ABSTRACT

Objective:

Contrast-enhanced brain magnetic resonance imaging (MRI) is routinely performed in children with central precocious puberty (CPP). We evaluated the value of a dedicated sellar MRI protocol without contrast enhancement in girls with CPP.

Subjects and methods:

This study included 261 girls diagnosed with CPP. We performed sellar MRI scanning without gadolinium enhancement of the hypothalamic-pituitary area (HPA) at the pituitary level, including additional T2-weighted imaging of whole-brain scans to check for other lesions. We evaluated the prevalence of intracranial lesions via this MR protocol. In addition,the correlation between the clinical parameters and morphology of the pituitary gland on the images was assessed.

Results:

Intracranial lesions were detected in 17 (6.5%) of the 261 girls. Of the 17 girls with abnormalities, 16 (94.1%) had findings in brain areas other than the HPA. The weight, height, Tanner stage of patients were significantly (p < 0.05) higher in the group with greater pituitary height. Patient weight and height, Tanner stage of breast development, and luteinizing hormone (LH) levels were significantly (p < 0.05) greater in those with a higher pituitary grade as determined on sellar MRI.

Conclusion:

A dedicated unenhanced sellar MRI protocol provides valuable information on brain lesions and pituitary morphology. We found a significantly low prevalence of brain lesions among girls with CPP. Analysis of the height or shape of the pituitary gland on sellar MRI revealed significant correlations with the weight, height, Tanner stage, and LH levels of the patients.

Keywords
Girls; precocious puberty; brain; sellar; magnetic resonance imaging

INTRODUCTION

Central precocious puberty (CPP) is early development of secondary sexual characteristics before the age of 8 years in girls, caused by premature activation of the hypothalamic-pituitary-gonadal axis (HPA) (¹1 Chen M, Eugster EA. Central precocious puberty: Update on diagnosis and treatment. Paediatric Drugs. 2015;17(4):273-81.). Once CPP is confirmed by laboratory testing, central nervous system (CNS) imaging is performed to identify possible CNS abnormalities (²2 Carel JC, Eugster EA, Rogol A, Ghizzoni L, Palmert MR; ESPE-LWPES GnRH Analogs Consensus Conference Group, et al. Consensus statement on the use of gonadotropin-releasing hormone analogs in children. Pediatrics. 2009;123(4):e752-62.

3 Orsdemir SC, Garb JL, Allen HF. The prevalence of cranial MRI findings in girls with central precocious puberty: A systemic review and meta-analysis. J Pediatr Endocrinol Metab. 2018;31(7):701-10.

4 De Sanctis V, Corrias A, Rizzo V, Bertelloni S, Urso L, Galluzzi F, et al. Etiology of central precocious puberty in males: The results of the Italian study group for physiopathology of puberty. J Pediatr Endocrinol Metab. 2000;13 Suppl 1:687-93.-⁵5 Choi KH, Chung SJ, Kang MJ, Yoon JY, Lee JE, Lee YA, et al. Boys with precocious or early puberty: Incidence of pathological brain magnetic resonance imaging findings and factors related to newly developed brain lesions. Ann Pediatr Endocrinol Metab. 2013;18(4):183-90.). The prevalence of CNS abnormalities in girls is low, at 0%-27%, and decreases with increasing age (⁶6 Atta I, Laghari TM, Khan YN, Lone SW, Ibrahim M, Raza J. Precocious puberty in children. J Coll Physicians Surg Pak. 2015;25(2):124-8

7 Bridges NA, Christopher JA, Hindmarsh PC, Brook CG. Sexual precocity: Sex incidence and aetiology. Arch Dis Child. 1994;70(2):116-8.-⁸8 Chalumeau M, Chemaitilly W, Trivin C, Adan L, Breart G, Brauner R. Central precocious puberty in girls: An evidence-based diagnosis tree to predict central nervous system abnormalities. Pediatrics. 2002;109(1):61-7.). Recently, there has been controversy has arisen over whether cranial imaging is necessary for all girls with CPP (⁹9 Vuralli D, Gonc EN, Alikasifoglu A, Kandemir N, Ozon ZA. Central nervous system imaging in girls with central precocious puberty: When is necessary? Arch Endocrinol Metab. 2020;64(5):591-6.). Some pediatric endocrinologists recommend that girls with CPP undergo cranial magnetic resonance imaging (MRI) only if they are < 6 years of age (³3 Orsdemir SC, Garb JL, Allen HF. The prevalence of cranial MRI findings in girls with central precocious puberty: A systemic review and meta-analysis. J Pediatr Endocrinol Metab. 2018;31(7):701-10.). Some doctors and parents become concerned, however, if CNS abnormalities are not ruled out.

Contrast-enhanced brain MRI (CE-MRI) is the diagnostic modality that is used to exclude organic causes of CPP. However, CE-MRI contrast injection that is part of CEMRI, has several disadvantages, including discomfort to the patient, the need for sedation, and the high cost of the procedure (¹⁰10 Blumfield E, Moore MM, Drake MK, Goodman TR, Lewis KN, Meyer LT, et al. Survey of gadolinium-based contrast agent utilization among the members of the Society for Pediatric Radiology: A Quality and Safety Committee report. Pediatr Radiol. 2017;47(6):665-73.). In addition, the clinical impact and toxicity of gadolinium-based contrast agent agents is unclear, and long-term safety has not been fully established in pediatric patients (¹¹11 Elbeshlawi, I. Abdelbaki MS. Safety of gadolinium administration in children. Pediatr Neurol. 2018;86:27-32.,¹²12 Salerno S, Granata C, Trapenese M, Cannata V, Curione D, Rossi Espagnet MC, et al. Is MRI imaging in pediatric age totally safe? A critical reprisal. Radiol Med. 2018;123(9):695-702.). In consideration of these issues, guidelines for CPP screening tests need refinement. Therefore, we investigated the value of a dedicated sellar MRI protocol to evaluate the hypothalamic-pituitary axis (HPA), including additional T2-weighted imaging (T2WI) of the entire brain without contrast enhancement, in girls with CPP, and we discuss the clinical findings that justify its use. The primary aim of this study was to evaluate the prevalence and types of intracranial lesions in girls with CPP by age groups. A second aim was to evaluate the correlations of clinical and biochemical characteristics according to the morphology (height and shape) of the pituitary gland in sellar MRI images.

SUBJECTS AND METHODS

Patients

We retrospectively reviewed the records of girls diagnosed with CPP who underwent unenhanced sellar MRI at our hospital between January 2011 and July 2020. Patients with missing clinical data were excluded from the study. In total, 261 girls were included in the final analysis. The study protocol was approved by the institutional review board of our committee (SC21RISI0028). The requirement for informed consent was waived due to the retrospective nature of the study. The research was conducted in accordance with principles of the Declaration of Helsinki.

Clinical features and CPP diagnosis

The CPP diagnosis was based on clinical and biochemical data. The clinical characteristics included age at diagnosis, age at the time of the MRI, age at thelarche/pubarche, weight (kg), height (cm), body mass index (BMI), mid-parental height, and the Tanner stage of breast and pubic hair development, as assessed by a pediatric endocrinologist. Standard deviation scores (SDSs) for height, weight, and BMI were calculated using 2017 National Growth Charts. The mid-parental height was calculated as (mother’s height + (father’s height − 13)/2 and denoted as SDS. Bone age (BA) was assessed based on the match between a left hand X-ray image and the Greulich and Pyle atlas. The gonadotropin-releasing hormone (GnRH) stimulation test, which is the gold standard for diagnosing CPP, was performed to obtain biochemical data. Serum levels of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) were measured before and 30 min after intravenous (IV) injection of GnRH (100 µg Relefact; Sanofi-Aventis, Frankfurt am Main, Germany). CPP was diagnosed after it was confirmed that the patient had developed breasts before the age of 8 years, and had an advanced BA > 2 standard deviations (SDs) above the patient’s chronological age. The criterion for a CPP diagnosis was defined as a peak LH level ≥ 5 mIU/mL after a GnRH stimulation test. Serum LH and FSH levels were measured using immunoradiometric assays (BioSource, Nivelles, Belgium).

Sellar MRI protocol and image interpretation

We used a Signa Excite 1.5 T MRI scanner (GE Healthcare, Milwaukee, WI, USA) before 2016 and a Skyra 3 T MRI scanner (Siemens Healthcare, Erlangen, Germany) after 2016. MRI scans of the HPA were obtained in the coronal, sagittal, and axial planes at the pituitary level. The sagittal plane views were positioned parallel to the midline of the pilot scan in the coronal plane. We also performed a whole-brain axial T2WI scans to check for lesions. The imaging sequences and parameters are reported in Supplementary Table 1. Contrast enhancement was not used for the initial examinations in any of the patients. Only five of the 17 patients in whom abnormalities were found by initial MRI underwent additional contrast-enhanced scans. The MRI images of all patients were analyzed and interpreted by two experienced radiologists (SA Park and GY Lim). Pituitary shape, height, and stalk, and the presence of other abnormities in the HPA were verified. The mid-sagittal section was defined by visualizing the anterior and posterior pituitary lobes, along with the pituitary stalk, in the same slice. The height of the pituitary gland was measured at the site of insertion of the stalk as the maximum vertical distance between the upper and the lower borders of the gland. In the present study, increased pituitary height (pituitary hyperplasia) was considered as a height greater than 6 mm (¹³13 Elster AD, Chen MY, Williams DW 3rd, Key LL. Pituitary gland: MR imaging of physiologic hypertrophy in adolescence. Radiology. 1990;174(3 Pt 1):681-5.). The shape of the pituitary gland on sagittal images was graded using the scoring system of Elster and cols. (¹³13 Elster AD, Chen MY, Williams DW 3rd, Key LL. Pituitary gland: MR imaging of physiologic hypertrophy in adolescence. Radiology. 1990;174(3 Pt 1):681-5.) (Figure 1). In this system, the grades were as follows: 1, markedly concave upper surface (> 2 mm central depression); 2, minimally concave upper surface with < 2 mm central depression; 3, flat upper surface; 4, minimally convex upper surface (<2 mm central elevation); and 5, markedly convex upper surface, appearing almost spherical. The pooled prevalence of intracranial lesions was calculated, and stratified by age group (< 6, 6-8, and > 8 years). We also assessed changes in the clinical and laboratory parameters according to the height and shape of the pituitary gland in the images.

Statistical analyses

Statistical analyses were performed using IBM SPSS Statistics software (version 26.0; IBM Corp., Armonk, NY, USA). Data are expressed as the mean ± SD. The Mann-Whitney U test was used to compare the MRI findings and clinical parameters between the groups. The Jonckheere-Terpstra test was used to identify trends in the clinical characteristics according to pituitary shape. In all analyses, p < 0.05 was taken to indicate statistical significance.

RESULTS

Prevalence of intracranial lesions in MRI images according to age group

In our cohort, 0.8% (n = 2) of the girls were aged < 6 years, 46% (n = 120) were aged 6-8 years, and 53.2% (n = 139) were aged 8-9 years (Table 1). The patients were divided into the following three groups according to the MRI findings: group 1, normal with no CNS or HPA abnormalities (n = 244, 93.5%); group 2, abnormalities in the brain region but not in the HPA region: pineal cysts (n = 12), choroidal fissure cysts (n = 2), sphenoid sinus retention cysts (n = 1), and neuroepithelial cysts (n = 1) (group 2, n = 16, 6.1%); and group 3, pathological abnormalities in the HPA associated with CPP (n = 1, 0.4%). The single patient in group 3 was a 4-year-old girl with a hypothalamic hamartoma (Table 1). Group 3 abnormal findings were detected in one of two girls aged < 6 years, whereas there were no abnormal findings in the girls with CPP aged 6-8 years or > 8 years. Only 6 of 120 girls (2.3%) aged 6-8 years and 10 of 139 girls (3.8%) with CPP aged > 8 years had group 2 abnormal findings (Table 1).

For all five patients who underwent a subsequent contrast-enhanced MRI scan, there were no additional diagnostic findings in the enhanced images compared to the non-enhanced ones.

Clinical characteristics according to pituitary height

The clinical characteristics of the patients are summarized in Supplementary Table 2. Clinical characteristics according to pituitary height are presented in Table 2. Patients with increased pituitary height were significantly (p < 0.05) heavier, taller, and at a later Tanner stage than those with normal pituitary height (Table 2). No significant differences in mid-parental height or other clinical features were observed between the two groups (Table 2). BMI (SDS) was 0. 73 ± 1.91 in the pituitary hyperplasia group and 0.18 ± 0.92 in the group with normal pituitary height (p = 0.12).

Trends in clinical characteristics according to pituitary shape

The trends in the clinical characteristics according to pituitary shape are shown in Table 3. Patient weight, height, BMI, Tanner stage of breast development, and baseline/peak LH ratio were significantly greater in those with a higher pituitary grade as determined on sellar MRI. The obesity rate increased with pituitary shape maturation (p = 0.049). No significant increasing or decreasing trends were observed in mid-parental height (p = 0.60) or other parameters.

DISCUSSION

CPP can be idiopathic or associated with CNS abnormalities, such as hamartomas or brain tumors. The prevalence of CNS abnormalities is much lower in girls (0%-27%) than in boys, and decreases with age (6-8). Recent studies that have classified girls with CPP according to age at diagnosis reported that 17.1%-26.9% of girls diagnosed at age < 6 years have a CNS pathology compared to 0%-1.9% of those diagnosed at age ≥ 6 years (9,14-17). In our study, abnormal findings occurred in 6.5% of the cases, but most (6.1%) were in the brain regions outside the HPA, and none of the girls aged > 6 years had lesions in the HPA region related to CPP. However, these results may have been influenced by selection bias. The reason for this feature may be that 53.2% of the patients were aged 8-9 years. Generally, routine sellar MRI was performed for girls with CPP who were younger than 6-8 years. In our study, MRI was performed in girls aged 8-9 years to evaluate the patients at the time of the diagnosis. The precise onset of secondary sexual characteristic development was unknown because the parents did not know the exact onset age. Therefore, the onset of secondary sexual characteristic development could have occurred at ages younger than those we identified. Thus, there could have been considerable gap between patient onset age and the age at the time of diagnosis. Nevertheless, some cases showed early puberty in this age group. In these cases, we explained the relationships between brain lesions and CPP to the patients’ parents, and performed MRI on request.

There is debate whether such cranial imaging is necessary for all girls with CPP (¹⁴14 Pedicelli S, Alessio P, Scirè G, Cappa M, Cianfarani S. Routine screening by brain magnetic resonance imaging is not indicated in every girl with onset of puberty between the ages of 6 and 8 years. J Clin Endocrinol Metab. 2014;99(12):4455-61.

15 Chalumeau M, Hadjiathanasiou CG, Ng SM, Cassio A, Mul D, Cisternino M, et al. Selecting girls with precocious puberty for brain imaging: validation of European evidence-based diagnosis rule. J Pediatr. 2003;143(4):445-50.

16 Chalumeau M, Chemaitilly W, Trivin C, Adan L, Breart G, Brauner R. Central precocious puberty in girls: An evidence-based diagnosis tree to predict central nervous system abnormalities. Pediatrics. 2002;109(1):61-7.-¹⁷17 Kaplowitz PB. Do 6-8 year old girls with central precocious puberty need routine brain imaging? Int J Pediatr Endocrinol. 2016;2016:9.). Some pediatric endocrinologists recommend that girls with CPP only undergo cranial MRI if they are < 6 years old (⁹9 Vuralli D, Gonc EN, Alikasifoglu A, Kandemir N, Ozon ZA. Central nervous system imaging in girls with central precocious puberty: When is necessary? Arch Endocrinol Metab. 2020;64(5):591-6.). Some doctors and parents become concerned when girls with CPP forgo exams. Contrast-enhanced MRI is routinely performed in many tertiary care centers to rule out brain abnormalities in girls diagnosed with CPP, despite the disadvantages of administering contrast agents and IV sedation, which is often needed in young children (¹⁰10 Blumfield E, Moore MM, Drake MK, Goodman TR, Lewis KN, Meyer LT, et al. Survey of gadolinium-based contrast agent utilization among the members of the Society for Pediatric Radiology: A Quality and Safety Committee report. Pediatr Radiol. 2017;47(6):665-73.

11 Elbeshlawi, I. Abdelbaki MS. Safety of gadolinium administration in children. Pediatr Neurol. 2018;86:27-32.-¹²12 Salerno S, Granata C, Trapenese M, Cannata V, Curione D, Rossi Espagnet MC, et al. Is MRI imaging in pediatric age totally safe? A critical reprisal. Radiol Med. 2018;123(9):695-702.). The standard sellar MRI protocol includes 2-3 mm thick, T1- and T2-weighted images in the sagittal and coronal planes. Conventional spin-echo techniques are usually employed for T1-weighted imaging, whereas turbo/fast spin-echo sequences are obtained for T2WI. Thin-slice (2-3 mm thick) contrast enhanced T1-weighted sequences should be obtained in the sagittal and coronal planes (¹⁸18 Cassio A, Cacciari E, Zucchini S, Balsamo A, Diegoli M, Orsini F. Central precocious puberty: Clinical and imaging aspects. J Pediatr Endocrinol Metab. 2000;13 Suppl 1:703-8.,¹⁹19 Ng SM, Kumar Y, Cody D, Smith CS, Didi M. Cranial MRI scans are indicated in all girls with central precocious puberty. Arch Dis Child. 2003;88(5):414-8.). Such protocols typically take 30-40 minutes and can be prolonged, especially in pediatric examinations. Therefore, the screening test should be more concise, and we evaluated the value of a dedicated sellar MRI protocol to evaluate the HPA and an additional T2WI of the entire brain without contrast enhancement in girls with CPP. This simplified dedicated protocol shortened the scanning time by 10-15 min, resulting in a reduction in anxiety of the parents and patients and lower costs, due to not performing sedation or using a contrast medium.

Because pituitary microadenoma and Rathke’s cleft cyst can only be seen in contrast-enhanced images, and the diagnosis of these lesions can be missed in non-contrast images. Nevertheless, the clinical significance of these lesions in girls with CPP has not been demonstrated. It would have been ideal to compare this proposed protocol with contrast enhancement methods to validate the protocol, but this would be ethically problematic and practically impossible. By contrast, comparing a historical cohort of CPP patients who underwent contrast-enhanced MRI with a group that did not undergo contrast-enhanced MRI is possible. These data would significantly increase the value of the study.

We could not rule out the possibility that some brain lesions were not found due to the lack of MRI contrast enhancement in the study protocol, but we were able to describe the morphometry of the pituitary gland and analyzed the correlations between pituitary morphology and the clinical parameters of the patients. The height and shape of the pituitary gland varied among patients on sellar MRI. We were interested in determining whether there were correlations with pituitary height and shape. Patients with an increased pituitary height were significantly heavier, taller, and at a later Tanner stage than those with normal pituitary height. No significant difference in mid-parental height was observed between the two groups. Among the other laboratory parameters, basal and peak LH levels were significantly higher in the pituitary hyperplasia group. The pituitary height cutoff standard in our study referred to the pituitary hyperplasia standard in previous studies. In the future, it will be necessary to establish objective standards by comparing a normal control group of the same age.

In addition, patient weight, height, BMI, Tanner stage of breast development, and the baseline/peak LH ratio were significantly greater in those with a larger pituitary grade as determined by sellar MRI. In other words, the values of the clinical parameters tended to be increased significantly in accordance with the convex nature of the pituitary gland’s upper margin. No significant increasing or decreasing trends were observed for mid-parental height.

BMI (SDS) tended to increase with maturation of the pituitary shape (p = 0.049).

The present study had several limitations. First, our patients only underwent unenhanced MRI, so we could not compare the diagnostic utility between unenhanced and contrast-enhanced MRI results. Second, the proportion of patients aged > 8 years was larger than in previous studies; this may have affected the results. Third, a single-center study is subject to a number of biases, including selection bias, which may limit the generalizability of the findings; however, the results are meaningful due to the large sample size.

In conclusion, unenhanced dedicated sellar MRI of the HPA, with additional T2WI of the brain region, provided valuable information to detect organic lesions and determine pituitary gland morphology. We observed a significantly low prevalence of brain lesions among girls with CPP. As this was only a non-contrast study, comparative studies with contrast-enhanced MRI are required to validate the proposed protocol. Analysis of the correlations between the clinical characteristics and sellar MRI findings indicated that patient weight, height, BMI, Tanner stage, and LH level were associated with pituitary height or shape on sellar MRI. The results of this study suggest that clinicians should carefully examine the morphology of the pituitary gland in addition to determination of pathological causes of CPP on MRI in these patients.

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