Hormonal and Glucose Regulation PDF

Summary

This document provides an overview of hormonal and glucose regulation, including learning objectives, exemplars, and different types of hormone cell communication. It also details the interactions between the hypothalamus and pituitary gland, and the various pituitary hormones and their functions. It's a useful resource for understanding the complex interplay of hormones in the human body.

Full Transcript

Hormonal & Glucose Regulation
Learning Objectives
1. Explain the hypothalamus-pituitary-hormone axis and feedback system
2. Recognize the hormones that originate in the anterior and posterior pituitary glands
3. Differentiate between diseases associated with hyperfunction versus hypofunction of the
pituitary, thyroid, and adrenal glands
4. Identify the risk factors for type 1 diabetes, type 2 diabetes, and metabolic syndrome
5. Recognize the signs,symptoms, and clinical manifestations of type 1 diabetes and type 2
diabetes
6. Describe the pathological mechanism that cause type 1 and type 2 diabetes
7. Recognize the potential complications of uncontrolled diabetes and untreated metabolic
syndrome
Exemplars
Diabetes 1 and 2
Hypo/hyperglycemia
○ Metabolic syndrome
○ Starvation
Hypo/hyperthyroidism
Cushings’ Syndrome
Addison’s Disease
Syndrome of Inappropriate Antidiuretic Hormone (SIADH)
Diabetes Insipidus (DI)
Hormone Cell to Cell Communication
Paracrine pathway > hormones are produced in a cell, secreted, and act directly on
nearby receptive cells
Autocrine pathway > the same as the paracrine pathway except that the receptor cells
are also secretory cells so, in essence, the cell is able to produce the hormone and exert
an effect on itself
Endocrine pathway > hormones are produced in a cell, secreted, and travel through
blood vessels to distant cells, attach to receptors, and act on that cell
Synaptic pathway > hormones (neurotransmitters) are produced in the neuron, secreted,
and travel along the axon to the synapse where they are released and taken up by a
nearby neuron with the appropriate receptors to exert an effect
Neuroendocrine pathway > hormones (neurohormones) are produced in a neuron,
secreted, travel along the axon to the synapse, are released, are taken up into the
vascular system, and travel to distant cells with the appropriate receptors to exert an
effect
Hypothalamus and Pituitary Interaction
The hypothalamus produces several releasing and inhibiting hormones that act on the
pituitary glands, stimulating the the release of pituitary hormones
○ The hormones produce in the hypothalamus are corticotrophin-releasing
hormone, dopamine, growth hormone-releasing hormone, somatostatin,
gonadotrophin-releasing hormone and thyrotrophin-releasing hormone
 Two hormones are produced by the hypothalamus and then stored in the posterior
pituitary gland before being secreted into bloodstream
○ Hormones known as posterior pituitary hormones are synthesized by
hypothalamus, and include oxytocin and antidiuretic hormone (ADH or
Vasopressin). The hormones are then stored in neurosecretory vesicles (Herring
bodies) before being secreted by the posterior pituitary into the bloodstream
The hypothalamus produces several releasing and inhibiting hormones that act on the
pituitary gland, stimulating the release of pituitary hormones
Of the pituitary hormones, several act on other glands located in various regions of the
body, whereas other pituitary hormones directly affect their organs
Disorders of Pituitary Function
Hypothalamus (Grape size) produces antidiuretic hormone and oxytocin and then stores
them in the posterior pituitary
The hypothalamus and the anterior pituitary communicate via a portal system
○ Pituitary gland (pea size) is also called “Hypophysis”
○ Pituitary gland is the “master gland”
Responsible for regulating other glands
○ Two portions; each with unique functions
Anterior
Posterior
Anterior pituitary
○ TSH, ACTH, LH, FSH, GH, Prolactin
Posterior Pituitary
○ Oxytocin, vasopressin
Pituitary Hormones
Anterior
○ ACTH > adrenocorticotropic hormone, or corticotropin, stimulates release of
corticosteroids
Adrenal cortex
○ GH > growth hormone-triggers growth
Bone
○ TSH > thyroid stimulating hormone - stimulates thyroid gland
○ FSH > follicle stimulating hormone-stimulates graafian follicles and seminiferous
tubules
Testis, Ovary
○ LH > luteinizing hormone-stimulates production of androgens (testosterone) and
rupture of follicle to release ovum
Testis, ovary
○ Prolactin > stimulates milk production > mammary gland
Posterior
○ ADH > antidiuretic hormone or vasopressin - decreases diuresis by controlling
renal function
Kidney tubules
○ Oxytocin > stimulates contraction of uterus and letdown in lactating females
 Uterus smooth muscle, mammary gland
Hypopituitarism: Growth Hormone Deficiency
Inhibits somatic growth
Primary site of dysfunction appears to be in the hypothalamus
S/S > short stature, obesity, immature facial feature, delayed puberty, hypoglycemia,
seizures, obesity, insulin resistance
The pituitary secretes hormones that are essential to growth and reproduction
Evaluation of GH Deficiency and GH replacement
Family history
Growth patterns and health history
Definitive diagnosis bases of radioimmunoassay of plasma GH levels
Hand x-rays to evaluate growth potential vs ossification
Endocrine studies to detect deficiencies
Prognosis
GH replacement successful in 80% of patients
Growth rate of 3.5-4 cm/yr before treatment and increase to 8-9 cm/yr after treatment
Response varies based on age, length of treatment, frequency of doses, dosage, weight,
and GH receptor amount
Family support needs
Child’s body image
Preparing child for daily injections
Treatment very expensive ( $20,000 - $ 30,000 a year)
Pituitary Hyperfunction of GH: Clinical Manifestations
Excess GH before closure of epiphyseal shafts results in overgrowth of long bones
Reach heights of 8 feet or more
Vertical growth and increased muscle
Weight generally in proportion to height
Excess GH after epiphyseal closure is called acromegaly
○ Gigantism if before
Typical facial features
Acromegaly > symptoms = pituitary adenoma, hypertrophy of sweat/sebaceous glands,
galactorrhoea ( prolactin), cardiomegaly hypertension, sexual dysfunction, peripheral
neuropathy, visual field defects, prominent supraorbital ridge, large nose and jaw (teeth
are separated or lacking), abnormal glucose tolerance test (glucosuria/polyuria), spade
shaped hands and feet, arthrosis
Diagnostic Evaluations and Management
Caused by non-cancerous tumor in anterior pituitary gland called adenoma
Radiologic studies, endocrine studies
Surgical treatment to remove tumor
Radiation and radioactive implants
Hormone replacement therapy after surgery in some cases
Early identification of patients with excessive growths rates
Early treatment for improved outcomes
 ○ Emotional support, body image concerns, unusual in US early intervention
prevents
Diabetes Insipidus (DI)
The principle disorder of the posterior pituitary
Results from hyposecretion of ADH
Produces uncontrolled diuresis
Primary causes > familial or idiopathic
Secondary causes > trauma, tumors, CNS, infection, aneurysm
History of head injury, pituitary tumor, or craniotomy
Clinical Manifestations of DI and TX
Cardinal signs > polyuria and polydipsia
First sign is often enuresis (involuntary urination)
The urine is highly dilute with a low specific gravity. Loss of fluids leads to serum
hyperosmolality and severe dehydration. Shock and death can occur if untreated
Infants > irritability relieved with feedings of water but not milk, dehydration often occurs
Instruct parents in difference between diabetes insipidus and diabetes mellitus
Daily hormone replacement of vasopressin
○ Drug of choice = DDAVP
○ Nasal spray or IV administration
○ Requires treatment for life
S/S > up to 20 L urine per day, lower specific gravity, hypovolemia, increased thirst,
tachycardia, low BP, lower osmolarity
Syndrome of Inappropriate Antidiuretic Hormone: SIADH
Produced by hypersecretion of the posterior pituitary (increased ADH)
S/S > fluid retention and hypotonicity (low sodium), anorexia, nausea/vomiting, irritability,
personality changes
Symptoms disappear when ADH is decreased
Diagnosis > hyponatremia (serum sodium less than 135 mEq/L), hypotonicity (plasma
osmolality less than 280 mOsm/kg), decreased urine volume, highly concentrated urine
with a high sodium content
Treatment
○ Accurate I and O
○ Observe for signs of fluid overload
○ Water restriction
○ Seizure precautions
○ Hypertonic saline in severe cases
○ Administer ADH-antagonizing meds
Diabetes Insipidus vs SIADH

Diabetes Insipidus SIADH

High urinary output Low urinary output

Low levels of ADH High levels of ADH
 Hypernatremia Hyponatremia

Dehydrated Over hydrated

Lose too much fluid Retain too much fluid
Both will present with excessive thirst

Thyroid Function
Thyroid hormone regulates Basal metabolic rate
Thyroid secretes two types of hormones
○ Thyroid hormone, which is made up of
Thyroxine (T4)
Triiodothyronine (T3)
May have hypothyroidism or hyperthyroidism
May have disturbance in secretion of TSH
Hypothyroidism
Deficient thyroid hormones
Acquired or congenital
Congenital hypothyroidism occurs during fetal development and results in thyroid gland
underdevelopment, insufficient synthesis of thyroid hormone, or problems with TSH
secretion. In utero, maternal T4 crosses the placenta; therefore, the newborn appears
unaffected at birth. If the child is untreated after birth, the lack of thyroid hormone
production and secretion results in intellectual disability and impaired growth
Acquired hypothyroidism can result from 1.) deficient thyroid hormone synthesis; 2.)
destruction of the thyroid gland; or 3.) impaired TSH or TRH secretion
Common causes of acquired hypothyroidism include autoimmunity, iodine deficiency,
surgical removal or or radiation therapy to the thyroid gland, medications that destroy the
thyroid gland, and genetic defects that affect the thyroid hormones. Hashimotos is an
autoimmune cause more common in females
Clinical Manifestations of Hypothyroidism
Low metabolic rate
Fatigue, cold intolerance, weakness, weight gain, constipation, impaired reproduction,
impaired memory
Myxedematous skin changes (swelling of the skin and underlying tissue)
○ Dry skin
○ Sparse hair
○ Periorbital edema
S/S > hair loss, apathy, lethargy, dry skin, muscle aches/weakness, constipation,
receding hairline, facial/eyelid edema, dull blank expression, extreme fatigue, thick
tongue/slow speech, anorexia, brittle nails/hair
○ Late clinical manifestations > subnormal temperature, bradycardia, weight gain
lowered level of consciousness, thickened skin, cardiac complications
Hypothyroidism TX
 Lifelong thyroid hormone replacement therapy is initiated and increased gradually until
optimal hormone levels and clinical improvement are achieved. The most common drug
used to treat hypothyroidism is levothyroxine (synthroid, levoxyl)
Levothyroxine is a synthetic form of T4
Hyperthyroidism (Graves Disease)
Common cause of hyperthyroidism is Graves disease
○ Enlarged thyroid gland and exophthalmos
○ Peak incidence 12-14 years age, but may be present at birth
○ Familial association
Manifestations develop gradually, often over 6-12 months
Diagnosis based on increased levels of T4 and T3 with suppressed TSH
Hyperthyroidism Clinical Manifestations
Excessive metabolic rate
Weight loss, agitation, restlessness, sweating, heat intolerance, diarrhea, tachycardia,
heart palpitations, tremors, fine hair, oily skin, irregular menstruation, weakness
Goiter > enlargement of thyroid gland
Exophthalmos (protrusion of the eyeballs) is also characteristic of Graves disease. This
protrusion is usually bilateral and results from the interaction of TSH-sensitized
antibodies interacting with fibroblast antigens found in extraocular muscles and tissues.
The interaction results in lymphocyte infiltration, edema, and fibroblast accumulation,
which displaces the eyeballs forward. Exophthalmos often persists despite treatment of
hyperthyroidism
T3, T4, TSH
Triiodothyronine (T3), thyroxine (T4), thyroid stimulating hormone (TSH)
PTU > given to those with graves disease to decrease thyroid hormone levels
Synthroid > if TSH is high want to make sure T4 increases, also give if lacking T4
Pituitary issue > everything low
T3 and T 4 high and TSH low > hyperthyroid give PTU
Hypothyroid if T3 and T4 down, TSH elevated

Types of Hormone Normal Ranges

TSH 0.5 - 4.5 mIU/L

Total T4 (TT4) 5.4 -11.5 mcg/dl

Total T3 (TT3) 80 - 220 ng/dl

Thyroid Crisis or Storm
May occur from sudden release of hormone
○ Unusual in children but can be life threatening in adults
May be precipitated by infection, surgery, or discontinuation of anti-thyroid therapy
Treatment of thyroid storm
○ Antithyroid drugs
○ Propranolol
Nursing Considerations
Identify clients with hyper and hypothyroidism
Be alert for signs and symptoms
Client needs quiet environment, rest periods
Help family cope with emotional lability associated with disorder
Dietary requirements to meet client’s increased metabolic rate
Medications > side effects
Disorders of Adrenal Function
Adrenal cortex secretes three groups of steroids
○ Glucocorticoids (cortisol, corticosterone)
Regulates metabolism, inflammatory/immune response, and the stress
response
Increase in cortisol = increase blood sugar
○ Mineralocorticoids (aldosterone)
Regulates sodium and potassium levels, regulates water balance and
blood pressure
○ Sex steroids (androgens, estrogens, and progestins)
Contribute to pubic and axillary hair growth; minimally affect sexual
function
Adrenal medulla secretes catecholamines: epinephrine and norepinephrine
Altered levels of these produces significant dysfunction
Catecholamine-secreting tumors are the primary of adrenal medullary hyperfunction
(pheochromocytoma)
Pheochromocytoma
Adrenal tumor that secretes catecholamines
Clients often have bilateral, multiple, benign tumors
Increased production of catecholamines > may mimic other disorders
Surgical removal of tumor (s)
May require bilateral adrenalectomy and lifelong glucocorticoid and mineralocorticoid
therapy
Cushing Syndrome
 A characteristic group of manifestations caused by excessive circulating free cortisol
May be caused by excessive or prolonged steroid therapy
Condition is reversible once steroids are discontinued
Abrupt withdrawal of steroids may precipitate acute adrenal insufficiency
Etiologies of Cushing Syndrome
Long-term administration of corticosteroid medications (such as prednisone)
Tumors of the pituitary gland that stimulate excess ACTH production
Tumors of the adrenal gland that stimulate excess cortisol production
Ectopic production ACTH or CRH from a tumor at a distant site, such as small cell
carcinoma of the lung
Diagnostic Evaluation
Confirm excess cortisol levels
X-rays: evaluate for osteoporosis and skull films to look for enlargement of sella turcica
(bony depression in sphenoid bone)
Laboratory tests
○ Fasting blood glucose
○ Serum electrolytes
○ 24 hr urine

Cushing Syndrome Symptoms
Excessive hair growth, red cheeks, weight gain and pendulous abdomen with red striae,
poor wound healing, ecchymosis, moon face or buffalo hump
Therapeutic management
○ Surgery or radiation
○ Replacement of growth hormone, ADH, TH, gonadotropins
Acute Adrenocortical Insufficiency
Adrenal crisis
Diagnosis generally based on clinical symptoms
Most serious endocrine disorder > hypotension, shock, death
Autoimmune destruction of the layers of the adrenal cortex is the most common cause of
the disease. Others result from adrenal gland granuloma, tumors, or drugs that block the
synthesis of corticosteroids
These conditions lead to the inability of the adrenal glands to produce any
glucocorticoids, mineralocorticoids, or androgens. As a result, ACTH levels are elevated
to increase the secretion of these three major steroid hormones from the adrenal glands.
(excess melanin)
Don't have the ability to fight or flight mode
Chronic Adrenocortical Insufficiency: Addison Disease
When it occurs, usually result of neoplasms or lesion of adrenal glands or idiopathic
cause
Symptoms appear gradually after 90% of adrenal tissue is nonfunctional
Treatment: IV infusion of hydrocortisone then oral replacement of steroids following

Deficient Hormones Clinical Manifestations

Glucocorticoids Hypoglycemia, weakness, poor stress
response, fatigue, anorexia, nausea,
vomiting, weight loss, personality changes

Mineralocorticoids Dehydration, hyponatremia, hyperkalemia,
hypotension, weakness, fatigue, shock

Androgens Sparse axillary and pubic hair

Pancreatic Hormone Function
Function of islets of langerhans
 ○ Alpha cells produce glucagon
○ Beta cells produce insulin
○ Delta cells produce somatostatin (believed to regulate insulin and glucagon)
○ Insulin is needed for glucose uptake
Decrease insulin secretion > lower blood glucose, increase alpha, high
insulin
Starvation
Glucose is a major energy source for body tissues. In starvation, dietary glucose is
unavailable for glucose-dependent tissues,such as the brain and muscle tissue. The
body attempts to manufacture glucose in a process called gluconeogenesis by breaking
down muscle proteins. The muscle then releases acidic byproducts, promoting metabolic
acidosis
Insulin is a hormone that promotes glucose production and uptake by cells and inhibits
the use of fat stores for energy. If the body is to adapt to starvation effectively, insulin
production must be suppressed to inhibit glucose uptake and gluconeogenesis, and
another energy source must be used at a greater level than glucose
This is accomplished through a compensatory increase in glucagon, cortisone,
epinephrine, and growth hormone. These hormones all have anti-insulin effects and also
stimulate enzymes on the adipocytes to release fatty acids for energy. The fatty acids
travel to the liver and are converted to ketones. Ketones are the replacement energy
source that allows sparing of muscle catabolism. The brain and other glucose-dependent
tissues prefer glucose but will use ketones for energy as an adaptive response
Diabetes Mellitus Type 1
Characterized by a total or partial deficiency of the hormone insulin
Destruction of beta cells, usually leading to absolute insulin deficiency
Typically, onset in childhood and adolescence, but can occur at any age
Most DM of childhood is Type 1

Type 1 Type 2

The body does not make enough insulin The body cannot use insulin properly
Insulin Dependent Insulin Resistant

Usually ages 0-40 (mostly young children or Usually ages 40+ (mostly adults but occurring
teens) in children and teens who are overweight and
obese)

Increased thirst/urination, weight loss, fatigue, Increased thirst/urination, weight loss, fatigue,
fruity smelling breath, irritability, blurred blurred vision, slow healing sores or frequent
vision, slow healing sores or frequent infections
infections

There is no way to prevent Type 1 Diabetes Most cases of Type 2 diabetes can be
prevented

Insulin injections, blood sugar checks, health Healthy eating/meal planning, increased
 eating and meal planning, increased physical physical activity, oral medication, blood sugar
activity checks, sometimes insulin injections

Diabetes Mellitus Type 1
With a deficiency of insulin, glucose is unable to enter the cell, and remains in blood
causing hyperglycemia
When serum glucose exceeds renal threshold glucose spills into urine (glycosuria)
Cells break down protein for conversion to glucose by the liver (glucogenesis)
Type 1 DM believed to be autoimmune disease arising when a person with a genetic
predisposition is exposed to a precipitating event such as viral infection
Heredity is prominent factor in etiology

High A1C > high blood sugar for long time
DM Type 1: Ketoacidosis
When glucose is unavailable for cellular metabolism, the body breaks down alternate
sources of energy
Ketones are released, and excess ketones are eliminated in urine (ketonuria) or by the
lungs (acetone breath)
Ketones in the blood are strong acids that lower serum pH and produce ketoacidosis
Severe insulin deficiency, common complication of type 1 DM
Characterized by hyperglycemia, metabolic acidosis, glucosuria, ketonuria, ketonemia
Diabetic Ketoacidosis DKA
Emergency situation
Results from progressive deterioration with dehydration, electrolyte imbalance, acidosis,
coma, and may cause death
Treatment of DKA focuses on stabilizing blood glucose levels, correcting acidosis,
replacing fluids and electrolytes, and improving tissue perfusion. These goals are
accomplished through intravenous administration of insulin, fluid, and electrolyte
solutions

TX Type 1 DM
Insulin therapy
Glucose monitoring > goal range 80-120 mg/dl
Urine testing for ketones
○ q3h during illness and whenever glucose is > 240 mg/dl when illness not present
Nutrition, exercise
Teach patient and family how to manage hypoglycemic episodes
Illness management, management of DKA
Kussmaul Respirations > Have with DKA
Hyperventilation characteristics of metabolic acidosis, resulting from respiratory system’s
attempt to eliminate excess CO2 by increased depth and rate
Breath also has a sweet, fruity odor caused by the release of acetone, a volatile form of
ketones
Hypoglycemia
A state of significantly low blood glucose that results in clinical manifestations, such as
weakness, pallor, or cool/clammy skin
 Most commonly found in individuals with type 1 diabetes who are undergoing insulin
replacement therapy. Insulin replacement therapy requires the careful intake of adequate
nutrients to match the injected insulin.
Simple carbohydrates, such as that found in sugary foods like syrup, fruit juice, or honey,
enter the blood and rapidly raise the blood sugar. This stimulates the rapid release of
insulin. The insulin pulls this excess glucose into cells of the body and actually deprives
the brain of glucose.
Type 2 Diabetes
Arises because of insulin resistance
Onset usually after age 40
Native American, Hispanics, and African-American are at increased risk of type 2 DM
Affected persons may or may not require insulin injections
Symptoms are insidious and nonspecific. Potentially polydipsia, polyphagia, and polyuria
may occur
Usually related to long-term complications such as visual changes, changes in kidney
function, coronary artery disease, peripheral vascular disease, recurrent infections, or
neuropathy
Metabolic Syndrome
Metabolic syndrome is a condition that includes insulin resistance and a constellation of
other metabolic problems, including obesity, high triglyceride levels, low high-density
lipoprotein (HDL) levels, hypertension, and coronary heart disease
Individuals diagnosed with type 2 diabetes must also be evaluated for metabolic
syndrome to determine the full range of metabolic alterations
Long-Term Complications of DM
Microvascular complications, especially nephropathy and retinopathy
Macrovascular disease, neuropathy
Patient Education DM and Insulin Therapy
Nature of disease
Meal planning
Insulin therapy > types of insulin, duration, onset and peak action, mixing and
administration of types of insulin, rotation of injection sites
Insulin pump therapy
Glucose monitoring
Recognition and treatment of hypoglycemia and hyperglycemia
Management of minor illnesses
Record keeping
Hygiene, family support, acute care
Khan Academy Videos
Hormones = chemical messengers > communicate through body > wireless go into
bloodstream and work on body without directly connecting
○ Endocrine >far distance
○ Paracrine > regionally
○ Autocrine > small distance in one cell or next
Pituitary gland > master gland
○ Has an effect on thyroid > metabolism (T3 and T4)
○ TSH > acts on thyroid gland > stimulates gland to make thyroid hormone >
regulate metabolism
○ Hyperthyroidism > fast metabolism
○ Hypothyroidism > slow metabolism
○ ACTH > acts on adrenal cortex, sit above kidney, make cortisol which regulates
glucose metabolism, maintain BP, aldosterone
○ LH, FSH > act on gonads (ovaries,testes) sperm/egg production, testosterone
○ GH > optimal growth of long bones
○ Prolactin > lactation, breast feed
Hypothalamus/ posterior pituitary > ADH and Oxytocin
Adrenal gland
○ Cortex > steroids are made > cortisol and aldosterone
○ Medulla > catecholamine (epi,Nepi)
Pancreas > blood sugar (insulin, glucagon)