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Review slides Lecture Exam 3 1 Overview of the Endocrine System The endocrine system consists of - collections of cells located in tissues scattered throughout the body - that produce substances released into the blood (hormones) - to ultimately affect the activity and metabolism of target cells. Secrete into Affect activity Endocrine glands Blood Inside cells Exocrine glands Ducts or on to free surface Outside cells 2 Classification of Hormones Amino acids Amino Acid Derivatives Peptides Proteins, glycoproteins Hormones Steroids (cholesterol-derived) Eicosanoids (cell membranes) Lipid Derived (locally acting) 3 Actions of Steroid Hormones • hormone crosses membranes • hormone combines with receptor in nucleus or cytoplasm • synthesis of mRNA activated • mRNA enters cytoplasm to direct synthesis of protein, e.g., aldosterone->Na/K Pump (Thyroid hormone has a similar mechanism of action, even though it is a tyrosine derivative) Magnitude of cellular response proportional to the number of hormone-receptor complexes formed 4 Actions of Amino Acid-Derived Hormones • hormone (first messenger) binds to receptor on cell membrane • adenylate cyclase activated • ATP converted to cAMP • cAMP (second messenger) promotes a series of reactions leading to cellular changes Magnitude of response is not directly proportional to the number of hormone-receptor complexes – it’s amplified 5 Control of Hormonal Secretions • primarily controlled by negative feedback mechanism 1) Hormonal 2) Neural 3) Humoral 6 Control mechanisms for hormone release Target Cell Activation By Hormones • Target cells must have specific receptors to be activated by hormones • Magnitude of target cell activation depends upon – Blood levels of the hormone • Rate of release from producing organ • Rate of degradation (target cells, kidney, liver) • Half-life – Relative numbers of receptors for the hormone • Cellular receptors can be up- or down-regulated – Affinity (strength) of binding of the hormone to its receptor 7 Pituitary Gland Control • Hypothalamic releasing hormones stimulate cells of anterior pituitary (adenohypophysis) to release their hormones • Nerve impulses from hypothalamus stimulate nerve endings in the posterior pituitary (neurohypophysis) gland to release its hormones Note the hypophyseal portal system of the adenohypophysis (two capillaries in series) 8 Hormones of the Anterior Pituitary (SeT GAP) (an ‘axis’) Tropic hormones control the activity of other endocrine glands All anterior pituitary hormones use second messengers 9 Overview of the Pituitary Hormones Figure from: Martini, Anatomy & Physiology, Prentice Hall, 2001 All anterior and posterior pituitary hormones bind to membrane receptors and use 2nd messengers (cAMP) SeT GAP 10 Hormone Summary Table I – Pituitary Hormones Tissue Origin Destination Action on Target Tissue Control of Release1 anterior pituitary males: seminiferous tubules of testes; females: ovarian follicle males: sperm production females: follicle/ovum maturation Gonadotropin Releasing Hormone (GnRH) LUETINIZING HORMONE (LH) anterior pituitary In males: interstitial cells in testes; in females: mature ovarian follicle males: testosterone secretion females: ovulation Gonadotropin Releasing Hormone (GnRH) T THYROID STIMULATING HORMONE (TSH) anterior pituitary thyroid secrete hormones Thyrotropin Releasing Hormone (TRH) G GROWTH HORMONE (GH) anterior pituitary bone, muscle, fat growth of tissues Growth Hormone Rleasing Hormone (GHRH) A ADRENOCORTICOTROPIC HORMONE (ACTH) anterior pituitary adrenal cortex secrete adrenal hormones Corticotropin Releasing Hormone (CRH) P PROLACTIN (PRL) anterior pituitary mammary glands produce milk Prolactin Releasing Hormone (PRH) ANTI-DIURETIC HORMONE (ADH) (VASOPRESSIN) posterior pituitary distal convoluted tubule (DCT) reabsorption of water; increases blood pressure increase in osmolarity of plasma or a decrease in blood volume OXYTOCIN (OT) posterior pituitary uterine smooth muscle; breast contraction during labor; milk letdown Stretching of uterus; infant suckling Name FOLLICLE STIMULATING HORMONE (FSH) Se(x) 11 Hormone Summary Table II Tissue Name Origin Destination Action on Target Tissue Control of Release TRIIODOTHYRONINE (T3) & THYROXINE (T4) Thyroid (follicular cells) all cells increases rate of metabolism (BMR) Thyroid Stimulating Hormone (TSH) Thyroid (C cells) Intestine, bone, kidney Decreases plasma [Ca2+] ( intestinal absorp of Ca; action of osteoclasts; excretion of Ca by kidney plasma [Ca2+] Parathyroids Intestine, bone, kidney Increases plasma [Ca2+] ( intestinal absorp of Ca; action of osteoclasts; excretion of Ca by kidney plasma [Ca2+] cardiac muscle, arteriole and bronchiole smooth muscle, diaphragm, etc increases heart rate and blood pressure... (fight or flight) Sympathetic Nervous System CALCITONIN PARATHYROID HORMONE (PTH) EPINEPHRINE/ NOREPINEPHRINE (Catecholamines) Adrenal Medulla ALDOSTERONE (Mineralocorticoids) Adrenal Cortex Kidneys; sweat glands; salivary glands; pancreas reabsorption of water and Na (increases blood pressure) and excretion of K (mineralocorticoid) Angiotensin II plasma [Na+] plasma [K+] CORTISOL (Glucocorticoids) Adrenal Cortex all cells Diabetogenic; anti-inflammatory (glucocorticoid) ACTH INSULIN β-cells of Pancreatic Islets all cells, liver and skeletal muscle pushes glucose into cells from blood, glycogen formation (decreases blood glucose) plasma [glucose] SNS GLUCAGON α-cells of pancreatic Islets liver and skeletal muscle breakdown of glycogen (increase in blood glucose) plasma [glucose] TESTOSTERONE Testes secondary sex organs development and maintenance LH ESTROGEN Ovaries secondary sex organs development at puberty and maintenance throughout life LH NATRIURETIC PEPTIDES atria and ventricles of heart increased excretion of sodium and water from kidneys, blood volume, blood pressure Stretching of atria and ventricles adrenal cortex, kidneys 12 Renin-angiotensin Pathway 13 Stress Types of Stress • physical stress • psychological (emotional) stress (Stress is any condition, physical or emotional, that threatens homeostasis) Stress Response (General Adaptation Syndrome [GAS]) • hypothalamus triggers sympathetic impulses to various organs • epinephrine is released • cortisol is released to promote longer-term responses Three general phases of the GAS to stress ARE: • Alarm phase • Resistance phase • Exhaustion phase 14 Responses to Stress Exhaustion - lipid reserves - production of glucocorticoids - electrolyte imbalance - damage to vital organs 15 Diabetes (= Overflow) • Diabetes Mellitus (DM) – Hyposecretion or hypoactivity of insulin – Three P’s of Diabetes Mellitus (mellitum = honey) • Polyuria (increased urination) • Polydipsia (increased thirst) • Polyphagia (increased hunger) – Hyperglycemia, ketonuria, glycosuria • Renal Glycosuria – excretion of glucose in the urine in detectable amounts – normal blood glucose concentrations or absence of hyperglycemia • Diabetes Insipidus (insipidus = tasteless) – Hyposecretion or hypoactivity of ADH – Polyuria – Polydipsia 16 Functions of the Kidneys • Make urine • Regulate blood volume and blood pressure • Regulate plasma concentrations of Na+, K+, Cl-, HCO3-, and other ions • Help to stabilize blood pH • Conserve valuable nutrients • Assist the liver in detoxification and deamination 17 Anatomical Features of Kidneys Kidneys are retroperitoneal Helps maintain position of kidney Figure from: Martini, Anatomy & Physiology, Prentice Hall, 2001 18 Location of Kidneys Figure from: Martini, Anatomy & Physiology, Prentice Hall, 2001 Located retroperitoneally from T12 to L3 Left kidney is slightly higher than right kidney Adrenal glands sit on the medial and superior part of kidneys Nephro(s) = kidney Pyel(o) = pelvis 19 The Nephron (80%) Vasa recta are associated with juxtamedullary nephrons (20%) Nephrons are the structural and functional units of the kidney Sympathetic nerve fibers from the ANS innervate the kidney 20 Blood Flow Through Kidney and Nephron Know this! 21 Renal Corpuscle (Glomerulus + Capsule) Efferent arteriole is smaller than the afferent arteriole Filtrate in capsular space This creates a high pressure (~55-60 mm Hg) in the glomerular capillary bed Podocytes form the visceral layer of the glomerular capsule. Their pedicels (foot processes) form filtration slits (or slit pores) that function in forming filtrate. 22 The Nephron 1. Glomerular capsule 2. PCT – simple cuboidal with a brush border (DCT) 3. Thin segment of the descending nephron loop - simple squamous epithelium 4. Thick ascending nephron loop cuboidal/low columnar (PCT) The order of the parts of the nephron is important to know 5. DCT - simple cuboidal with no microvilli (specialized for secretion, not 23 absorption) Juxtaglomerular Apparatus Juxtaglomerular cells (JG) - modified smooth muscle cells in the wall of the afferent arteriole that contract (and secrete renin) Cells of the macula densa (MD) are osmoreceptors responding to solute concentration of filtrate MD + JG cells = juxtaglomerular apparatus 24 Glomerular Filtrate and Urine Composition (1.8 L/day) Glomerular filtrate is about the same composition as plasma: H2O, glucose, amino acids, urea, uric acid, creatine, creatinine, Na, Cl, K, HCO3-, PO43-, SO42-. But notice how different the composition of urine is. Additionally, note that protein is not normally present in urine. 25 Urine Formation Fluid from plasma passes into the glomerular capsule and becomes filtrate at an average rate of 125 ml/minute. This is known as the Glomerular Filtration Rate (GFR) • Glomerular Filtration (GF) *Adds to volume of urine produced • substances move from blood to glomerular capsule • Tubular Reabsorption (TR) *Subtracts from volume of urine produced • substances move from renal tubules into blood of peritubular capillaries • glucose, water, urea, proteins, creatine • amino, lactic, citric, and uric acids • phosphate, sulfate, calcium, potassium, and sodium ions • Tubular Secretion (TS) *Adds to volume of urine produced • substances move from blood of peritubular capillaries into renal tubules • drugs and ions, urea, uric acid, H+ Urine formation = GF + TS - TR 26 Glomerular Filtration Glomerular filtrate is plasma that passes through 1) the fenestrae of the capillary endothelium, 2) the basement membrane around the endothelium, and 3) the filtration slits (slit pores) of the pedicels This is called the ‘filtration membrane’ Glomerular filtration is a mechanical process based primarily on molecule size 27 Glomerular Filtration and Urine Formation Glomerular Filtration Rate (GFR) is directly proportional to the net filtration pressure GFR 125 ml/min (180 L/day) Urine output is only 0.6 – 2.5 L per day (an average of about 1.8 L, or about 1% of glomerular filtrate) 99% of filtrate is reabsorbed!! NFP * Blood pressure is the most important factor altering the glomerular hydrostatic pressure (and NFP). A MAP fall of 10% will severely impair glomerular filtration; a fall of 15-20% will stop it. = HPg – (HPc + OPg) Net Filtration Pressure = force favoring filtration – forces opposing filtration (*glomerular capillary ( capsular hydrostatic pressure hydrostatic pressure) + glomerular capillary osmotic pressure ) 28 Summary of Factors Affecting GFR Factor Effect Vasoconstriction Afferent arteriole (Δ radius GFR) GFR Efferent arteriole (Δ radius 1/GFR) ↑ GFR Vasodilation Afferent arteriole ↑ GFR Efferent arteriole GFR Increased capillary hydrostatic pressure ↑ GFR Increased colloid osmotic pressure GFR Increased capsular hydrostatic pressure GFR Know this table – it’s important! 29 Three Major Ways of Regulating GFR 1) Autoregulation – Maintains GFR despite changes in local blood pressure and blood flow (between 90 – 180 mm Hg mean systemic pressure) – Myogenic (muscular) mechanism – contraction of afferent arteriolar vascular smooth muscle when stretched (increased BP); relaxation occurs when BP declines – Tubuloglomerular mechanism – MD cells detect flow rate and/or osmolarity of filtrate in DCT -> JG cells contract -> afferent arteriole constricts -> GFR 30 Three Major Ways of Regulating GFR 2) Neural (Autonomic) Regulation – Mostly sympathetic postganglionic fibers = vasoconstriction of afferent arterioles GFR (conserves water, redirects blood to other organs) – Stimulates juxtaglomerular apparatus to secrete renin – May override autoregulatory mechanism at afferent arteriole 3) Hormonal Regulation – Renin-angiotensin system – ECF volume and BP – Atrial Natriuretic Peptide (ANP) - ↑ GFR, ↑ fluid loss (dilates afferent arteriole, constricts efferent arteriole) 31 Renin-Angiotensin System Renin is released by the juxtaglomerular apparatus due to: 1) Decline of BP (Renin 1/Pressure) (ACE) Actions of Angiotensin II 2) Juxtaglomerular stimulation by sympathethic NS 3) Decline in osmotic concentration of tubular fluid at macula densa ( Renin 1/[NaCl] ) Stabilizes systemic blood pressure and extracellular fluid volume 32 Tubular Reabsorption in PCT 65% of filtrate volume is reabsorbed in the PCT 8 mm Hg COP Tubular fluid Tubular reabsorption - reclaiming of substances in filtrate by body (tubule blood) Peritubular cap: 1) Low hydrostatic pressure 2) High COP 3) High permeability All uric acid, about 50% of urea, and no creatinine is reabsorbed Renal threshold is the plasma level (concentration) above which a particular solute will appear in urine, e.g., 180 mg/dl 33 Summary of Reabsorption and Secretion Nephron Loop (of Henle) Process PCT Reabsorption Glucose, aa, protein, urea, uric acid, Na+, Cl-, HCO3- Secretion Creatinine H+ Some drugs Descending H2O Urea Ascending Na+/Cl-, K+ (NO H2O) - DCT Collecting duct Na+/ClH2 O HCO3- H2O (only if ADH is present), urea H+/K+ NH4+ - 34 Reabsorption in the PCT Substance Mechanism of Reabsorption Notes Na+ (Cl-) Primary Active Transport Na+ reabsorption is the driving force for most other reabsorption H2O Osmosis Closely associated with movement of Na+ (Obligatory water reabsorption) Glucose Secondary Active transport Limited # of molecules can be handled (Tm = 375 mg/min); attracts H20 Amino Acids Secondary Active transport Three different active transport modalities; difficult to overwhelm Other electrolytes Secondary Active transport 35 Tubular Reabsorption & Renal Clearance • Reabsorption by tubular cells is a selective process – Occurs mainly in the proximal convoluted tubules (PCT) – Has a transport maximum, Tm, for most substances besides Na+ • Tm is the rate at which solutes can be transported, e.g., 375 mg/min • Renal threshold is the plasma level (concentration) above which a particular solute will appear in urine, e.g., 180 mg/dl • Renal Clearance – volume of plasma from which the kidneys clear a particular substance in a given time (usually 1 minute) – inulin clearance test (standard; Cinulin = GFR = ~125 ml/min) – tests of renal clearance are used to calculate glomerular filtration rate – Examples: - Cx = 125 ml/min (amt of x contained in 125 ml of ‘x’ is removed from the plasma every min = 100%) - Cx = 60 ml/min (some reabsorption of ‘x’ is occurring) - Cx = 0 ml/min (complete reasbsorption of ‘x’ is occurring) 36 - Cx = 630 ml/min (secretion of ‘x’ is occurring) Secretion in the PCT and DCT In the DCT potassium ions or hydrogen ions may be secreted in exchange for reabsorbed sodium ions. Reabsorption of Na+ in the DCT is increased by the hormone, aldosterone. Other compounds are actively secreted as well, e.g., histamine, ammonia, creatinine, penicillin, phenobarbital. Active Active and Passive Renal threshold is the plasma level (concentration) above which a particular solute will appear in urine, e.g., 180 mg/dl 37 Summary of Events in the Nephron (Aldosterone) (Aldosterone) 1. Filtrate produced 2. Reabsorption of 65% of filtrate 3. Obligatory water reabsorption 4. Reabsorption of Na+ and Cl- by active transport (NO H2O reabsorption) 5,6. Facultative reabsorption of water (ADH is needed) 7. Absorption of solutes and water by vasa recta to maintain 38 osmotic gradient The Countercurrent Multiplier Approximate normal osmolarity of body fluids The mechanism shown is called the “countercurrent multiplier” Reduced osmolarity of tubular fluid due to action of countercurrent multiplier Countercurrent multiplier allows the kidneys to vary the concentration of urine Vasa recta maintains the osmotic gradient of the renal medulla so the countercurrent multiplier can work Figure from: Martini, Anatomy & Physiology, Prentice Hall, 2001 39 Urea,Uric Acid, and Diuretics Urea • product of amino acid catabolism • plasma concentration reflects the amount or protein in diet • enters renal tubules through glomerular filtration • 50% reabsorbed • rest is excreted Uric Acid • product of nucleic acid metabolism • enters renal tubules through glomerular filtration • 100% of filtered uric acid is reabsorbed • 10% secreted and excreted A diuretic promotes the loss of water in the urine. Anything that adds more solute to tubular fluid will attract H2O and can function as a diuretic to increase the volume of urine, e.g., glucose (osmotic diuretic) 40 Urine • Urine composition varies depending upon – Diet – Level of activity • Major constituents of urine – – – – – – H2O (95%) Creatinine (remember, NONE of this is reabsorbed) Urea (most abundant solute), uric acid Trace amounts of amino acids Electrolytes Urochrome (yellow color), urobilin, trace of bilirubin • Normal urine output is 0.6-2.5 L/day (25-100 ml/hr) • Output below about 25 ml/hour = kidney failure (oliguria -> anuria) 41 Terms to know… • • • • • • • • Anuria – absence of urine Diuresis – increased production of urine Dysuria – difficult or painful urination Enuresis – uncontrolled (involuntary) urination Glycosuria (glucosuria) – glucose in the urine Hematuria – blood in the urine Oliguria – scanty output of urine Polyuria – excessive urine output 42 Elimination of Urine Flow of Urine • nephrons • collecting ducts • renal papillae • minor calyces -> major calyces • renal pelvis • ureters • urinary bladder • urethra • outside world Know this sequence… 43 Ureters and Urinary Bladder Urinary elimination system is lined mostly by transitional epithelium Ureters - retroperitoneal tubes about 25 cm long - carry urine from kidneys to bladder by peristaltic contractions Urinary bladder (cyst[o]) - temporary storage reservoir for urine Smooth muscular layer runs in all directions (detrusor muscle) under parasympathetic control. Contraction compresses the bladder and causes urine to flow into urethra Internal sphincter is thickening of detrusor muscle at neck of bladder – closed when detrusor is relaxed; open when detrusor contracts 44 Urethra Note the short urethra in females (about 4 cm) Note the long male urethra (about 18-20 cm). There are three sections to the male urethra: - Prostatic urethra - Membranous urethra - Penile urethra Figure from: Saladin, Anatomy & Physiology, McGraw Hill, 2007 45 Micturition (Urination) Reflex Figure from: Saladin, Anatomy & Physiology, McGraw Hill, 2007 46 Fluid and Body Compartments About 40 L of fluid (avg. adult male; less in females due to greater proportion of body fat) Major forces affecting movement of fluid between compartments: 1) Hydrostatic pressure 2) Osmotic pressure (ICF) 25L (ECF) 15L ‘Compartments’ commonly behave as distinct entities in terms of ion distribution, but ICF and ECF osmotic concentrations (about 290-300 mOsm/L) are identical. This is because H2O is free to flow between compartments and any disturbance in osmolarity is quickly corrected by H2O movement. 47 Body Fluid Ionic Composition ECF major ions: - sodium, chloride, and bicarbonate ICF major ions: - potassium, magnesium, and phosphate (plus negatively charged proteins) You should know these chemical symbols and charges of ions 48 Fluid (Water) Balance Balance; = * urine production is the most important regulator of water balance (water in = water out) 49 Major Regulators of H2O Intake and Output • Regulation of water intake • increase in osmotic pressure of ECF → osmoreceptors in hypothalamic thirst center → stimulates thirst and drinking • Regulation of water output • Obligatory water losses (must happen) • insensible water losses (lungs, skin) • water loss in feces • water loss in urine (min about 500 ml/day) • increase in osmotic pressure of ECF → ADH is released • concentrated urine is excreted • more water is retained • LARGE changes in blood vol/pressure → Renin and ADH release 50 Dehydration and Overhydration Dehydration • osmotic pressure increases in extracellular fluids • water moves out of cells • osmoreceptors in hypothalamus stimulated • hypothalamus signals posterior pituitary to release ADH • urine output decreases Severe thirst, wrinkling of skin, fall in plasma volume and decreased blood pressure, circulatory shock, death Overhydration • osmotic pressure decreases in extracellular fluids • water moves into cells • osmoreceptors inhibited in hypothalamus • hypothalamus signals posterior pituitary to decrease ADH output • urine output increases ‘Drunken’ behavior (water intoxication), confusion, hallucinations, convulsions, coma, death 51 Osmolarity and Milliequivalents (mEq) • Recall that osmolarity expresses total solute concentration of a solution (Osmolarity = Amt of solute / Vol of H O) 2 – Osmolarity (effect on H2O) of body solutions is determined by the total number of dissolved particles (regardless of where they came from) – The term ‘osmole’ reflects the number of particles yielded by a particular solute (milliosmole, mOsm, = osmole/1000) • 1 mole of glucose (180g/mol) -> 1 osmole of particles • 1 mole of NaCl (58g/mol) -> 2 osmoles of particles • An equivalent is the positive or negative charge equal to the amount of charge in one mole of H+ – A milliequivalent (mEq) is one-thousandth of an Eq – Used to express the concentration of CHARGED particles in a solution 52 Electrolyte Balance Electrolyte balance is important because: 1. It regulates fluid (water) balance 2. Concentrations of individual electrolytes can affect cellular functions Electrolyte Normal plasma concentration (mEq/L) Na+ 140 1. Renin-angiotensin pathway 2. Aldosterone (Angiontensin II, Na+, K+) 3. Natriuretic peptides Cl- 105 Follows Na+ K+ 4.0 1. Secretion at DCT (aldosterone sensitive) Ca2+ 5.0 1. Calcitonin (children mainly) 2. Parathyroid hormone 3. Vitamin D (dietary uptake from intestines) Major mechanism(s) regulating retention and loss 53 Summary Table of Fluid and Electrolyte Balance Condition Initial Change H2O in the ECF Change in OSMOLARITY (**Corrected by change in H2O levels) H2O in the ECF H2O/Na+ in the ECF Initial Effect Correction Na+ concentration, Thirst → H2O intake ECF osmolarity ADH → H2O output Na+ concentration, Thirst → H2O intake ECF osmolarity ADH → H2O output volume, BP Change in VOLUME (**Corrected by change in Na+ levels) H2O/Na+ in the ECF volume, BP Renin-angiotensin: Thirst ADH aldosterone vasoconstriction Natriuretic peptides: Thirst ADH aldosterone You should understand this table Result H2O in the ECF H2O in the ECF H2O intake Na+/H2O reabsorption H2O loss H2O intake Na+/H2O reabsorption H2O loss 54 Acid/Base Buffers A buffer resists changes in pH Buffer Chemical Type Physical (first line of defense) Speed Seconds Respiratory Physiological Minutes Renal Physiological Hours Days Eliminate H+ from body? No Yes (indirectly as CO2) Yes Examples Bicarbonate, phoshate, proteins (ICF, plasma proteins, Hb) H2O + CO2 H+ + HCO3- H+ excretion HCO3- excretion/retention* *Normal plasma [HCO3-] ≈ 25 mEq/L 55 Acidosis and Alkalosis If the pH of arterial blood drops to 6.8 or rises to 8.0 for more than a few hours, survival is jeopardized Classified according to: 1. Whether the cause is respiratory (CO2), or metabolic (other acids, bases) 2. Whether the blood pH is acid or alkaline Respiratory system compensates for metabolic acidosis/alkalosis Renal system compensates for respiratory acidosis/alkalosis 56 Those pesky sequencing questions… Select the numbered sequence on the right that most correctly lists the steps in baking a cake shown on the left. 1. Bake at 3500 for 30 min 2. Combine ingredients 3. Eat the cake 4. Get pans/measuring cups ready 5. Go to supermarket 6. Make shopping list a. 3,2,1,6,5,4 b. 5,6,4,2,1,3 c. 6,5,4,2,1,3 d. 6,5,2,4,1,3 57