Hypopituitarism laboratory findings

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Iqra Qamar M.D.[2]

Overview

A subnormal or reduced concentration of pituitary hormones is diagnostic of hypopituitarism. Patients with complete hormonal deficiencies are mostly symptomatic and have low serum concentrations of both, the pituitary hormones as well as the target-organ hormones. Patients having partial hormonal deficiencies are detected by dynamic tests/stimulatory tests such as corticotropin stimulation, insulin-induced hypoglycemia and metyrapone test. Corticotropin deficiency is detected by assessing basal cortisol secretion. Patients with intermediate cortisol levels need to be tested for adrenocorticotrophic hormone (ACTH) reserve. There are several tests to check the ACTH reserve. Metyrapone test is preferred over others as it is applicable to all adults with no age restriction and has good correlation with stress related cortisol response. Patients with hypopituitarism are screened for hypothyroidism by measuring thyroxine, total thyroxine (T4) and triiodothyronine (T3) uptake, and free T4. Gonadotropin deficiency is confirmed with low estradiol, low testosterone, and low/normal serum FSH/LH. Growth hormone deficiency is confirmed with provocative tests (insulin induced hypoglycemia and arginine and GHRH combination) for growth hormone (GH) secretion resulting in subnormal levels of serum GH levels, serum insulin-like growth factor-1 levels lower than the age-specific lower limit of normal and deficiency of more than one pituitary hormones, such as ACTH, TSH, and gonadotropins. ADH deficiency is assessed by water deprivation test and ADH suppression test. Prolactin deficiency can be confirmed by directly measuring prolactin levels on more than one occasion as its secretion is episodic but it is not done routinely as it is not clinically significant.

Laboratory Findings

Dynamic tests for making a diagnosis of hypopituitarism

Following dynamic tests can be used to make a diagnosis of hypopituitarism:[8][9][10][11][12][13][14][15][16]

Hormone Test Procedure Normal response
Growth hormone Insulin tolerance
  • Glucose should drop <40 mg/dL, (2.2 mmol/L)
  • GH should be >3–5 μg/L
  • Cut-offs for GH response are BMI related 
GHRH + arginine  
  • Administer GHRH, 1 μg/kg (max 100 μg) iv followed by an arginine infusion 0.5 g/kg (max 35 g) over 30 min
  • Sample blood at 0, 30, 45, 60, 75, 90, 105, and 120 min for GH
  • GH >4 μg/L, but cutoffs for GH response should be correlated to BMI (obesity may blunt GH response to stimulation)
Glucagon
  • Administer glucagon, 1 mg (1.5 mg if weight >90 kg) IM
  • Sample blood at 0, 30, 60, 90, 120, 150, 180, 210, and 240 min for GH and glucose
  • GH >3 μg/L, but cutoffs for GH response should be correlated to BMI (Obesity may blunt GH response to stimulation)
ACTH Insulin tolerance
  • Glucose should drop <40 mg/dL (2.2 mmol/L)
  • Peak cortisol should be >500–550 nmol/L (>18.1–20 μg/dL) depending on assay
Corticotropin standard dose (250 μg)
  • Sample blood at 0, 30, and 60 min for cortisol
  • Cortisol should be at 30 or 60 min >500–550 nmol/L (>18.1–20 μg/dL) depending on assay
Corticotropin low dose (1 μg)
  • Cortisol should be at 30 min >500 nmol/L (18.1 μg/dL) depending on assay
ADH Water deprivation test 
  • Initiate fluid deprivation for 8h (starting from 8 AM)
  • Weigh patient at beginning of testing, then measure weight and urine volume hourly during the test
  • At 4 PM administer DDAVP 2 μg im and allow patient to drink freely
Diabetes insipidus (DI): Plasma osmolality >295 mOsm/L with inappropriately hypotonic urine (urine osmolality/plasma osmolality ratio <2) during the fluid deprivation confirms DI (test is discontinued)

Partial/primary polydipsia: With partial DI or primary polydipsia, urine concentrates partially during the water deprivation test (300–800 mOsm/kg), and further investigation is required including a prolonged water deprivation test or DDAVP therapeutic trial

Notes for water deprivation test:

  • Continue measuring urine osmolality hourly for the next 4 h (after DDVAP administration) and measure hourly urine volumes.
  • Stop test if >3% weight loss occurs. 

Legend:

IV: Intravenous, IM: Intramuscular, GH: Growth hormone, GHD: Growth hormone deficiency, BMI: Body mass index

1.Corticotropin:

(a) Basal ACTH secretion:

The normal range of serum cortisol is 5 to 25 mcg/dL (138 to 690 nmol/L). Serum cortisol levels are measured at 8 to 9 am and results are interpreted as follows:

Serum cortisol Basal adrenocorticotrophic hormone (ACTH)
Low: ≤3 mcg/dL (83 nmol/L) Cortisol deficiency
High: ≥18 mcg/dL (497 nmol/L) No cortisol deficiency even in times of stress
Intermediate: >3 mcg/dL (83 nmol/L) 

but

<18 mcg/dL (497 nmol/L)

Needs evaluation for ACTH reserve

(b) ACTH reserve:

Metyrapone test:

Metyrapone blocks 11-beta-hydroxylase (CYP11B1), an enzyme that catalyzes the last step in cortisol production resulting in decreased cortisol and increased 11-deoxycortisol concentration. In this test 750 mg of Metyrapone is administered orally every 4 hours for 24 hours. Serum cortisol and 11-deoxycortisol concentration are checked at 8 am after 24 hours and the results are interpreted as follows:

Subject Cortisol level 11-deoxycortisol level
Normal subjects < 7 mcg/dL (172 nmol/L) ≥10 mcg/dL (289 nmol/L)
Patients with decreased ACTH reserve <7 mcg/dL (172 nmol/L) <10 mcg/dL (289 nmol/L)

2.Thyrotropin:

Patients with hypopituitarism are screened for hypothyroidism by measuring:[27]

Condition Serum T3 Serum free T4 Serum TSH
Central hypothyroidism Low or normal Low or low-normal Low, normal, or slightly high

3.Gonadotropins

Gonadotropin-releasing hormone test may be used to detect serum levels for gonadotropins (follicle stimulating hormones and luteinizing hormones) but repeated stimulations by gonadotropin-releasing hormone are required to make a diagnosis.

Females:

Secondary hypogonadism can be confirmed in an amenorrheic woman having:

Males:

4.Growth hormone

The following tests and laboratory findings can be used to confirm growth hormone (GH) deficiency in a patient having an organic pituitary disease:[28][29][30][31]

(a) Provocative tests for growth hormone (GH) secretion resulting in subnormal levels of serum GH levels.

GH provocative tests Serum GH levels
Insulin induced hypoglycemia <5.1 ng/mL
Arginine and GHRH combination <4.1 ng/mL

(b) Serum insulin-like growth factor-1 levels lower than the age-specific lower limit of normal. This test is useful in children but not in adults as up to 1/3rd of adults with confirmed GH deficiency have normal IGF-1 levels.

(c) Deficiency of more than one pituitary hormones e.g ACTH, TSH and gonadotropins. For more information on laboratory findings click here.

5.Antidiuretic hormone (ADH) deficiency

(a) Water deprivation test:

It is used to differentiate psychogenic polydipsia from diabetes insipidus. Water intake is restricted with continuous monitoring (as patients with psychogenic polydipsia try even to drink the toilet water) and hourly measurements of serum and urine osmolalities. Results are interpreted as follows:[32]

Condition Serum osmolality Urine osmolality
Psychogenic polydipsia Normal
Diabetes insipidus -

(b) Vasopressin stimulation test:

This test is used to differentiate central from nephrogenic diabetes insipidus. Serum and urine osmolalities are measured 1 hour after administration of either subcutaneous 1-2mcg of desmopressin (DDAVP) or 5 units of aqueous vasopressin. The results are interpreted as follows:

Diabetes insipidus Serum osmolality Urine osmolality
Central
Nephrogenic no change no change

6.Prolactin:

Prolactin deficiency can be confirmed by directly measuring prolactin levels on more than 1 occasion as its secretion is episodic. Serum prolactin level may be increased in a patient with hypothalamic or pituitary lesion but is rarely low. The following are the salient features associated with prolactin level testing:[33][34]

  • Hypoprolactinemia is a marker of severe pituitary damage in patients having structural pituitary disease
  • It is important to measure serum prolactin level as it can give an idea about the location of lesion
  • Routine testing is not done because:
    • It is difficult to differentiate between low and normal serum prolactin concentrations
    • Clinically not relevant unless a woman wishes to lactate
    • There is no standardized test to assess prolactin reserve

References

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