Exam 2

Angiotensin-converting enzyme (kinase II)

-Catalyzes the conversion of angiotensin I (inactive) to angiotensin II (highly active) -Involved in the breakdown of bradykinin

Hypertonic contraction

-Loss of water > loss of sodium -Reduced ECF volume -Increase in osmolality

Magnesium

-Serum ____________ levels 1.8-3.0 mg/dl Actions: -Required for activity of many enzymes -Binding of messenger RNA to ribosomes Functions to regulate: -Transmission -Excitability

Hypomagnesemia

-Serum magnesium <1.8 mg/dl Causes: -Diarrhea -Hemodialysis -Kidney disease -Poor nutritional states

Hypermagnesemia

-Serum magnesium >3.0 mg/dl -Most common with renal insufficiency (RI)

Isotonic contraction

-Sodium and water are lost in isotonic proportions -Decrease in total volume -No change in osmolality

c.) Reflex tachycardia (quickest response)

A patient is prescribed a medication that lowers the arterial blood pressure. The nurse should assess for which response by the body to restore the blood pressure? a.) Orthostatic hypotension b.) Fluid retention (later response) c.) Reflex tachycardia (quickest response) d.) Increased natriuresis

Hydrochlorothiazide (HCTZ)

AKA "HCTZ" Most widely used thiazide Common uses: HTN Edema

Cardiac afterload

AP that the left ventricle must overcome to eject blood

Aldosterone

Actions of _____________ -Regulation of blood volume and blood pressure -Pathologic cardiovascular effects: Remodeling, fibrosis, dysrhythmias

Spironolactone

Aldosterone antagonist Common Uses: -HTN -Edema -Heart failure (HF/CHF) -Primary hyperaldosteronism -Premenstrual syndrome (PMS) -Polycystic ovary syndrome (PCOS) -Acne

Rapid control by ANS: Baroreceptor reflex

Attempts to keep PR at a predetermined level

Hyperkalemia

Can be used to treat low extracellular levels of potassium, due to ______________________. -Oral or rectal administration sodium polystyrene sulfonate [Kayexalate®] -Calcium salt -Insulin -Dialysis -Sodium bicarbonate

Metabolic Acidosis

Causes: -Chronic renal failure -Loss of bicarbonate -Metabolic disorders -Poisoning by methanol -Certain medications Treatment: -Correction of the underlying cause of acidosis -If severe: alkalinizing salt

Hypotonic contraction

Causes: -Excessive loss of Na through kidneys Treatment: -Mild: Isotonic NaCl infusion (NS) -Severe: Hypertonic solution (3% NaCl) -Watch for signs of fluid overload

Metabolic Alkalosis

Causes: -Excessive loss of gastric acid -Administration of alkalinizing salts -Severe volume contraction Treatment: -Solution of sodium chloride plus potassium chloride

Hypertonic contraction

Causes: -Excessive sweating, osmotic diuresis, 2nd to extensive burns, etc. Treatment: -Hypotonic fluids (0.45% NaCl) or fluids that contain no solutes at all -Initial therapy: Drink water

Respiratory Alkalosis

Causes: -Hyperventilation --> decrease in CO2 Treatment: -Mild: None needed -More severe: Rebreathe CO2-laden expired breath

Volume expansion

Causes: -Overdose with therapeutic fluids -Disease states Treatment: -Diuretics -Select agents (HF)

Respiratory Acidosis

Causes: -Retention of CO2 secondary to hypoventilation Treatment: -Correction of respiratory impairment -Infusion of sodium bicarbonate if severe

Hyperkalemia

Causes: -Severe tissue trauma -Untreated Addison's disease -Acute acidosis -Misuse of potassium-sparing diuretics -Overdose with IV potassium Consequences: -Disruption of cardiac electrical activity -Earliest signs of danger: Mild (5-7 mEq/L) Severe (8-9 mEq/L) -Noncardiac signs: Confusion, anxiety, dyspnea, weakness or heaviness of legs, paresthesias (hands/feet/lips)

Isotonic contraction

Causes: -Vomiting, diarrhea, kidney disease, and misuse of diuretics Treatment: -Fluids that are isotonic to plasma -0.9% NaCl -Replenish slowly

Hyokalemia

Causes: -meds Adverse effects: -Seen in skeletal & smooth muscle, BP, and EKG changes -Increases risk for HTN and stroke (CVA)

Cardiac preload

End-diastolic volume or end-diastolic pressure

acidic

HCO3 less than 22 is _____________

alkaline

HCO3 more than 26 is _____________

Insulin

Has profound effect on potassium levels

Cardiac Output

Heart Rate x Stroke Volume

-Constricts renal blood vessels -Acts on the kidney to promote retention of sodium and water and excretion of potassium

How does the RAAS help to regulate the BP?

Volume expansion

Increase in the total volume of body water May be isotonic, hypertonic, hypotonic

Renal Excretion

Increased by: -Aldosterone -Most diuretics except potassium-sparing -Influenced by extracellular pH -Alkalosis -Acidosis

Hypotonic contraction

Loss of sodium > loss of water Both volume and osmolality of ECF are reduced

ACE inhibitors

MOA: -Inhibits ACE -Reduced levels of angiotensin II --> dilate blood vessels, reduce blood volume -Increased levels of bradykinin ---> vasodilation; cough, angioedema Administration: -PO (most common) & IV -ALL are excreted by kidneys --> renal dosing PRN

Low pH Normal PaCO2 Low HCO3

Metabolic acidosis is characterized by:

High pH Normal PaCO2 High HCO3

Metabolic alkalosis is characterized by:

Potassium

Most abundant intracellular cation Reference range: 3.5-5.0mEq/L Extracellular concentrations are low Plays major role in: -Conducting nerve impulses -Maintaining electrical excitability of muscle -Regulating A/B balance

Furosemide (Lasix)

Most frequently prescribed loop diuretic Uses: Pulmonary edema Edematous states Hypertension (HTN) MOA: blocks reabsorption at ascending loop of Henle Rapid onset (PO 60 min; IV 5 min)

Triamterene

Non-aldosterone antagonist Uses: HTN Edema

alkaline

PaCO2 less than 35 is ___________

acidic

PaCO2 more than 45 is ___________

Hypomagnesemia

Prevention and treatment -Replacement: Magnesium oxide or sulfate (IM or IV) Adverse effects: -Neuromuscular blockade -Suppressed cardiac impulse conduction -Respiratory paralysis -Cardiac arrest

Kidneys

Primary regulator of potassium levels

Hyperkalemia

Principal complication of treating hypokalemia

Angiotensin-Converting Enzyme (ACE) Inhibitors

Prototype: Captopril

Angiotensin II Receptor Blockers (ARBs)

Prototype: Losartan (Cozaar®) Another example: Amlodipine (Norvasc®)

Steady-state control by ANS

Regulates AP by adjusting cardiac output (CO) and peripheral resistance

Low pH High PaCO2 Normal HCO3

Respiratory acidosis is characterized by:

High pH Low PaCO2 Normal HCO3

Respiratory alkalosis is characterized by:

Ramipril

Risk reduction of MI, stroke, and death in patients at high CV risk

Hyperkalemia

Serum potassium levels above 5.0 mEq/L

Hypokalemia

Serum potassium levels below 3.5 mEq/L

Thiazides

Similar to effects of loops Max diuresis is much lower than loops Depend on adequate kidney function: -Not effective when urine flow is scant -Can't be used with severe renal impairment -Ineffective if low GFR (<15-20 mL/min)

Frank-Starling Law

Stroke volume of the heart increases in response to an increase in the volume of blood in the ventricles, before contraction (the end diastolic volume), when all other factors remain constant.

ACE inhibitors

Suffix: -pril Indications: -HTN -HF -Acute MI -LV dysfunction -Diabetic and nondiabetic nephropathy Side effect: dry cough

Hypermagnesemia

Symptoms of mild intoxication: -Muscle weakness -Hypotension -Sedation -ECG changes Treatment: -Diuresis -IV Calcium gluconate -Dialysis

Heart Rate

The _______ ________ is controlled by the autonomic nervous system (ANS)

Furosemide (Lasix)

The following adverse effects are related to which diuretic: -Hypokalemia (dysrhythmias) -Hyponatremia, hypochloremia, and dehydration -Hypotension (loss of volume, relaxation of venous smooth muscle) -Ototoxicity -Hyperglycemia -Hyperuricemia

Furosemide (Lasix)

The following are drug interactions are for which diuretic: -K dependent drugs -Digoxin -Ototoxic drugs -Potassium-sparing diuretics -Lithium -Antihypertensive agents -NSAIDs

Hyperkalemia

Treatments of _______________ include: -Hold potassium-containing foods & salt substitutes -Hold potassium accumulating medications -Counteract potassium-induced cardiotoxicity

-Bicarbonate-carbonic acid buffer system -Respiratory system: CO2 (acid) -Kidneys: HCO3- (base)

What 3 systems help maintain acid-base disturbances?

-Hypovolemia (dehydrated) -Acid/Base imbalance -Electrolyte imbalances

What are some adverse effects of diuretics?

-Autonomic innervation -Fitness levels -Age -Hormones

What are some factors affecting heart rate?

-Heart size -Gender -Contractility -Duration of contraction

What are some factors affecting stroke volume?

-Systemic filling pressure -Auxiliary muscle pumps -Resistance to flow between peripheral vessels and the right atrium -Right atrial pressure

What are some factors that determine venous return?

-Bumetanide -Torsemide -Ethacrynic acid

What are some other high ceiling (loop) diuretics?

-Modest increase in diuresis -Substantial decrease in K+ excretion

What are some useful responses of potassium sparing diuretics?

-Cleansing -Balance -Excretion

What are the 3 basic functions of the kidneys?

-Filtration (happens in the glomerulus) -Reabsorption -Active tubular (secretion proximal convoluted tubule)

What are the 3 basic renal processes of the kidneys?

-Volume contraction -Volume expansion

What are the abnormal stages of hydration?

-Glomerulus -Proximal convoluted tubule -Loop of Henle -Distal convoluted tubule

What are the four functionally distinct regions of the kidney?

-Loop: Furosemide (Lasix) -Thiazide: Hydrochlorothiazide ("HCTZ") -Osmotic: Mannitol -Potassium-sparing: Aldosterone antagonists (Spironolactone) & Nonaldosterone antagonists (Triamterene)

What are the four major categories of diuretics?

22-26

What are the normal ranges for HCO3?

35-45

What are the normal ranges for PaCO2?

7.35-7.45

What are the normal ranges for pH?

-Aldosterone Antagonist (Spironolactone) -Non-Aldosterone Antagonist (Trimaterene)

What are the two subcategories of potassium sparing diuretics?

Carbonic Anhydrase Inhibitors

What diuretic is used for increased ocular pressure?

-Angiotensin-Converting Enzyme (ACE) Inhibitor (any with suffix "-pril") (Prototype: Captopril) Angiotensin II Receptor Blocker (ARB) Prototype: Losartan (Cozaar®) another example: Amlodipine (Norvasc®) -Direct Renin Inhibitor Prototype: Aliskiren -Aldosterone Antagonist Prototype: Eplerenone (Inspra ®)

What drugs act on the RAAS?

Block Na and Cl reabsorption

What is the MOA of diuretics?

3.5-5.0 mEq/L

What is the reference range of potassium? Note: ranges vary by facility and within the literature

Proximal tubule (greatest diuresis)

What is the site of action for diuretics?

Angiotensin II

Which angiotensin has the following actions: -Powerful Vasoconstrictor -Synthesis/Release of Aldosterone -Alteration of cardiac and vascular structure -Hypertrophy and remodeling in the heart -Thickening of blood vessels

ACE inhibitors

Which class of drugs contain the following adverse effects and black box warning? AE: -First dose hypotension (severe HTN, diuretic use, Na or volume depleted) -Cough -Angioedema (seek immediate care, never take again) -Hyperkalemia -Renal failure (renal artery stenosis, solitray kidney stenosis) **BBW** -Fetal toxicity -Fetal injury (2nd or 3rd trimesters)

ACE inhibitors

Which class of drugs have the following drug interactions? -Diuretics -Antihypertensive agents -Drugs that raise potassium levels -Lithium ---> lithium accumulation/toxicity -NSAIDs ---> reduced effect of ACEIs (advil, aleve, aspirin)

Hydrchlorothiazide (HCTZ)

Which diuretic has a MOA location of the early segment of the distal convoluted tubule, and peaks in 4-6 hours

Aldosterone Antagonist (Spironolactone)

Which diuretic has the following MOA: -Blocks aldosterone in distal nephron -Retains potassium -Increases excretion of sodium

Mannitol (Osmotic)

Which diuretic has the following MOA: Creates osmotic force in lumen of nephron --> diuresis

Non-Aldosterone Antagonist (Triamterene)

Which diuretic has the following MOA: -Disrupts Na-K exchange in distal nephron -Directly inhibits the exchange mechanism -Decreases sodium reuptake -Inhibits ion transport

Aldosterone Antagonist (Spironolactone)

Which diuretic has the following adverse effects and drug intercations AE: Hyperkalemia, Endocrine effect Drug Interactions: Thiazide and loop diuretics, Agents that raise potassium levels

Mannitol (Osmotic)

Which diuretic has the following adverse effects: -Edema -Headache -Nausea -Vomiting -Fluid and electrolyte imbalance

Non-Aldosterone Antagonist (Triamterene)

Which diuretic has the following adverse effects? -Hyperkalemia -Leg cramps -Nausea -Vomiting -Dizziness

Mannitol (Osmotic)

Which diuretic has the following uses: -Prophylaxis of renal failure -Reduction of intracranial pressure (ICP) -Reduction of intraocular pressure (IOP)

Potassium-Sparing Diuretics

Which diuretic is rarely used alone for therapy?

Mannitol (Osmotic)

Which diuretic must be given parenterally?

Severe Hypokalemia

Which form of Hypokalemia should be treated with the following: -IV potassium chloride (KCl) -If untreated, results in cardiac arrest -Must be diluted (40mEq or less) -Infused slowly (generally no faster than 10 mEq/hr) -Must never be administered by IV push

Mild Hypokalemia

Which form of Hypokalemia should be treated with the following: -PO potassium chloride (KCl) -Sustained-release version has fewer GI effects -Side effects: Abdominal discomfort, N/V/D -Should be taken with meals and/or full glass of H2O

d.) A patient who is prescribed a drug that promotes venous vasodilation (dizzy)

Which patient would the nurse expect to have the highest risk for postural hypotension? a.) A patient who is prescribed a drug that acts primarily on the arterioles b.) A patient who is prescribed a drug that blocks the renin-angiotensin-aldosterone system c.) A patient who is prescribed a drug that triggers the baroreceptor reflex d.) A patient who is prescribed a drug that promotes venous vasodilation (dizzy)

Volume contraction

decrease in total body water

acidic

pH less then 7.35 is _________

alkaline

pH more than 7.45 is ___________

Peripheral Resistance

regulated by constriction & dilation of arterioles (afterload)