Hypopituitarism and growth hormone deficiency in adult subjects after traumatic brain injury: who and when to test

Identifying Growth Hormone Deficiency in Brain-Injured Patients: The Quality of Life Scale-99

Traumatic brain injury (TBI) is frequently associated with hypopituitarism. The hypothalamic-pituitary axis appears to be susceptible to the same forces that cause injury to the parenchyma of the brain. Following even a mild TBI (mTBI), patients may suffer transient or permanent decreases in anterior pituitary hormones, including somatotropin (growth hormone [GH]), gonadotropins (luteinizing hormone and follicle-stimulating hormone), thyrotropin, and adrenocorticotropic hormone, with the most frequent long-term deficiency being GH deficiency (GHD). GHD is common after mTBI and is often the cause of persistent post-concussive symptoms a year or more post-injury. GHD is known to cause physical and cognitive fatigue, cognitive inefficiency, metabolic changes, and a range of psychological symptoms. Confusing the picture is that some symptoms of GHD are also common to brain injury itself. To facilitate the detection of GHD when comorbid with TBI, we utilized a new symptom inventory, the Quality-of-Life Scale-99 (QoLS-99), and administered it to a cohort of chronic TBI subjects with and without GHD, distinguished using the insulin tolerance test (ITT). Between 2018 and 2023, 371 patients completed the QoLS-99, of which 263 underwent GH testing with the ITT. Of these 263 patients, 136 (52%) were diagnosed with GHD. A retrospective comparison of QoLS-99 scores found that loss of libido (p < 0.006), a reliance on sleep aids (p < 0.011), and feeling overweight (p < 0.015) were the strongest univariate predictors of GHD. Most survey items did not elicit a significant difference in response between the GHD groups, and for those that did, effect sizes were mild to moderate. Still, initial findings demonstrate strong predictive value in a subset of survey items (i.e., GHD symptoms) that are most discriminating in the sample of patients with TBI. A multivariate prediction model using this subset of questions was able to differentiate GHD status in patients with TBI, correctly identifying 88% of GHD cases with a 37% false positive rate. Based on these findings, we recommend that clinicians inquire about libido, insomnia, and body image as potential markers for GHD. Furthermore, given the amenability of patients with GHD to growth hormone replacement therapy, we strongly encourage clinicians and basic scientists to develop interventions for the large and underserved population of patients with TBI with comorbid GHD.

Pituitary pathology in traumatic brain injury: a review

PURPOSE

Traumatic brain injury most commonly affects young adults under the age of 35 and frequently results in reduced quality of life, disability, and death. In long-term survivors, hypopituitarism is a common complication.

RESULTS

Pituitary dysfunction occurs in approximately 20-40% of patients diagnosed with moderate and severe traumatic brain injury giving rise to growth hormone deficiency, hypogonadism, hypothyroidism, hypocortisolism, and central diabetes insipidus. Varying degrees of hypopituitarism have been identified in patients during both the acute and chronic phase. Anterior pituitary hormone deficiency has been shown to cause morbidity and increase mortality in TBI patients, already encumbered by other complications. Hypopituitarism after childhood traumatic brain injury may cause treatable morbidity in those survivors. Prospective studies indicate that the incidence rate of hypopituitarism may be ten-fold higher than assumed; factors altering reports include case definition, geographic location, variable hospital coding, and lost notes. While the precise pathophysiology of post traumatic hypopituitarism has not yet been elucidated, it has been hypothesized that, apart from the primary mechanical event, secondary insults such as hypotension, hypoxia, increased intracranial pressure, as well as changes in cerebral flow and metabolism may contribute to hypothalamic-pituitary damage. A number of mechanisms have been proposed to clarify the causes of primary mechanical events giving rise to ischemic adenohypophysial infarction and the ensuing development of hypopituitarism.

CONCLUSION

Future research should focus more on experimental and clinical studies to elucidate the exact mechanisms behind post-traumatic pituitary damage. The use of preventive medical measures to limit possible damage in the pituitary gland and hypothalamic pituitary axis in order to maintain or re-establish near normal physiologic functions are crucial to minimize the effects of TBI.

Hypopituitarism After Traumatic Brain Injury

Acquired hypopituitarism is associated with traumatic brain injury. This neuroendocrine dysfunction can cause both short-term and long-term morbidity resulting in a cognitive, physiological, and behavioral decline, which increases the burden of the disease and the cost of care. Data in the trauma literature is derisory on this subject. The aim of this review is to edify clinicians on this condition, outline the screening criteria and methods for hypopituitarism after traumatic brain injury, and bring awareness to the chronic effects.

Neuroendocrine Abnormalities Following Traumatic Brain Injury: An Important Contributor to Neuropsychiatric Sequelae

Neuropsychiatric symptoms following traumatic brain injury (TBI) are common and contribute negatively to TBI outcomes by reducing overall quality of life. The development of neurobehavioral sequelae, such as concentration deficits, depression, anxiety, fatigue, and loss of emotional well-being has historically been attributed to an ambiguous "post-concussive syndrome," considered secondary to frank structural injury and axonal damage. However, recent research suggests that neuroendocrine dysfunction, specifically hypopituitarism, plays an important role in the etiology of these symptoms. This post-head trauma hypopituitarism (PHTH) has been shown in the past two decades to be a clinically prevalent phenomenon, and given the parallels between neuropsychiatric symptoms associated with non-TBI-induced hypopituitarism and those following TBI, it is now acknowledged that PHTH is likely a substantial contributor to these impairments. The current paper seeks to provide an overview of hypothesized pathophysiological mechanisms underlying neuroendocrine abnormalities after TBI, and to emphasize the significance of this phenomenon in the development of the neurobehavioral problems frequently seen after head trauma.

Analytical challenges for measuring steroid responses to stress, neurodegeneration and injury in the central nervous system

Levels of steroids in the adult central nervous system (CNS) show marked changes in response to stress, degenerative disorders and injury. However, their analysis in complex matrices such as fatty brain and spinal cord tissues, and even in plasma, requires accurate and precise analytical methods. Radioimmunoassays (RIA) and enzyme-linked immunosorbent assays, even with prepurification steps, do not provide sufficient specificity, and they are at the origin of many inconsistent results in the literature. The analysis of steroids by mass spectrometric methods has become the gold standard for accurate and sensitive steroid analysis. However, these technologies involve multiple purification steps prone to errors, and they only provide accurate reference values when combined with careful sample workup. In addition, the interpretation of changes in CNS steroid levels is not an easy task because of their multiple sources: the endocrine glands and the local synthesis by neural cells. In the CNS, decreased steroid levels may reflect alterations of their biosynthesis, as observed in the case of chronic stress, post-traumatic stress disorders or depressive episodes. In such cases, return to normalization by administering exogenous hormones or by stimulating their endogenous production may have beneficial effects. On the other hand, increases in CNS steroids in response to acute stress, degenerative processes or injury may be part of endogenous protective or rescue programs, contributing to the resistance of neural cells to stress and insults. The aim of this review is to encourage a more critical reading of the literature reporting steroid measures, and to draw attention to the absolute need for well-validated methods. We discuss reported findings concerning changing steroid levels in the nervous system by insisting on methodological issues. An important message is that even recent mass spectrometric methods have their limits, and they only become reliable tools if combined with careful sample preparation.

Differences according to Sex in Sociosexuality and Infidelity after Traumatic Brain Injury

OBJECTIVE

To explore differences according to sex in sociosexuality and infidelity in individuals with TBI and in healthy controls.

PARTICIPANTS

Forty-two individuals with mild, moderate, and severe TBI having completed a postacute TBI rehabilitation program, at least six months after injury, and 47 healthy controls.

MAIN MEASURES

Sociosexual Orientation Inventory-Revised (SOI-R) and Attitudes toward Infidelity Scale.

RESULTS

Overall, men score significantly higher than women in sociosexuality. However, there was a nonsignificant trend towards a reduction of sociosexuality levels in men with TBI. Infidelity levels were comparable in healthy controls and individuals with TBI. In individuals with TBI, less acceptance of infidelity was significantly associated with an unrestricted sociosexual orientation, but not in healthy controls.

CONCLUSIONS

As documented in previous cross-cultural studies, men have higher levels of sociosexuality than women. However, men with TBI showed a tendency towards the reduction of sociosexuality. The possibility of a latent explanatory variable is suggested (e.g., post-TBI neuroendocrinological changes). TBI does not seem to have an impact on infidelity, but individuals with TBI who express less acceptance of infidelity also report a more promiscuous mating strategy regarding their behavior, attitudes, and desire. Theoretical implications are discussed in terms of evolutionary theories of human sexuality and neuropsychology.

Correlation of brain levels of progesterone and dehydroepiandrosterone with neurological recovery after traumatic brain injury in female mice

Traumatic brain injury (TBI) is an important cause of disability in humans. Neuroactive steroids, such as progesterone and dehydroepiandrosterone (DHEA), are neuroprotective in TBI models. However in order to design potential neuroprotective strategies based on neuroactive steroids it is important to determine whether its brain levels are altered by TBI. In this study we have used a weight-drop model of TBI in young adult female mice to determine the levels of neuroactive steroids in the brain and plasma at 24h, 72 h and 2 weeks after injury. We have also analyzed whether the levels of neuroactive steroids after TBI correlated with the neurological score of the animals. TBI caused neurological deficit detectable at 24 and 72 h, which recovered by 2 weeks after injury. Brain levels of progesterone, tetrahydroprogesterone (THP), isopregnanolone and 17β-estradiol were decreased 24h, 72 h and 2 weeks after TBI. DHEA and brain testosterone levels presented a transient decrease at 24h after lesion. Brain levels of progesterone and DHEA showed a positive correlation with neurological recovery. Plasma analyses showed that progesterone was decreased 72 h after lesion but, in contrast with brain progesterone, its levels did not correlate with neurological deficit. These findings indicate that TBI alters the levels of neuroactive steroids in the brain with independence of its plasma levels and suggest that the pharmacological increase in the brain of the levels of progesterone and DHEA may result in the improvement of neurological recovery after TBI.

Pituitary dysfunction after traumatic brain injury: a clinical and pathophysiological approach

Traumatic brain injury (TBI) is a growing public health problem worldwide and is a leading cause of death and disability. The causes of TBI include motor vehicle accidents, which are the most common cause, falls, acts of violence, sports-related head traumas, and war accidents including blast-related brain injuries. Recently, pituitary dysfunction has also been described in boxers and kickboxers. Neuroendocrine dysfunction due to TBI was described for the first time in 1918. Only case reports and small case series were reported until 2000, but since then pituitary function in TBI victims has been investigated in more detail. The frequency of hypopituitarism after TBI varies widely among different studies (15-50% of the patients with TBI in most studies). The estimates of persistent hypopituitarism decrease to 12% if repeated testing is applied. GH is the most common hormone lost after TBI, followed by ACTH, gonadotropins (FSH and LH), and TSH. The underlying mechanisms responsible for pituitary dysfunction after TBI are not entirely clear; however, recent studies have shown that genetic predisposition and autoimmunity may have a role. Hypopituitarism after TBI may have a negative impact on the pace or degree of functional recovery and cognition. What is not clear is whether treatment of hypopituitarism has a beneficial effect on specific function. In this review, the current data related to anterior pituitary dysfunction after TBI in adult patients are updated, and guidelines for the diagnosis, follow-up strategies, and therapeutic approaches are reported.

Hypopituitarism after traumatic brain injury

The prevalence of hypopituitarism after traumatic brain (TBI) injury is widely variable in the literature; a meta-analysis determined a pooled prevalence of anterior hypopituitarism of 27.5%. Growth hormone deficiency is the most prevalent hormone insufficiency after TBI; however, the prevalence of each type of pituitary deficiency is influenced by the assays used for diagnosis, severity of head trauma, and time of evaluation. Recent studies have demonstrated improvement in cognitive function and cognitive quality of life with substitution therapy in GH-deficient patients after TBI.

Is routine endocrine evaluation necessary after paediatric traumatic brain injury?

BACKGROUND

Traumatic brain injury (TBI) is a common event in childhood. It is a recognised cause of hypopituitarism both in adult and paediatric patients. Routine endocrine evaluation has been proposed for adult TBI-survivors; nevertheless, incongruous data have been reported in children.

AIM

The goal of this study was to describe the prevalence of pituitary dysfunction after TBI in a cohort of children.

MATERIAL/SUBJECTS AND METHODS

This is a cross-sectional study comprising retrospective medical record review and prospective testing. Children with brain injury discharged from the Paediatric Intensive Care Unit from year 2004 to 2009 were recruited. Height and weight were recorded, systemic examination was performed and baseline pituitary function tests were undertaken. Provocative tests were performed only if abnormal basal levels were detected.

RESULTS

Thirty-six patients were collected; the mean age at assessment was 7.2 years and the mean interval since injury 3.3 years. All patients had skull fracture or intracranial haemorrhage; 36.6 % of them had moderate to severe TBI. No abnormalities were found on examination. Low serum IGF 1 levels were detected in four patients and two patients had low serum cortisol levels with inappropriately normal plasma ACTH concentrations. No evidence of pituitary dysfunction was observed in these patients after clinical follow-up, repeated baseline hormone levels or dynamic function tests.

CONCLUSIONS

No endocrine sequelae have been detected in this population. The routine endocrine evaluation in children with mild to moderate TBI might not be justified, according to our findings.

Hypopituitarism following traumatic brain injury: determining factors for diagnosis

Neuroendocrine dysfunction, long recognized as a consequence of traumatic brain injury (TBI), is a major cause of disability that includes physical and psychological involvement with long-term cognitive, behavioral, and social changes. There is no standard procedure regarding at what time after trauma the diagnosis should be made. Also there is uncertainty on defining the best methods for diagnosis and testing and what types of patients should be selected for screening. Common criteria for evaluating these patients are required on account of the high prevalence of TBI worldwide and the potential new cases of hypopituitarism. The aim of this review is to clarify, based on the evidence, when endocrine assessment should be performed after TBI and which patients should be evaluated. Additional studies are still needed to know the impact of post-traumatic hypopituitarism and to assess the impact of hormone replacement in the prognosis.

Negative effect of hypopituitarism following brain trauma in patients with diffuse axonal injury

Object

The aim of this prospective observational study was to assess the incidence and pattern of hypopituitarism after diffuse axonal injury (DAI) and to identify its effect on these patients in terms of functional outcome.

Methods

Of 1307 patients with traumatic brain injury treated at the authors' institution between March 2005 and June 2008, 65 patients with DAI were enrolled in the present study. The authors determined basal hormone levels, initial Glasgow Coma Scale scores, the Marshall CT grades, the presence of abnormal signal intensity indicating lesions on MR images, and duration of unconsciousness. At the 6-month follow-up visits, functional outcomes were estimated using the Modified Barthel Index. Univariate and multivariate analyses were performed to identify factors that influenced functional outcomes.

Results

Twenty-one patients with hypopituitarism (Group A) had more lesions in the body of the corpus callosum, basal ganglia, thalamus, and the gray–white matter junction than those without hypopituitarism (Group B). In Group A, growth hormone deficiency (17 patients, 80.9%) was the most common, and multiple pituitary hormone deficiencies were found in 12 patients (57.1%). The mean Modified Barthel Index score at the 6-month follow-up was 64.7 in Group A and 88.5 in Group B (p = 0.027). Duration of unconsciousness (p = 0.035), the Marshall CT grade (p = 0.021), hypopituitarism (p = 0.044), and abnormal signal intensities on MR imaging in midline or deep structures of the brain (p = 0.001) were found to be associated with functional outcome.

Conclusions

The findings in this prospective observational study suggest that hypopituitarism in patients with DAI has a relationship not only with injuries in the midline or deep structures of the brain, but also with a poor outcome.

Pituitary function in subjects with mild traumatic brain injury: a review of literature and proposal of a screening strategy

Traumatic brain injury (TBI) is an important public health problem all over the world. The level of consciousness of the patients and the severity of the brain injury is commonly evaluated by the Glascow Coma Scale as mild, moderate and severe TBI. When we consider the high frequency of mild TBI (MTBI) among the all TBI patients the burden of the pituitary dysfunction problem in this group could not be ignored. However, one of the most important and still unresolved questions is which patients with MTBI should be screened for hypopituitarism? Another type of head trauma which could be considered as the subgroup of MTBI is sports related chronic repetitive head trauma. Therefore, in this review we will discuss the frequency, characteristics and current management of pituitary dysfunction in patients with MTBI including the subjects exposed to sports related chronic mild head trauma.

Hypogonadism after traumatic brain injury

Traumatic brain injury (TBI) is the most common cause of death and disability in young adults. Post-TBI neuroendocrine disorders have been increasingly acknowledged in recent years due to their potential contribution to morbidity and, probably, to mortality after trauma. Marked alterations of the hypothalamic-pituitary axis during the post-TBI acute and chronic phases have been reported. Prospective and longitudinal studies have shown that some abnormalities are transitory. On the other hand, there is a high frequency (15% to 68%) of pituitary hormone deficiency among TBI survivors in a long term setting. Post-TBI hypogonadism is a common finding after cranial trauma, and it is predicted to develop in 16% of the survivors in the long term. Post-TBI hypogonadism has been associated with adverse results in the acute and chronic phases after injury. These data reinforce the need for identification of hormonal deficiencies and their proper treatment, in order to optimize patient recovery, improve their life quality, and avoid the negative consequences of non-treated hypogonadism in the long term.

Traumatic brain injury induced hypopituitarism in children and adolescents

Little is known with regard to traumatic brain injury (TBI)-induced hypopituitarism in children and adolescents and this may be due to the small number of reports on the topic. This review analyzed available pediatric data. Moderate or severe trauma are the risk factors for TBI-induced hypopituitarism. TBI-induced hypopituitarism in children and adolescents is uncommon, and may be transient or evolving in time. Only panhypopituitarism is persistent. The most common deficiencies are growth hormone and gonadotropin deficiency. TBI-induced hypopituitarism may have serious outcomes on growth, pubertal development, body composition, bone and brain development and function, which all affect recovery and rehabilitation of these young people after TBI. Raising awareness is necessary and multidisciplinary protocols should emerge.

Histologic study of the human pituitary gland in acute traumatic brain injury

PURPOSE

Approximately 25% of patients with traumatic brain injury (TBI) may develop partial or complete hypopituitarism. The causative mechanisms involved in its development are not clear. To the authors' knowledge, there have been no recent morphologic studies of the pituitary following TBI.

METHODS

To characterize the resultant histologic changes, this study investigated the pituitaries of 42 patients who died following a motor vehicle accident, all from the Mayo Tissue Registry. Twelve patients died instantly at the scene of the accident (Group I) whereas 30 survived between 3 hours and 7 days (Group II). All pituitary specimens were obtained at autopsy, formalin-fixed and paraffin-embedded. Hematoxylin-eosin sections cut in horizontal or sagittal plane were examined light-microscopically.

RESULTS

No infarction was noted in the pituitary specimens from group I. In group II, 13 of 30 (43%) showed acute infarcts of varying size. The extent of infarction in group II ranged from focal to sub-total necrosis involving 90% of the adenohypophysis.

CONCLUSIONS

Underlying adenohypophysial pathology in patients dying after TBI is acute infarction. Loss of large numbers of adenohypophysial cells causes reduced secretion of adenohypophysial hormones and may contribute to post-traumatic hypopituitarism.

Magnetic resonance imaging changes in the pituitary gland following acute traumatic brain injury

OBJECTIVE

The objective was to study the anatomical changes in the pituitary gland following acute moderate or severe traumatic brain injury (TBI).

DESIGN

Retrospective, observational, case-control study.

SETTING

Neurosciences Critical Care Unit of a university hospital.

PATIENTS

Forty-one patients with moderate or severe TBI who underwent magnetic resonance imaging (MRI) during the acute phase (less than seven days) of TBI. MRI scans of 43 normal healthy volunteers were used as controls.

INTERVENTIONS

None.

MEASUREMENTS AND MAIN RESULTS

Patient demographics, Acute Physiology and Chronic Health Evaluation II (APACHE II) score, Injury Severity Score (ISS), post-resuscitation Glasgow Coma Score (GCS), Glasgow Outcome Score (GOS), mean intracranial pressure (ICP), mean cerebral perfusion pressure (CPP), computed tomography (CT) data, pituitary gland volumes and structural lesions in the pituitary on MRI scans. The pituitary glands were significantly enlarged in the TBI group (the median and interquartile range were as follows: cases 672 mm3 (range 601-783 mm3) and controls 552 mm3 (range 445-620 mm3); p value<0.0001). APACHE II, GCS, GOS and ICP were not significantly correlated with the pituitary volume. Twelve of the 41 cases (30%) demonstrated focal changes in the pituitary gland (haemorrhage/haemorrhagic infarction (n=5), swollen gland with bulging superior margin (n=5), heterogeneous signal intensities in the anterior lobe (n=2) and partial transection of the infundibular stalk (n=1).

CONCLUSIONS

Acute TBI is associated with pituitary gland enlargement with specific lesions, which are seen in approximately 30% of patients. MRI of the pituitary may provide useful information about the mechanisms involved in post-traumatic hypopituitarism.

Traumatic brain injury-mediated hypopituitarism. Report of four cases

Hypopituitarism has been increasingly recognised following traumatic brain injury. We report four children involved in motor vehicle accidents who had traumatic brain injury-mediated hypopituitarism. Various hormone defects are described. Growth hormone was the most commonly affected pituitary hormone. The time interval between the injury and diagnosis of pituitary hormone deficiency was between 2.5 weeks to 1.5 years. Hormone replacement therapy permitted normal completion of growth and development. Awareness among physicians treating children with traumatic brain injury of the risk of hypopituitarism is necessary to optimise the outcome.

A single growth hormone determination 30 minutes after the administration of the GHRH plus GHRP-6 test is sufficient for the diagnosis of somatotrope dysfunction in patients who have suffered traumatic brain injury

As hypopituitarism is frequent in patients who have suffered a traumatic brain injury (TBI) a hormonal check-up is necessary. However, the prevalence of TBI is so large that the number of potential candidates to be tested is difficult to manage, in particular for GH deficiency diagnosis that requires cumbersome and expensive dynamic tests. GHRH plus GH-releasing hexapeptide (GHRP-6) is a safe and effective test capable of segregating normal subjects from GH deficient patients. As the GHRH+GHRP-6 test induces GH peaks consistently in the first 30 min, the working hypothesis assessed in this study was whether a single determination of GH 30 min after stimulus could provide the same biochemical classification as the whole secretory curve. A total of 83 subjects who suffered TBI at least one year before the study were administered GHRH 1 mug/kg iv plus GHRP-6 1 mug/kg iv at 0 min, and blood samples were obtained at regular intervals. GH was determined in all samples. An excellent correlation was observed between GH values at 30 min and GH peaks (r=0.972, p<0.0001). When comparing the 30-min GH values against the peaks, the biochemical classification changed only in 5 out of 83 subjects from normal GH secretion to uncertain.

CONCLUSIONS

The GHRH+GHRP-6 test is convenient, safe and in patients with TBI can be reduced to a single fixed GH determination 30 min after stimulus without losing diagnostic power.