Is routine endocrine evaluation necessary after paediatric traumatic brain injury?

Protocol-Based Standardized Endocrinological Evaluation of Children With Traumatic Brain Injury: A Quality Improvement Initiative

INTRODUCTION

Traumatic brain injury (TBI) can disrupt the hypothalamo-pituitary axis, causing neuroendocrine dysfunction. As a third of children can develop post-traumatic hypothalamo-pituitary axis dysfunction (HPAD), a longitudinal follow-up is required in children with TBI.

METHOD

The study comprised a pre-quality improvement (QI) phase (baseline phase) and a QI phase (post-intervention phase). Retrospective data were collected on children with TBI at our hospital during the pre-QI phase of the study to estimate the baseline data on HPAD prevalence and pediatric endocrine referral rate. Guidance protocol for standardizing the pediatric endocrine referral, evaluation, and follow-up of children with TBI was implemented. Prospective data were collected to estimate outcome measures (prevalence of HPAD, rate of initial endocrine consultation and outpatient follow-up) and process measures (protocol adherence rate).

RESULT

Twenty-seven children, aged ≤19 years, were admitted with TBI in the pre-QI phase. The median age was 9 years. Motor vehicle accidents predominated. Thirty percent had limited endocrine evaluation, and 4% had transient cranial diabetes insipidus (DI). The QI phase included 8 children. Demographic data were similar to those in the pre-QI phase. Both outcome and process measures increased to 75% from the pre-QI phase following the protocol implementation.

CONCLUSION

A lower prevalence rate of HPAD in the current cohort may be owing to underevaluation and a smaller sample size. The QI initiative incorporating a guidance protocol-based endocrinological approach to children with TBI improved the pediatric endocrinology referral and follow-up rates.

Endocrine Abnormalities in Children With Traumatic Brain Injury at a Tertiary Care Center

Objective Accidental traumatic brain injury (TBI) can lead to severe complications such as endocrine abnormalities and long-term morbidities and can negatively impact patient lives. These conditions are also associated with a high cost of treatment over a lifetime, a significant concern in low-to-middle-income countries (LMICs). In Pakistan, the prevalence of children with endocrine abnormalities secondary to TBI remains largely unexplored. We conducted a retrospective cross-sectional study to estimate the burden of endocrine abnormalities due to TBI among children in our population. Methods Twenty patients previously admitted with head injury between September and October 2019 were retrospectively reviewed with tests for baseline serum sodium, plasma osmolality, cortisol, adrenocorticotropin (ACTH), free thyroxine (fT4), growth hormone (GH), insulin growth factor-1 (IGF-1), follicle-stimulating hormone (FSH), luteinizing hormone (LH), thyroid-stimulating hormone (TSH), prolactin, estradiol, and testosterone. Data were collated from the electronic Health and Information Management System (HIMS) and analyzed using SPSS v25. Chi-square and t-tests were used to identify associations between variable groups. Outcomes of interest included correlations between hormonal levels and demographic factors, interventions and hormonal levels, and complication rates and hormonal levels. Results Our study reports three (15% of the total cohort) patients with pituitary hormone deficits (two with low IGF-1 and one with low TSH). High serum IGF-1 and ACTH levels were also observed in three (15%) children. High IGF-1 was associated with female gender (p=0.007), mechanical ventilation (p=0.038), and falls (p=0.028). IGF-1 (p=0.035) and GH (p=0.049) levels were associated with improvement in Extended Glasgow Outcome Scale (GOS-E) score. Testosterone was positively correlated with a high percentile for height (p=0.005) and GOS-E scores on follow-up (p=0.030). High testosterone levels (592.12 ± 102.28 ng/dl) were associated with good functional outcomes in post-pubescent patients (p<0.05). Serum fT4 was linked with a high GOS-E score at discharge in prepubescent patients (p=0.034). Neurosurgical decompression was the only risk factor for hormone deficiency, comprising 67% of the group with hormone deficiencies (p=0.028). The learning difficulties were observed exclusively in children with hormonal deficiencies (7 patients, p=0.000).  Conclusion Hormonal dysfunction due to TBI in children can lead to poor outcomes. High serum IGF-1, testosterone, and free T4 levels were associated with improved functional outcomes in children with TBI. Limited follow-up and resources in LMICs are significant barriers to addressing the morbidity associated with these conditions and need to be addressed at a health policy level.

Recurrent hypoglycemic seizure as a presenting symptom of post-TBI hypopituitarism in children: a case report, review and proposed protocol

OBJECTIVES

Post-traumatic brain injury hypopituitarism is a common unrecognized condition in children after head injury. Due to its similarity of clinical symptoms with those of head trauma, clinical diagnosis of post-TBI hypopituitarism is challenging. To date, there is no standardized screening protocol for children with history of brain injury. This article demonstrates a case of 14-year-old boy with severe head trauma who developed refractory seizures with episodic hypoglycemia and weight loss. We aimed to focus on the prevalence, clinical courses and clinical implementations of each hormonal axis in children with post-traumatic brain injury hypopituitarism. We also aim to raise awareness of this condition to pediatricians in light of enhancing patient care.

METHODS

We have searched for original articles, published in English between year 2000 and 2021. There are 20 related articles, authors reviewed all the articles independently.

RESULTS

Prevalence of post-traumatic hypopituitarism ranges from 5-57% in children. Growth hormone is the most commonly affected hormone. The highest prevalence is 42.3% at more than 12 months after the brain injury. The symptoms and severity range from asymptomatic to requiring long-term hormonal therapy. Although normalization of pituitary function is demonstrated at various times after the injury, hormone replacement therapy is still required in some patients.

CONCLUSIONS

This is the first report that demonstrates a presenting symptom of hypopituitarism mimic traumatic brain symptoms which result in it being overlooked. This case emphasizes the need to develop pituitary function screening protocols for children with TBI. We have proposed our pituitary screening protocol for children with TBI in this article.

Evidence Limitations in Determining Sexually Dimorphic Outcomes in Pediatric Post-Traumatic Hypopituitarism and the Path Forward

Neuroendocrine dysfunction can occur as a consequence of traumatic brain injury (TBI), and disruptions to the hypothalamic-pituitary axis can be especially consequential to children. The purpose of our review is to summarize current literature relevant to studying sex differences in pediatric post-traumatic hypopituitarism (PTHP). Our understanding of incidence, time course, and impact is constrained by studies which are primarily small, are disadvantaged by significant methodological challenges, and have investigated limited temporal windows. Because hormonal changes underpin the basis of growth and development, the timing of injury and PTHP testing with respect to pubertal stage gains particular importance. Reciprocal relationships among neuroendocrine function, TBI, adverse childhood events, and physiological, psychological and cognitive sequelae are underconsidered influencers of sexually dimorphic outcomes. In light of the tremendous heterogeneity in this body of literature, we conclude with the common path upon which we must collectively arrive in order to make progress in understanding PTHP.

Epidemiology of Pediatric Traumatic Brain Injury and Hypothalamic-Pituitary Disorders in Arizona

Traumatic brain injury (TBI) in children can result in long-lasting social, cognitive, and neurological impairments. In adults, TBI can lead to endocrinopathies (endocrine system disorders), but this is infrequently reported in children. Untreated endocrinopathies can elevate risks of subsequent health issues, such that early detection in pediatric TBI survivors can initiate clinical interventions. To understand the risk of endocrinopathies following pediatric TBI, we identified patients who had experienced a TBI and subsequently developed a new-onset hypothalamic regulated endocrinopathy (n = 498). We hypothesized that pediatric patients who were diagnosed with a TBI were at higher risk of being diagnosed with a central endocrinopathy than those without a prior diagnosis of TBI. In our epidemiological assessment, we identified pediatric patients enrolled in the Arizona Health Care Cost Containment System (AHCCCS) from 2008 to 2014 who were diagnosed with one of 330 TBI International Classification of Diseases (ICD)-9 codes and subsequently diagnosed with one of 14 central endocrinopathy ICD-9 codes. Additionally, the ICD-9 code data from over 600,000 Arizona pediatric patients afforded an estimate of the incidence, prevalence, relative risk, odds ratio, and number needed to harm, regarding the development of a central endocrinopathy after sustaining a TBI in Arizona Medicaid pediatric patients. Children with a TBI diagnosis had 3.22 times the risk of a subsequent central endocrine diagnosis compared with the general population (±0.28). Pediatric AHCCCS patients with a central endocrine diagnosis had 3.2-fold higher odds of a history of a TBI diagnosis than those without an endocrine diagnosis (±0.29). Furthermore, the number of patients with a TBI diagnosis for one patient to receive a diagnosis of a central endocrine diagnosis was 151.2 (±6.12). Female subjects were more likely to present with a central endocrine diagnosis after a TBI diagnosis compared to male subjects (64.1 vs. 35.9%). These results are the first state-wide epidemiological study conducted to determine the risk of developing a hypothalamic-pituitary disorder after a TBI in the pediatric population. Our results contribute to a body of knowledge demonstrating a TBI etiology for idiopathic endocrine disorders, and thus advise physicians with regard to TBI follow-up care that includes preventive screening for endocrine disorders.

Should We Assess Pituitary Function in Children After a Mild Traumatic Brain Injury? A Prospective Study

Objective: The aim of this study was to evaluate the frequency of hypopituitarism following TBI in a cohort of children who had been hospitalized for mild TBI and to identify the predictive factors for this deficiency. Design: A prospective study was conducted on children between 2 and 16 years of age who had been hospitalized for mild TBI according to the Glasgow Coma Scale between September 2009 and June 2013. Clinical parameters, basal pituitary hormone assessment at 0, 6, and 12 months, as well as a dynamic testing (insulin tolerance test) 12 months after TBI were performed. Results: The study included 109 children, the median age was 8.5 years. Patients were examined 6 months (n = 99) and 12 months (n = 96) after TBI. Somatotropic deficiency (defined by a GH peak <20 mUI/l in two tests, an IGF-1 <-1SDS and a delta height <0SDS) were confirmed in 2 cases. One case of gonadotrophic deficiency occurred 1 year after TBI among 13 pubertal children. No cases of precocious puberty, 5 cases of low prolactin level, no cases of corticotropic insufficiency (cortisol peak <500 nmol/l) and no cases diabetes insipidus were recorded. Conclusion: Pituitary insufficiency was present 1year after mild TBI in about 7% of children. Based on our results, we suggest testing children after mild TBI in case of clinical abnormalities. i.e., for GH axis, IGF-1, which should be assessed in children with a delta height <0 SDS, 6 to 12 months after TBI, and a dynamic GH testing (preferentially by an ITT) should be performed in case of IGF-1 <-1SDS, with a GH threshold at 20 mUI/L. However, if a systematic pituitary assessment is not required for mild TBI, physicians should monitor children 1 year after mild TBI with particular attention to growth and weight gain.

Pituitary dysfunction after traumatic brain injury: are there definitive data in children?

In the past decade, several studies in adults and children have described the risk of pituitary dysfunction after traumatic brain injury (TBI). As a result, an international consensus statement recommended follow-up on the survivors. This paper reviews published studies regarding hypopituitarism after TBI in children and compares their results. The prevalence of hypopituitarism ranges from 5% to 57%. Growth hormone (GH) and ACTH deficiency are the most common, followed by gonadotropins and thyroid-stimulating hormone. Paediatric studies have failed to identify risk factors for developing hypopituitarism, and therefore we have no tools to restrict screening in severe TBI. In addition, the present review highlights the lack of a unified follow-up and the fact that unrecognised pituitary dysfunction is frequent in paediatric population. The effect of hormonal replacement in patient recovery is important enough to consider baseline screening and reassessment between 6 and 12 months after TBI. Medical community should be aware of the risk of pituitary dysfunction in these patients, given the high prevalence of endocrine dysfunction already reported in the studies. Longer prospective studies are needed to uncover the natural course of pituitary dysfunction, and new studies should be designed to test the benefit of hormonal replacement in metabolic, cognitive and functional outcome in these patients.

Post-traumatic hypopituitarism: report of a child case

Case

We report a case of post‐traumatic hypopituitarism in a 9‐year‐old boy who was injured in a car accident.

Outcome

Post‐traumatic hypopituitarism might be caused by moderate to severe head trauma, and while this possibility has recently drawn attention in adults, few reports are available regarding children. Our patient experienced head and facial injury, resulting in post‐traumatic hypopituitarism. Six hours after injury he suffered from diabetes insipidus and hormone replacement therapy was started. On day 12 he underwent facial fracture reduction under general anesthesia. On day 24 he was discharged from the hospital. One year after the injury, secretory function and water dehydration tests suggested the possibility of post‐traumatic hypopituitarism.

Conclusion

We experienced a child case of post‐traumatic hypopituitarism. Emergency physicians should pay attention to the possibility of post‐traumatic hypopituitarism in cases of traumatic brain injury.

Update of Endocrine Dysfunction following Pediatric Traumatic Brain Injury

Traumatic brain injuries (TBI) are common occurrences in childhood, often resulting in long term, life altering consequences. Research into endocrine sequelae following injury has gained attention; however, there are few studies in children. This paper reviews the pathophysiology and current literature documenting risk for endocrine dysfunction in children suffering from TBI. Primary injury following TBI often results in disruption of the hypothalamic-pituitary-adrenal axis and antidiuretic hormone production and release, with implications for both acute management and survival. Secondary injuries, occurring hours to weeks after TBI, result in both temporary and permanent alterations in pituitary function. At five years after moderate to severe TBI, nearly 30% of children suffer from hypopituitarism. Growth hormone deficiency and disturbances in puberty are the most common; however, any part of the hypothalamic-pituitary axis can be affected. In addition, endocrine abnormalities can improve or worsen with time, having a significant impact on children’s quality of life both acutely and chronically. Since primary and secondary injuries from TBI commonly result in transient or permanent hypopituitarism, we conclude that survivors should undergo serial screening for possible endocrine disturbances. High indices of suspicion for life threatening endocrine deficiencies should be maintained during acute care. Additionally, survivors of TBI should undergo endocrine surveillance by 6–12 months after injury, and then yearly, to ensure early detection of deficiencies in hormonal production that can substantially influence growth, puberty and quality of life.