Hypopituitarism after traumatic brain injury

Traumatic brain injury (TBI) is one of the main causes of death and disability in young adults, with consequences ranging from physical disabilities to long-term cognitive, behavioural, psychological and social defects. Post-traumatic hypopituitarism (PTHP) was recognized more than 80 years ago, but it was thought to be a rare occurrence. Recently, clinical evidence has demonstrated that TBI may frequently cause hypothalamic-pituitary dysfunction, probably contributing to a delayed or hampered recovery from TBI. Changes in pituitary hormone secretion may be observed during the acute phase post-TBI, representing part of the acute adaptive response to the injury. Moreover, diminished pituitary hormone secretion, caused by damage to the pituitary and/or hypothalamus, may occur at any time after TBI. PTHP is observed in about 40% of patients with a history of TBI, presenting as an isolated deficiency in most cases, and more rarely as complete pituitary failure. The most common alterations appear to be gonadotropin and somatotropin deficiency, followed by corticotropin and thyrotropin deficiency. Hyper- or hypoprolactinemia may also be present. Diabetes insipidus may be frequent in the early, acute phase post-TBI, but it is rarely permanent. Severity of TBI seems to be an important risk factor for developing PTHP; however, PTHP can also manifest after mild TBI. Accurate evaluation and long-term follow-up of all TBI patients are necessary in order to detect the occurrence of PTHP, regardless of clinical evidence for pituitary dysfunction. In order to improve outcome and quality of life of TBI patients, an adequate replacement therapy is of paramount importance.     

Hypopituitarism following traumatic brain injury.

Recent studies have demonstrated that hypopituitarism, and in particular growth hormone (GH) deficiency, is common among survivors of traumatic brain injury (TBI) tested several months or years following head trauma. In addition, it has been shown that post-traumatic neuroendocrine abnormalities occur early and with high frequency. These findings may have significant implications for the recovery and rehabilitation of patients with TBI. Although data emerging after 2000 demonstrate the relevance of the problem, in general there is a lack of awareness in the medical community about the incidence and clinical repercussions of the pathology. Most, but not all, head trauma associated with hypopituitarism is the result of motor accidents. The subjects at risk are those who have suffered moderate-to severe head trauma although mild intensity trauma may precede hypopituitarism also. Particular attention should be paid to this problem in children and adolescents. Onset of pituitary deficits can evolve over years following injury. For the assessment of the GH-IGF axis in TBI patients, plasma IGF-I concentrations, plus dynamic GH testing is indicated. Some degree of hypopituitarism is found in 35-40% of TBI patients. Among multiple pituitary deficits, the most common ones were GHD and gonadotrophin deficiency. In most series 10-15% presented with severe GHD and 15% with partial GHD after stimulating GH secretion confirming that the most common isolated deficit is GHD. Psychometric evaluation together with neurocognitive testing shows variability of disability and the possibility that untreated TBI induced hypopituitarism contributes to the chronic neurobehavioral problems seen in many head-injured patients warrants consideration. Preliminary data, from small pilot, open-label studies show that subjects treated with GH experience significant improvements in concentration, memory, depression, anxiety and fatigue. In conclusion, pituitary failure can occur even in minor head injuries and is poorly recognized.     

Hypopituitarism following severe traumatic brain injury.

Although hypopituitarism is a known complication of traumatic head injury, it may be under-recognized due to its subtle clinical manifestations. To address this issue, we determine the prevalence of neuroendocrine abnormalities in patients rehabilitating from severe traumatic brain injury (Glasgow Coma Scale < or = 8). 76 patients (mean age 39 +/- 14 yr; range 18-65; 53 males and 23 females; BMI 25.8 +/- 4.2 kg/m2; mean +/- SD) with a severe traumatic brain injury, an average of 22 +/- 10 months before this study (median, 20 months), underwent a series of standard endocrine tests, including TSH, free T4, T4, T3, prolactin, testosterone (males), estradiol (females), cortisol, ACTH, GH, and IGF-I. All subjects also underwent GH response to GHRH + arginine. Growth hormone deficiency (GHD) was defined as a GH response < 9 microg/L to GHRH + arginine and was confirmed by ITT (< 3 microg/L). Pituitary deficiency was shown in 24% of the patients (18/76). 8% (n = 6) had GHD (GH-peak range [GHRH + arginine]: 2.8-6.3 microg/L; GH-peak range [ITT]: 1.5-2.2 microg/L; IGF-I range: 62-174 microg/L). 17% (n = 13) had hypogonadism (total testosterone < 9.5 nmol/L and low gonadotropins in 12 males; low estradiol, and low gonadotropins in 1 female). Total testosterone levels did not correlate with BMI or age. 2 males with hypogonadism also showed a mild hyperprolactinemia (33 and 41 ng/ml). 3% (n = 2) patients had partial ACTH-deficiency (cortisol-peak [ITT] 392 and 417 nmol/L) and 3% (n = 2) had TSH-deficiency. In summary, we have found hypopituitarism in one-fourth of patients with predominantly secondary hypogonadism and GHD. These findings strongly suggest that patients who suffer head trauma must routinely include neuroendocrine evaluations.     

Hypopituitarism induced by traumatic brain injury in the transition phase

Traumatic brain injury (TBI) has been associated with hypopituitarism in general and GH deficiency (GHD) in particular; the consequences of this on growth and development are likely to be critical in children and adolescents in the so-called "transition phase". In order to verify the consequences of TBI on pituitary function in the transition phase, we studied a population of adolescents and young adults 3 and 12 months after brain injury [no. = 23, 9 females, 14 males; age: 16-25 yr; body mass index (BMI): 21.9 +/- 0.6 kg/m2]. At 3 months, hypopituitarism was present in 34.6%. Total, multiple and isolated deficits were present in 8.6, 4.3 and 21.7%, respectively. Diabetes insipidus (DI) was present in 8.6% patients and mild hyperprolactinemia in 4.3%. At 12 months, hypopituitarism was present in 30.3%. Total, multiple and isolated deficits were present in 8.6, 4.3 and 17.4%, respectively. DI was present in 4.3% of patients and mild hyperprolactinemia in 4.3%. Total hypopituitarism was always confirmed at retesting. Multiple and isolated hypopituitarism were confirmed in 0/1 and 2/5, respectively. Two/23 patients showed isolated hypopituitarism at 12 months only; 1 patient with isolated at 3 months showed multiple hypopituitarism at retesting. GHD and secondary hypogonadism were the most common acquired pituitary deficits. These results show the high risk of TBI-induced hypopituitarism also in the transition age. Thus it is recommended that pediatric endocrinologists follow-up pituitary function of children and adolescents after brain injuries.     

重视急性脑损伤后非神经系统器官损伤和功能障碍的防治

严重急性脑损伤后常并发心、肺和胃肠等颅外非神经器官损伤和功能障碍,是影响急性脑损伤患者早期死亡的主要因素。本文总结了急性脑损伤后心、肺和胃肠并发症的发生率和危害、病理生理和防治策略,以引起临床医师的重视,加强急性脑损伤后颅外非神经器官损伤和功能障碍的防治。     

Hypopituitarism following traumatic brain injury (TBI): a guideline decalogue

In order to gain further insight into hypopituitarism, that ensues moderate to severe traumatic brain injury (TBI), a group of experts actively working in the field gathered to exchange recent data and concepts. The objective arising from the meeting was to enhance the awareness of both medical specialists and health care administrators on the problem, whose prevalence is higher than previously thought. Guidelines for the diagnosis and management of TBI-mediated hypopituitarism were produced.     

Hypopituitarism in childhood and adolescence following traumatic brain injury: the case for prospective endocrine investigation

Pituitary dysfunction is now well recognised after traumatic brain injury (TBI) in adults; however, little except anecdotal evidence is known about this potential complication in childhood and adolescence. Histopathological evidence exists for both hypothalamic and pituitary damage, but few data specific to children have been published. We review the available paediatric data, which shows that after both mild and severe TBI, hypopituitarism may occur, with GH and gonadotrophin deficiencies appearing to be most common. Precocious puberty has also been documented. Road-traffic accidents, falls, sport and child abuse are the most common aetiological factors for paediatric TBI. There are no published data on the incidence or prevalence, neither within a population of children with TBI, of hypopituitarism, nor on its natural history or response to hormone replacement. We urge paediatric endocrinologists, in collaboration with adult endocrinologists, to perform formal prospective research studies in patients suffering from TBI to clarify these questions.     

Hypopituitarism is uncommon after aneurysmal subarachnoid haemorrhage

Objective Aneurysmal subarachnoid haemorrhage (SAH) has recently been reported as a common cause of chronic hypopituitarism, and introduction of routine neuroendocrine screening has been advocated. We aimed at estimating the risk of hypopituitarism after SAH using strict criteria including confirmatory testing in case of suggested insufficiency. Design Cross‐sectional evaluation with a nested prospective subgroup. Patients and measurements Endocrine evaluation was performed at a median of 14 months (range 11–26) post‐SAH in 62 patients with SAH and 30 healthy controls. Twenty‐six patients were followed prospectively (median 7 days, and 12 months post‐SAH). Endocrine evaluation included baseline evaluation, which was combined with an insulin tolerance test (ITT) or, if contraindicated, GHRH + arginine tests and a standard ACTH test at evaluation 1–2 years post‐SAH. Pituitary insufficiencies were confirmed by re‐evaluation. Results Early post‐SAH hormone alterations mimicking central hypogonadism were present in 58% of the patients and associated with a worse clinical state (P < 0·05). One to 2 years post‐SAH, initial neuroendocrine evaluation identified seven patients (11%) with abnormal results; three had free T4 and TSH suggestive of central hypothyroidism, three men had testosterone below 10 nm , and one had an insufficient GH and cortisol response to the ITT. None of these abnormalities was confirmed upon confirmatory testing. Conclusion In the largest reported cohort of patients with SAH to date, with early and late endocrine evaluation, none of the patients had chronic hypopituitarism. Based on these findings, the introduction of routine neuroendocrine screening is not justified, and the data suggest the importance of using strict diagnostic criteria in patients with a low pretest probability of hypopituitarism.     

肿瘤坏死因子α在大鼠脑外伤后急性胃黏膜病变中的作用

目的:检测肿瘤坏死因子α(TNF-α)在大鼠脑外伤后急性胃黏膜病变前后的含量并探讨其意义.方法:采用改良的Allen法建立大鼠颅脑外伤并发急性胃黏膜病变模型,同时设立假手术对照组,测定不同时间点(1,3,6,24h)各组大鼠血清中TNF-α含量及胃黏膜溃疡指数,并观察胃黏膜大体及光镜下组织病理学改变.结果:模型组1,3,6,24h血清中TNF-α含量明显高于对照组(t=16.45,P=0.000;r=5.252,P=0.000;t=9.099,P=0.000;t=12.028,P= 0.000).模型组胃黏膜损伤严重,6,24h点溃疡指数明显高于对照组(t=7.275,P=0.000;t= 10.579,P=0.000),TNF-α含量与溃疡指数呈线性正相关(r=0.68,P=0.004),组织学也有相应改变.结论:TNF-α在颅脑外伤急性胃黏膜病变的发病中起一定作用.     

蛛网膜下腔出血后早期脑损伤

蛛网膜下腔出血(subarachnoid hemorrhage,SAH)是一种致残率和病死率很高的疾病,临床仍缺乏有效的治疗手段.近年来的研究发现,早期脑损伤可能是导致SAH患者病死率较高和决定预后的首要原因.文章主要对SAH早期脑损伤的动物模型和发病机制做了综述.     

Hormonal diseases after traumatic brain injury

Traumatic brain injury represents major medical and social problem in all developed countries. Its incidence is about 200 per 100,000 inhabitants per year. In the acute phase immediately after injury the posterior pituitary dysfunction is well-known. The incidence of severe grossly hypernatremic cases of diabetes insipidus (DI) is about 3%, less severe form of ADH insufficiency was recognized in 21-26%. The syndrome of inappropriate antidiuretic hormone secretion (SIADH) was described in about 14%. These changes are transient in most cases, persisting DI has an incidence of 5-7% and SIADH cases recover almost always. Since the beginning of this century several series evaluating prospectively all patients after moderate to severe TBI have been published. Permanent hypopituitarism was found in one quarter to one half of them. The most common turned out to be the growth hormone (17.6%) and gonadotropic (13.4%) deficiency. Less common is the corticotropic (8.4%) and thyrotropic (4.3%) insufficiency. In the majority of patients an isolated dysfunction was discovered. However, in 9%, a combined failure of two or more HPA axis was present. This paper describes the minimum investigation needed to diagnose hypopituitarism by patients after TBI, who may profit from substitution therapy.     

Hypopituitarism findings in patients with primary brain tumors 1 year after neurosurgical treatment: preliminary report

Hypopituitarism represents the consequence of many conditions, in both the adult and child population. It may occur after neurosurgical treatment of brain tumors arising near sella turcica. Much more attention has been focused on lesions far from the hypothalamic-pituitary region as possible causes of pituitary impairment, validating the concept of the particular fragility of these structures. The aim of this study was to evaluate pituitary function in particular GH deficiency (GHD) in patients submitted to neurosurgery for benign tumors of the central nervous system (CNS) not involving hypothalamic-pituitary region. We observed 37 patients with benign brain tumors [13 males, 24 females, age: 54.6+/-13.9 yr; body mass index (BMI): 25.1+/-4.0 kg/m2] performing a basic evaluation of the pituitary function and a dynamic test of the GH/IGF-I axis [GHRH (1 microg/kg iv)+arginine (0.5 g/kg iv) test] for 3 and 12 months after the neurosurgical treatment. Some degree of hypopituitarism was shown in 16 patients (43.2%) at the 3-months follow-up. Hypogonadism was present in 4 patients, hypoadrenalism in another 4 and hypothyroidism in 2. Two patients showed mild hyperprolactinemia and no patients had diabetes insipidus. Seven patients (18.9%) were GH deficient (peak GH <16.5 microg/dl). At 12 months retesting, some degree of hypopituitarism was confirmed in 8 patients, hypogonadism in 2 and hypothyroidism in one; no patients showed hypoadrenalism and GHD was present in 5. This data suggests that hypopituitarism of various degree may develop in patients who are submitted to neurosurgery for primary brain tumors, even far from hypothalamic-pituitary region.     

Recurrent hyponatremia after traumatic brain injury

Dysregulation of the neuroendocrine system is a frequent complication after traumatic brain injury (TBI). Symptoms of these hormonal abnormalities might be subtle and thus easily ignored. Hyponatremia usually indicates underlying disorders that disrupt fluid homeostasis. In most patients with TBI, hyponatremia is a feature of the syndrome of inappropriate antidiuretic hormone (SIADH) secretion due to pituitary dysfunction after head injury. Usually TBI-associated hyponatremia is transient and reversible. We report the case of a 48-year-old man with TBI-associated hyponatremia with delayed recovery and recurrent hyponatremia precipitated by subsequent surgery. In this report, we emphasize the importance of identifying patients with slow recovery of the injured brain, which could complicate with SIADH and acute hyponatremia. Differentiating TBI-associated SIADH from other important causes of hyponatremia such as cerebral salt wasting, and hypocortisonism are also reviewed. Prevention of its recurrence by avoiding further risk is mandatory in managing patients with TBI.     

Developmental traumatic brain injury decreased brain derived neurotrophic factor expression late after injury

Pediatric traumatic brain injury (TBI) is a major cause of acquired cognitive dysfunction in children. Hippocampal Brain Derived Neurotrophic Factor (BDNF) is important for normal cognition. Little is known about the effects of TBI on BDNF levels in the developing hippocampus. We used controlled cortical impact (CCI) in the 17 day old rat pup to test the hypothesis that CCI would first increase rat hippocampal BDNF mRNA/protein levels relative to SHAM and Na?ve rats by post injury day (PID) 2 and then decrease BDNF mRNA/protein by PID14. Relative to SHAM, CCI did not change BDNF mRNA/protein levels in the injured hippocampus in the first 2 days after injury but did decrease BDNF protein at PID14. Surprisingly, BDNF mRNA decreased at PID 1, 3, 7 and 14, and BDNF protein decreased at PID 2, in SHAM and CCI hippocampi relative to Na?ve. In conclusion, TBI decreased BDNF protein in the injured rat pup hippocampus 14 days after injury. BDNF mRNA levels decreased in both CCI and SHAM hippocampi relative to Na?ve, suggesting that certain aspects of the experimental paradigm (such as craniotomy, anesthesia, and/or maternal separation) may decrease the expression of BDNF in the developing hippocampus. While BDNF is important for normal cognition, no inferences can be made regarding the cognitive impact of any of these factors. Such findings, however, suggest that meticulous attention to the experimental paradigm, and possible inclusion of a Na?ve group, is warranted in studies of BDNF expression in the developing brain after TBI.     

Hypopituitarism

Hypopituitarism is usually caused by tumours of the hypothalamus-pituitary region, but may also arise as the consequence of pituitary inflammation, infiltration or hypoperfusion. Tumour mass reduction by surgical intervention or following drug treatment may improve pituitary function. However, neurosurgical tumour resection and radiation therapy may lead to a permanent manifestation of hypopituitarism. Diagnosis is established by endocrine testing, revealing the characteristic low serum concentrations of both peripheral hormone and associated regulatory hormone of pituitary origin. Hypopituitarism may involve from one to all endocrine axes regulated by the pituitary (in order of frequency: growth hormone deficiency>secondary hypogonadism>secondary hypothyroidism>secondary adrenal failure). The treatment of permanent hypopituitarism consists of replacement of the peripheral hormones (hydrocortisone, DHEA, thyroxine, testosterone or oestradiol, growth hormone). Quality of life is impaired in a considerable number of patients with hypopituitarism and mortality is increased, mostly due to cardiovascular and cerebrovascular causes, but also as a consequence of recurrent respiratory infections. Long-term care and monitoring of patients with hypopituitarism requires the experienced endocrinologist.     

Hypopituitarism

Incidence and prevalence of hypopituitarism are estimated to be 4.2 per 100,000 per year and 45.5 per 100,000, respectively. Although the clinical symptoms of this disorder are usually unspecific, it can cause life-threatening events and lead to increased mortality. Current research has refined the diagnosis of hypopituitarism. Identification of growth hormone and corticotropin deficiency generally requires a stimulation test, whereas other deficiencies can be detected by basal hormones in combination with clinical judgment. Newly developed formulations of replacement hormones are convenient and physiological. Work has shown that many patients with brain damage--such as traumatic brain injury or aneurysmal subarachnoid haemorrhage--are at high risk of (sometimes unrecognised) hypopituitarism. Thus, a much increased true prevalence of this disorder needs to be assumed. As a result, hypopituitarism is not a rare disease and should be recognised by the general practitioner.     

Hypopituitarism

Hypopituitarism is the partial or complete insufficiency of anterior pituitary hormone secretion and may result from pituitary or hypothalamic disease. The reported incidence (12–42 new cases per million per year) and prevalence (300–455 per million) is probably underestimated if its occurrence after brain injuries (30–70% of cases) is considered. Clinical manifestations depend on the extent of hormone deficiency and may be non specific, such as fatigue, hypotension, cold intolerance, or more indicative such as growth retardation or impotence and infertility in GH and gonadotropin deficiency, respectively. A number of inflammatory, granulomatous or neoplastic diseases as well as traumatic or radiation injuries involving the hypothalamic-pituitary region can lead to hypopituitarism. Several genetic defects are possible causes of syndromic and non syndromic isolated/multiple pituitary hormone deficiencies. Unexplained gonadal dysfunctions, developmental craniofacial abnormalities, newly discovered empty sella and previous pregnancy-associated hemorrhage or blood pressure changes may be associated with defective anterior pituitary function. The diagnosis of hypopituitarism relies on the measurement of basal and stimulated secretion of anterior pituitary hormones and of the hormones secreted by pituitary target glands. MR imaging of the hypothalamo-pituitary region may provide essential information. Genetic testing, when indicated, may be diagnostic. Secondary hypothyroidism is a rare disease. The biochemical diagnosis is suggested by low serum FT4 levels and inappropriately normal or low basal TSH levels that do not rise normally after TRH. L-thyroxine is the treatment of choice. Before starting replacement therapy, concomitant corticotropin deficiency should be excluded in order to avoid acute adrenal insufficiency. Prolactin deficiency is also very rare and generally occurs after global failure of pituitary function. Prolactin deficiency prevents lactation. Hypogonadotropic hypogonadism in males is characterized by low testosterone with low or normal LH and FSH serum concentrations and impaired spermatogenesis. Hyperprolactinemia as well as low sex hormone binding globulin concentrations enter the differential diagnosis. Irregular menses and amenorrhea with low serum estradiol concentration (<100 pmol/l) and normal or low gonadotropin concentrations are the typical features of hypogonadotropic hypogonadism in females. In post menopausal women, failure to detect high serum gonadotropin values is highly suggestive of the diagnosis. In males, replacement therapy with oral or injectable testosterone results in wide fluctuations of serum hormone levels. More recently developed transdermal testosterone preparations allow stable physiological serum testosterone levels. Pulsatile GnRH administration can be used to stimulate spermatogenesis in men and ovulation in women with GnRH deficiency and normal gonadotropin secretion. Gonadotropin administration is indicated in cases of gonadotropin deficiency or GnRH resistance but is also an option, in alternative to pulsatile GnRH, for patients with defective GnRH secretion.