender, and population, was present in 10 patients, except one patient with LCH.

3.2. Posterior Pituitary Function

Urine volume of the 43 patients was mL/kg/day. Initial urine osmolality was mOsm/kg and serum osmolality was mOsm/kg. The ratio of urine osmolality to serum osmolality was <1.0 and increased significantly to mOsm/kg and mOsm/kg, respectively, after water deprivation (). In response to DDAVP, urine osmolality increased to mOsm/kg, with a mean increment of % (range: 39–450%). One patient received a diagnosis of partial CDI (urine osmolality increased by 39%) with a standard dose of desmopressin, and 42 patients had complete CDI. There were no differences between the two groups (Table 2).

3.3. Neuroimaging Findings

The posterior pituitary bright spot was absent on T1-weighted MRI in all 43 patients (100%). Of the 27 patients with abnormal pituitary stalk, hypothalamic-pituitary MRI revealed suprasellar mass in 9: germinoma (), supported by elevated serum CSF/β-HCG level, and craniopharyngioma () based on histological examination after surgery. Two children had LCH with thickened pituitary stalk, confirmed histopathologically in skin or skull lesion.

Craniopharyngioma patients () had an invisible pituitary stalk and anterior pituitary gland. In 2 of 3 germinoma patients with severe thickened pituitary stalk, the anterior pituitary was not seen on MRI, whereas the other had a reduced anterior pituitary size. Anterior pituitary glands in the 3 patients with moderately thickened pituitary stalk (1 with LCH and 2 with germinoma) were smaller than normal. Seventeen patients (1 with LCH and 16 with idiopathic cases) showed mildly thickened pituitary stalk, 3 of whom had a smaller anterior pituitary gland than normal. Of the 16 patients with normal pituitary stalk, 4 had hypoplastic anterior pituitaries.

In summary, anterior pituitary size was reduced in patients with normal or abnormal pituitary stalk and was undetected by MRI in patients with severely thickened and invisible pituitary stalk.

3.4. Anterior Pituitary Function

Anterior pituitary function was assessed in 43 patients; 23 (53.5%) had at least 1 anterior pituitary hormone deficiency. Isolated growth hormone deficiency was the most frequent abnormality (, 37.5%) and was not associated with pituitary stalk size.

Among the 16 patients with normal pituitary stalk, 6 (37.5%) had isolated growth hormone deficiency, 4 with small and 2 with normal anterior pituitary.

Among the 17 patients with mildly thickened pituitary stalk, 6 showed isolated growth hormone deficiency, 3 of whom had decreased size of anterior pituitary. Anterior pituitary hormone function was normal in 11 patients. MPHD was found in 2 patients with a moderately thickened pituitary stalk, and 2 of 3 patients with severely thickened pituitary stalk developed growth hormone deficiency and TSH deficiency. All 4 patients with an invisible pituitary stalk had MPHD (Table 3). In addition, 1 patient with germinoma and 1 patient with craniopharyngioma had elevated PRL levels (29.03 ng/mL and 58.54 ng/mL). Our study found an association between thickness of the pituitary stalk and the likelihood of MPHD ().

3.5. Follow-Up

Five patients with germinoma were treated with chemotherapy and then radiotherapy. Four patients with craniopharyngioma underwent surgical excision and pituitary stalk was undetectable on MRI. All patients with tumor developed at least 3 pituitary hormone deficiencies. Two patients with LCH are monitored regularly, and one was found to have isolated growth hormone deficiency. One craniopharyngioma patient relapsed 1.5 years after surgery.

One idiopathic patient with a mildly thickened pituitary stalk (3.4 mm) was normal one year after diagnosis but still required DDAVP therapy. The pituitary stalk of one patient increased from 3.9 mm to 4.0 mm after 6 months. Others did not have any significant change and are still under follow-up.

4. Discussion

We analyzed the clinical, biochemical, neuroradiological, and hormonal results from pediatric patients with CDI.

Polyuria and polydipsia are the most common manifestations of CDI. However, some patients were seen by the doctor because of slow growth. In addition, polyuria and polydipsia can be masked by ACTH deficiency [2]. A previous study reported that 40% of CDI patients had symptoms other than polyuria/polydipsia at presentation [1]. In the present study, 12 patients (27.9%) presented with short stature and had growth hormone deficiency, and another 5 patients presented with polyuria/polydipsia accompanied by short stature. Short stature and growth hormone deficiency were not associated with etiology, which is consistent with previous studies [13]. However, short stature can be a predictor of growth hormone deficiency. In addition, other symptoms or signs such as vomiting and headache might be related to intracranial tumors, and rash might be a predictor of LCH.

In the present study, the mean age at diagnosis was years, in accord with previous reports [14], widely ranging from 1.9 to 11.5 years. The time interval between onset and diagnosis varied by wide range. However, for 76.7%, the interval was more than 12 months; most children’s heights were below the 50th percentile and the body mass index was low. Two patients with longer intervals between onset and diagnosis (108 and 72 months, resp.) developed nephritic complications. Delay in diagnosis can affect life quality due to complications.

Polydipsia and polyuria exceeding 5 mL/kg/hour with urine specific gravity less than 1.01, plasma sodium level above 145 mmol/L, and dehydration are the hallmarks of diabetes insipidus in infants and children [15]. In the present study, the mean urine volume over 24 hours was mL/kg, approximately equal to 8.4 mL/kg/hour, much higher than 5 mL/kg/hour. Baseline levels of urine osmolality were lower than 300 mOsm/kg, and urine specific gravity was below 1.010. However, the average plasma sodium was mmol/L, which is not consistent with a previous hypernatremia report.

As a type of diabetes insipidus, it is important to differentiate CDI from nephrogenic diabetes insipidus and primary polydipsia, because inappropriate treatment can result in severe complications. Direct measurement of serum AVP is recommended for diagnosis [3, 4], but it has not been accepted due to several shortcomings [1, 16–21]. In contrast, copeptin, the C-terminal glycoprotein moiety of pro-AVP, has been suggested as a stable surrogate marker of AVP secretion to improve the differential diagnosis of diabetes insipidus [16]. A recent prospective multicenter study showed significant lower copeptin levels (both baseline and osmolality stimulated) in CDI cases [5]. However, we did not test AVP and copeptin when our patients were diagnosed, due to limitations.

The water deprivation test and DDAVP trial still are the gold standard for diagnosis/differential diagnosis of CDI. But the interpretation is more and more challenging. For example, we confirmed 42 complete CDI and 1 partial CDI using the protocol in our study, but this would have been 39 and 4, respectively, if we defined complete CDI as a ratio of urinary osmolality to plasma osmolality of ≤1.0 and partial CDI as >1.0 [1]. Only four patients with baseline urinary osmolality < 300 mOsm/kg showed an increase to >750 mOsm/kg after water deprivation, and this may be considered partial CDI if we used another protocol [22]. Although there would be different proportions of partial CDI and complete CDI given different interpretations, there was no correlation with ideology. All the patients responded to DDAVP treatment. This suggests that a therapeutic trial with the standard dose of desmopressin is important to differentiate partial CDI, partial nephrogenic diabetes insipidus, and primary polydipsia, if measurements of AVP and copeptin are limited.

MRI is recommended as soon as CDI is diagnosed. One common finding in MRI is the absence of a physiological posterior bright spot (PBS) on sagittal T1-weighted imaging. Some earlier reports showed that absence of a PBS is not specific for CDI diagnosis, because individual CDI cases with persistent PBS have been reported [23, 24]. However, the PBS is diminished or absent in both CDI and nephrogenic diabetes insipidus [25–27], and it is always absent when diabetes insipidus was a presenting symptom [13, 28]. All the cases in our study lack the PBS (100%).

A thickened pituitary stalk, isolated or with a mass, is another common finding on MRI, in 50–60% of the children. LCH, germinoma, and craniopharyngioma are the most common causes of thickened pituitary stalk, but neither the pattern nor the thickness of the pituitary stalk correlated with clinical features. Radiological features of craniopharyngioma are typical and easy to differentiate from LCH and germinoma [2]. It was difficult to distinguish on MRI between LCH and germinoma because LCH can be single system that only involves the hypothalamic-pituitary system; tumor markers such as AFP and β-HCG in the blood and central spinal fluid can be negative in the early stage of the tumor; and LCH and germinoma could share the same findings in some cases when CDI was diagnosed.

A biopsy of the pituitary stalk can provide a definitive diagnosis. However, physicians in China are conservative on biopsy, due to the risk of surgery and because of the parents. In our study, 2 of the 5 germinoma patients were diagnosed through elevated plasma β-HCG levels. One LCH patient had a skin rash, while the other 3 germinoma patients and 1 LCH patient were diagnosed by the good response to the trial therapeutic treatment (Table 4). Four craniopharyngioma patients had a typical pattern on MRI, which was confirmed by surgery and pathology.

The height of the pituitary gland on MRI can be normal, low, or high. Maghnie et al. [1] suggested that an associated large antehypophysis and a thickened stalk are highly suspicious of a germinal tumor. However, germinoma cases in our study had a small or invisible pituitary gland.

Dysfunction of the anterior pituitary can be determined at diagnosis and during the follow-up period of CDI. In the present study, 53.5% of the patients had anterior pituitary hormone deficiency when CDI was diagnosed, which was lower than the 80% reported by Liu et al. [29]. Most of these patients had growth hormone deficiency, not related to etiology.

In our study here, the probability of developing MPHD was associated with thickness of the pituitary stalk. In addition, our study found higher prevalence of MPHD in cases with intracranial tumor compared with LCH. Marchand et al. [30] found that the number of anterior pituitary deficiencies seemed to be dependent on the size of the initial lesion. In our patients, 2 LCH patients, there was no MPHD, perhaps because the sizes of the neoplasms were less than 6.5 cm. However, long-term monitoring is needed, because this can develop years after CDI [30, 31].

The natural history of CDI in terms of etiology is hard to determine. Clinical, radiological, and endocrinological investigations must be performed at diagnosis and follow-up. During follow-ups that ranged from 4.1 to 14.3 years of 43 idiopathic CDI patients (mean age: 7.4 y), 3 patients had LCH and one patient developed Hodgkin’s lymphoma 8.5 to 10 years after CDI onset [32]. Although the follow-up times of our present cases were not long enough, they are still being monitored. An appropriate therapeutic trial may be useful in patients with a persistent uncertain diagnosis; however, it should be conducted with close supervision.

In this study, we have demonstrated the limitations in the diagnosis and follow-up of childhood CDI in China. These limitations are important to note, and the attention of parents and physicians given to the associated symptoms, signs, and diagnostic tests should be improved to prevent delay in diagnosis. As soon as there is a diagnosis of CDI, regular and long-term clinical follow-ups are required that include imaging and tests for tumor markers and pituitary function.

Competing Interests

The authors declare that they have no competing interests.

References

M. Maghnie, G. Cosi, E. Genovese et al., “Central diabetes insipidus in children and young adults,” The New England Journal of Medicine, vol. 343, no. 14, pp. 998–1007, 2000.
View at: Publisher Site | Google Scholar
S. Ghirardello, N. Hopper, A. Albanese, and M. Maghnie, “Diabetes insipidus in craniopharyngioma: postoperative management of water and electrolyte disorders,” Journal of Pediatric Endocrinology and Metabolism, vol. 19, supplement 1, pp. 413–421, 2006.
View at: Google Scholar
R. L. Zerbe and G. L. Robertson, “A comparison of plasma vasopressin measurements with a standard indirect test in the differential diagnosis of polyuria,” The New England Journal of Medicine, vol. 305, no. 26, pp. 1539–1546, 1981.
View at: Publisher Site | Google Scholar
P. H. Baylis, M. B. Gaskill, and G. L. Robertson, “Vasopressin secretion in primary polydipsia and cranial diabetes insipidus,” Quarterly Journal of Medicine, vol. 50, no. 199, pp. 345–358, 1981.
View at: Google Scholar
K. Timper, W. Fenske, F. Kuhn et al., “Diagnostic accuracy of copeptin in the differential diagnosis of the polyuria-polydipsia syndrome: a prospective multicenter study,” The Journal of Clinical Endocrinology & Metabolism, vol. 100, no. 6, pp. 2268–2274, 2015.
View at: Publisher Site | Google Scholar
A. Varan, E. Atas, B. Aydin et al., “Evaluation of patients with intracranial tumors and central diabetes insipidus,” Pediatric Hematology and Oncology, vol. 30, no. 7, pp. 668–673, 2013.
View at: Publisher Site | Google Scholar
T. Cheetham and P. H. Baylis, “Diabetes insipidus in children: pathophysiology, diagnosis and management,” Pediatric Drugs, vol. 4, no. 12, pp. 785–796, 2002.
View at: Publisher Site | Google Scholar
M. Argyropoulou, F. Perignon, F. Brunelle, R. Brauner, and R. Rappaport, “Height of normal pituitary gland as a function of age evaluated by magnetic resonance imaging in children,” Pediatric Radiology, vol. 21, no. 4, pp. 247–249, 1991.
View at: Publisher Site | Google Scholar
S. Ghirardello, M.-L. Garrè, A. Rossi, and M. Maghnie, “The diagnosis of children with central diabetes insipidus,” Journal of Pediatric Endocrinology and Metabolism, vol. 20, no. 3, pp. 359–375, 2007.
View at: Google Scholar
W. Fenske and B. Allolio, “Current state and future perspectives in the diagnosis of diabetes insipidus: a clinical review,” Journal of Clinical Endocrinology and Metabolism, vol. 97, no. 10, pp. 3426–3437, 2012.
View at: Publisher Site | Google Scholar
M. F. Ikram, Z. Sajjad, I. Shokh, and A. Omair, “Pituitary height on magnetic resonance imaging observation of age and sex related changes,” Journal of the Pakistan Medical Association, vol. 58, no. 5, pp. 261–265, 2008.
View at: Google Scholar
J. Leger, A. Velasquez, C. Garel, M. A. X. Hassan, and P. Czernichow, “Thickened pituitary stalk on magnetic resonance imaging in children with central diabetes insipidus,” Journal of Clinical Endocrinology and Metabolism, vol. 84, no. 6, pp. 1954–1960, 1999.
View at: Google Scholar
J. De Buyst, G. Massa, C. Christophe, S. Tenoutasse, and C. Heinrichs, “Clinical, hormonal and imaging findings in 27 children with central diabetes insipidus,” European Journal of Pediatrics, vol. 166, no. 1, pp. 43–49, 2007.
View at: Publisher Site | Google Scholar
A. E. Al-Agha, M. J. Thomsett, J. F. Ratcliffe, A. M. Cotterill, and J. A. Batch, “Acquired central diabetes insipidus in children: a 12-year Brisbane experience,” Journal of Paediatrics and Child Health, vol. 37, no. 2, pp. 172–175, 2001.
View at: Publisher Site | Google Scholar
P. Saborio, G. A. Tipton, and J. C. Chan, “Diabetes insipidus.,” Pediatrics in Review, vol. 21, no. 4, pp. 122–129, 2000.
View at: Publisher Site | Google Scholar
W. Fenske, M. Quinkler, D. Lorenz et al., “Copeptin in the differential diagnosis of the polydipsia-polyuria syndrome-revisiting the direct and indirect water deprivation tests,” Journal of Clinical Endocrinology and Metabolism, vol. 96, no. 5, pp. 1506–1515, 2011.
View at: Publisher Site | Google Scholar
P. H. Baylis and G. L. Robertson, “Plasma vasopressin response to hypertonic saline infusion to assess posterior pituitary function,” Journal of the Royal Society of Medicine, vol. 73, no. 4, pp. 255–260, 1980.
View at: Google Scholar
N. G. Morgenthaler, J. Struck, C. Alonso, and A. Bergmann, “Assay for the measurement of copeptin, a stable peptide derived from the precursor of vasopressin,” Clinical Chemistry, vol. 52, no. 1, pp. 112–119, 2006.
View at: Publisher Site | Google Scholar
G. L. Robertson, E. A. Mahr, S. Athar, and T. Sinha, “Development and clinical application of a new method for the radioimmunoassay of arginine vasopressin in human plasma,” The Journal of Clinical Investigation, vol. 52, no. 9, pp. 2340–2352, 1973.
View at: Publisher Site | Google Scholar
G. Baumann and J. F. Dingman, “Distribution, blood transport, and degradation of antidiuretic hormone in man,” The Journal of Clinical Investigation, vol. 57, no. 5, pp. 1109–1116, 1976.
View at: Publisher Site | Google Scholar
J. W. Czaczkes, C. R. Kleeman, and M. Koenig, “Physiologic studies of antidiuretic hormone by its direct measurement,” The Journal of Clinical Investigation, vol. 43, pp. 1625–1640, 1964.
View at: Publisher Site | Google Scholar
N. Di Iorgi, F. Napoli, A. E. M. Allegri et al., “Diabetes insipidus—diagnosis and management,” Hormone Research in Paediatrics, vol. 77, no. 2, pp. 69–84, 2012.
View at: Publisher Site | Google Scholar
M. Maghnie, E. Genovese, S. Bernasconi, S. Binda, and M. Aricò, “Persistent high MR signal of the posterior pituitary gland in central diabetes insipidus,” American Journal of Neuroradiology, vol. 18, no. 9, pp. 1749–1752, 1997.
View at: Google Scholar
M. J. Hannon, C. Orr, C. Moran et al., “Anterior hypopituitarism is rare and autoimmune disease is common in adults with idiopathic central diabetes insipidus,” Clinical Endocrinology, vol. 76, no. 5, pp. 725–728, 2012.
View at: Publisher Site | Google Scholar
P. Halimi, R. Sigal, D. Doyon, S. Delivet, P. Bouchard, and I. Pigeau, “Post-traumatic diabetes insipidus: MR demonstration of pituitary stalk rupture,” Journal of Computer Assisted Tomography, vol. 12, no. 1, pp. 135–137, 1988.
View at: Google Scholar
M. Maghnie, A. Villa, M. Arico et al., “Correlation between magnetic resonance imaging of posterior pituitary and neurohypophyseal function in children with diabetes insipidus,” Journal of Clinical Endocrinology and Metabolism, vol. 74, no. 4, pp. 795–800, 1992.
View at: Publisher Site | Google Scholar
A. M. Moses, B. Clayton, and L. Hochhauser, “Use of T1-weighted MR imaging to differentiate between primary polydipsia and central diabetes insipidus,” American Journal of Neuroradiology, vol. 13, no. 5, pp. 1273–1277, 1992.
View at: Google Scholar
F. M. Elli, S. Ghirardello, C. Giavoli et al., “A new structural rearrangement associated to Wolfram syndrome in a child with a partial phenotype,” Gene, vol. 509, no. 1, pp. 168–172, 2012.
View at: Publisher Site | Google Scholar
S.-Y. Liu, Y.-C. Tung, C.-T. Lee et al., “Clinical characteristics of central diabetes insipidus in taiwanese children,” Journal of the Formosan Medical Association, vol. 112, no. 10, pp. 616–620, 2013.
View at: Publisher Site | Google Scholar
I. Marchand, M. A. Barkaoui, C. Garel, M. Polak, and J. Donadieu, “Central diabetes insipidus as the inaugural manifestation of langerhans cell histiocytosis: natural history and medical evaluation of 26 children and adolescents,” Journal of Clinical Endocrinology and Metabolism, vol. 96, no. 9, pp. E1352–E1360, 2011.
View at: Publisher Site | Google Scholar
J. Donadieu, M.-A. Rolon, I. Pion et al., “Incidence of growth hormone deficiency in pediatric-onset Langerhans cell histiocytosis: efficacy and safety of growth hormone treatment,” Journal of Clinical Endocrinology and Metabolism, vol. 89, no. 2, pp. 604–609, 2004.
View at: Publisher Site | Google Scholar
N. Di Iorgi, A. E. M. Allegri, F. Napoli et al., “Central diabetes insipidus in children and young adults: etiological diagnosis and long-term outcome of idiopathic cases,” Journal of Clinical Endocrinology and Metabolism, vol. 99, no. 4, pp. 1264–1272, 2014.
View at: Publisher Site | Google Scholar

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Copyright © 2016 Wendong Liu et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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