T3 - Renal Assessment

Question 1

~_____% TBW is water (varies w/ _____, ______, _____ %)

Answer 1

• 60%
• gender, age, body fat

Slide 3

Question 2

ECF- fluid outside of cells ( _____ + _______) = < 1/2 volume of TBW

Answer 2

ISF +Plasma

Slide 3

Question 3

How is osmolar homeostasis primarily mediated?

Answer 3

Osmolality sensors in the anterior hypothalamus

Slide 3

Question 4

What is the path created by the hypothalamus to regulate osmolar homeostasis?

Answer 4

• Stimulate thirst
• Cause pituitary release of vasopressin (ADH) (To retain fluid)
• Cardiac atria release ANP (will act on kidney to decrease Na/H2O reasbsorption) (to get rid of fluid)

Slide 3

Question 5

How is volume homeostasis mediated?

Answer 5

Mediated by juxtaglomerular apparatus

Slide 3

Question 6

What are the changes caused by the JGA?

Answer 6

• JGA senses a decrease in volume
• JGA triggers Renin-Angiotensinogen-Aldosterone system
• RAAS causes Na+/H2O reabsorption

Slide 3

Question 7

What would be concerning when it comes to Na levels and surgery?

Answer 7

Acute changes

≤125 or ≥155

Correct prior to elective cases

Slide 4 notes

Question 8

In hypovolemia, what fluid and Na abnormality would you expect?

What could be some causes?

Answer 8

• Na and H2O loss
• Diuretics, GI loss, burns, trauma
  Slide 4 notes

Question 9

What could cause sodium decrease in a euvolemic state?

Answer 9

• Salt restriction
• Endocrine-related: hypothyroid, SIADH (retaining H2O more than Na)

Slide 4

Question 10

What could be the cause of hyponatremia in a hypervolemic state with a urine Na >20?

Answer 10

• ARF/CKD
• Heart failure

Slide 4 notes

Question 11

What percentage of hospitalized patients are considered hyponatremic?

What could be a cause?

Answer 11

• 15%
• Over fluid-resuscitation
• ↑ endogenous vasopressin

Slide 4 notes

Question 12

Clinical neurological presentation of hyponatremia: 130-135 mEq/L

Answer 12

• Asymptomatic
• Headache
• Nausea
• Vomiting
• Fatigue
• Confusion
• Muscle cramps
• Depressed reflexes

*Bold are individual to this category and are not repeated in the next category

Slide 5

Question 13

Clinical neurological presentation of hyponatremia: 120-130 mEq/L:

Answer 13

• Malaise
• Unsteadiness
• Headache
• Nausea
• Vomiting
• Fatigue
• Confusion
• Muscle cramps

*Bold are individual to this category and are not repeated in the other categories

Slide 5

Question 14

Clinical neurological presentation of hyponatremia: <120 mEq/L

Answer 14

• Headache
  - Restlessness
  - Lethargy
  - Seizures
  - Brain-stem herniation
  - Respiratory arrest
  - Death

*Bold are individual to this category and are not repeated in the other categories

Slide 5

Question 15

Which are the most severe consequences of hyponatremia:

Answer 15

• Seizures
• Comma
• Death

Slide 5

Question 16

What is the single most important for the treatment of hyponatremia?

What are some treatment options?

Answer 16

• Treat underlying cause (look at volume status)
• Electrolyte drinks
• Normal saline
• Diuretics
• Hypertonic saline/3% NaCl

Slide 6

Question 17

What should the infusion rate be when treating hyponatremia with 3% NaCl hypertonic solution?

What should the Na correction not exceed?

Answer 17

• 80 ml/hr over 15h
• Correction should not exceed 1.5 mEq/L/hr

Slide 6

Question 18

What could happen with rapid correction of hyponatremia?

How fast would you have to correct in order to achieve this adverse effect?

Is this a serious or reversible adverse effect?

Answer 18

• Osmotic Demyelination Syndrome
• You’d have to correct >6 mEq/L in 24h
• Serious - often permanent neuro damage

Slide 6

Question 19

Are hyponatremic seizures a medical emergency?

How would you treat this?

Answer 19

• Yes! neurological damage could occur
• 3-5 ml/kg of 3% over 20 min until seizures resolve

Slide 6

Question 20

What are some causes of HYPERnatremia?

Answer 20

• Diabetes insipidus
• Excessive evaporation
• Poor oral intake (very young, very old, altered mental status)
• Overcorrection of hyponatremia
• GI losses
• Excessive sodium bicarb (treating acidosis)

Slide 7

Question 21

HYPERnatremia diagnostic algorithm

Hypovolemia

S/S:

• Urine Na >20:
• Urina Na <20:

Treatment:

Answer 21

PPT notes: Renal or GI loss

S/S: Decreased skin turgor, flat neck veins, dry mucous membranes, orthostatic hypotension, tachycardia, oliguria

Urine Na >20: Renal salt and water loss
- Osmotic diuretic
- Loop diuretic
- Postrenal obstruciton
- Intrinsic recall disease
- Profound glycosuria

Urine Na <20: Extrarenal salt and water loss
- Diarrhea
- GI fistulas
- Sweating

Treatment: Normal saline

Slide 8/9

Question 22

HYPERnatremia diagnostic algorithm

Euvolemia
- Urine Na ______?

Treatment:

Answer 22

Urine Na variable

Renal water loss:
- Diabetes insipidus: Central, nephrogenic, gestational

Extrarenal water loss:
- Insensible losses: Respiratory tract; Skin

Treatment: water replacement (po or D5W)

Slide 8

Question 23

HYPERnatremia diagnostic algorithm

Hypervolemia

S/S

Urine Na >20:

Treatment:

Answer 23

S/S: Peripheral edema, rales, ascites

Urine Na >20: Sodium gains
- Hyperaldosteronism
- Cushing’s syndrome
- Hypertonic dialysis
- IV NaHCO3
- NaCl tablets
- Hyperalimentation
- Salt water drowning

Treatment: diuretics

Slide 8/9

Question 24

What are common symptoms of HYPERnatremia?

Answer 24

LORDTS (Madea’s voice)

• Lethargy
• Orthostasis
• Restlessness
• Death
• Tremor/muscle twitching
• Seizures

Question 25

How would you treat HYPERnatremia in hypovolemic, euvolemic, or hypervolmeic states?

Answer 25

Root cause, Assess volume status (VS, UOP, Turgor, CVP)
- Hypovolemic: normal saline
- Euvolemic: water replacement (po or D5W)
- Hypervolemic: diuretics

Slide 9

Question 26

How fast do you want to reduce Na levels for correction?

Why would you want to correct at this rate?

Answer 26

≤ 0.5 mmol/L/hr and ≤ 10 mmol/L/day

• To avoid cerebral edema, seizures, and neurological damage

Question 27

What is the percentage of the major intracellular fluid (ICF) cation (K+) that is present in the extracellular fluid (ECF)?

Answer 27

Less than 1.5% of the major intracellular fluid cation is present in the extracellular fluid.

Question 28

Does serum potassium (K+) reflect transmembrane K+ regulation or total body K+ more accurately?

Answer 28

Serum potassium (K+) reflects transmembrane K+ regulation more than total body K+.

Question 29

What is the effect of aldosterone on potassium and sodium in the distal nephron?

Answer 29

Aldosterone causes the distal nephron to secrete potassium (K+) and reabsorb sodium (Na+).

Question 30

How does renal failure affect potassium excretion?

Answer 30

In renal failure, potassium excretion declines and excretion shifts towards GI system.

Question 31

When renal potassium excretion declines, where does the excretion shift towards?

Answer 31

When renal potassium excretion declines, excretion shifts towards the gastrointestinal (GI) system.

Question 32

What dietary issue can cause low serum potassium?

Answer 32

Low PO intake

Question 33

By which 2 ways mentioned in the PPT can we lose K+ through the kidneys?

Answer 33

Diuretics use and hyperaldosteronism can cause renal loss of potassium.

Question 34

How can gastrointestinal issues lead to low potassium?

Answer 34

Nausea, vomiting, diarrhea, and malabsorption can cause gastrointestinal loss of potassium.

Question 35

Which conditions lead to an intracellular shift of potassium?

Answer 35

Alkalosis, the use of β-agonists, and insulin administration can cause an intracellular shift of potassium.

Question 36

Which medical condition related to diabetes can cause low serum potassium? How?

Answer 36

Diabetic ketoacidosis (DKA) can lead to low serum potassium due to osmotic diuresis.

Question 37

Which type of blood pressure medication can lead to a decrease in potassium?

Answer 37

Hydrochlorothiazide (HCTZ) found in some blood pressure medications.

Question 38

What unusual dietary source can lead to low potassium levels?

Answer 38

Excessive consumption of licorice.

Question 39

What are general types of symptoms seen in hypokalemia?

Answer 39

Generally cardiac and neuromuscular symptoms.

Question 40

What muscular symptoms can hypokalemia cause?

Answer 40

Muscle weakness and cramps.

Question 41

What is ‘Ileus’ in the context of hypokalemia?

Answer 41

A disruption of the normal propulsive gastrointestinal motor activity due to hypokalemia.

Question 42

How does hypokalemia affect the heart?

Answer 42

It can cause dysrhythmias and U waves on an EKG.

Question 43

What is the typical rate for IV potassium replacement?

Answer 43

Generally 10-20 mEq/L per hour IV.

Question 44

What is the preferred route of potassium administration for treating hypokalemia?

Answer 44

Potassium orally is preferred over intravenous; central venous catheter (CVC) may be used; treatment may require several days.

Question 45

What is the effect of 10 mEq IV potassium on serum levels?

Answer 45

Each 10 mEq of IV potassium can raise the serum potassium by approximately 0.1 mmol/L.

Question 46

What treatments or actions should be avoided in hypokalemia?

Answer 46

Avoid excessive insulin, β-agonists, bicarbonate, hyperventilation, and diuretics.

Question 47

What are renal-related causes of hyperkalemia?

Answer 47

Renal failure and hypoaldosteronism (causes K+ secretion and excretion)

Question 48

Which type of drugs affecting the renin-angiotensin-aldosterone system (RAAS) can cause hyperkalemia?

Answer 48

Drugs that inhibit RAAS and drugs that inhibit K+ excretion

Question 49

How can neuromuscular blocking agents affect potassium levels?

Answer 49

Depolarizing NMBs like Succinylcholine (Succs) can cause hyperkalemia by increasing serum K+ by 0.5 to 1 mEq/L

*mEq is used interchangibly in monovalent ions just fyi

ChatGPT:
For monovalent ions (those with a charge of +1 or -1), like potassium (K+), sodium (Na+), chloride (Cl-), and bicarbonate (HCO3-), 1 mmol/L is equivalent to 1 mEq/L because their valence is 1.

However, for divalent ions (those with a charge of +2 or -2), like calcium (Ca2+), magnesium (Mg2+), and sulfate (SO4^2-), the situation is different. For these ions, 1 mmol/L is equivalent to 2 mEq/L because their valence is 2. Therefore, when converting concentrations for divalent ions, the concentration in millimoles is multiplied by 2 to get the concentration in milliequivalents.

Question 50

What role does acidosis play in potassium balance?

Answer 50

Both respiratory and metabolic acidosis can lead to hyperkalemia.

Question 51

Which conditions associated with cell damage can lead to hyperkalemia?

Answer 51

Cell death from trauma, use of tourniquets, and massive blood transfusion.

Question 52

What are the symptoms of chronic hyperkalemia?

Answer 52

Chronic hyperkalemia may cause minimal symptoms like malaise and gastrointestinal upset.

Question 52

What neuromuscular symptoms can occur with hyperkalemia?

Answer 52

Skeletal muscle paralysis and decreased fine motor skills.

Question 53

How does hyperkalemia affect the heart?

Answer 53

It can cause cardiac dysrhythmias.

Question 54

What are the EKG progression signs of hyperkalemia?

Answer 54

• Peaked T waves
• P wave disappearance
• Prolonged QRS complex
• Sine wave formation
• Asystole

Question 55

When should you dialyze a hyperkalemic patient before surgery?

Answer 55

Dialyze within 24 hours prior to surgery.

Question 56

What is the first initial treatment for hyperkalemia and why?

Answer 56

Calcium is given to quickly stabilize the cell membrane.

Question 57

How does hyperventilation affect serum potassium levels?

Answer 57

Increasing the pH by 0.1 can decrease K+ by 0.4-1.5 mmol/L.

Question 58

What is the role of insulin and glucose in treating hyperkalemia?

Answer 58

Insulin, given with glucose (10 units IV: 25g D50), can lower K+ levels, working in 10-20 minutes.

Question 59

What is the role of bicarbonate in managing hyperkalemia?

Answer 59

Bicarbonate can help shift potassium into cells by increasing blood pH, reducing serum levels.

Question 60

Which diuretics are useful in treating hyperkalemia?

Answer 60

Loop Diuretics can be used to increase renal excretion of potassium.

Question 60

How does Kayexalate work in treating hyperkalemia?

Answer 60

Kayexalate binds to K in digestive tract and removes potassium from the body, working over hours to days.

Question 61

What should be avoided in the management of hyperkalemia?

Answer 61

• Avoid using Succinylcholine (0.5-1 mEq/L increase)
• Hypoventilation (decreased pH=increased K)
• Lactated Ringer’s solution (will also decrease pH=increased K)
• Potassium-containing IV fluids.

Question 62

What is the distribution of calcium in the body?

Answer 62

Only 1% of the body’s calcium is in the extracellular fluid (ECF); 99% is stored in bones.

Question 63

Which form of plasma calcium is physiologically active?

Answer 63

Only ionized plasma calcium (Ca++) is physiologically active, not protein-bound calcium.

Question 64

What are the normal levels of ionized calcium (iCa++) in the blood?

Answer 64

Normal iCa++ levels range from 1.2 to 1.38 mmol/L.

Question 65

How are ionized calcium levels affected by albumin and pH?

Answer 65

Ionized calcium levels are influenced by albumin levels and pH.

• 60% plasma Ca++ is protein bound (mainly to albumin)
• pH changes influence the binding of Ca++ to albumin

Increase in pH/alkalosis=Increased Ca++ binding to albumin, therefore a decrease in plasma Ca++

Question 66

Which hormone increases gastrointestinal absorption, renal reabsorption of calcium, and pulls calcium from bone?

Answer 66

Parathyroid hormone (PTH) increases GI absorption, renal reabsorption, and mobilizes calcium from bone.

Question 67

What role does vitamin D play in calcium regulation?

Answer 67

Vitamin D augments intestinal calcium absorption.

Question 68

How does calcitonin affect calcium levels?

Answer 68

Calcitonin promotes bone resorption, which decreases plasma calcium levels.

Question 69

Aldosterone _________ effects K+

Answer 69

inversely

Question 70

3 major categories of cause of hypokalemia?

Answer 70

Renal loss
GI loss
Transcellular shift

Question 71

Aldosterone causes K+ ________ & ________

Answer 71

secretion & excretion

Question 72

Succinylcholine increases serum K+ by __________

Answer 72

0.5-1 mEq/L

Question 73

Dialysis ALSO initially causes ___________

Answer 73

Hypovolemia

Question 74

pH Δ’s influence the ____________ of Ca++ to albumin

Answer 74

binding

Question 75

___% plasma Ca++ is protein bound (mainly to _________)

Answer 75

• 60
• Albumiin

Question 76

↑pH/Alkalosis leads to ↑Ca++ binding to albumin

Therefore, there will be a ________ in plasma iCa++

Answer 76

decrease

Question 77

What can cause a decrease in parathyroid hormone (PTH) secretion leading to hypocalcemia?

Answer 77

Hypocalcemia can result from reduced PTH secretion, often as a complication of thyroid or parathyroid surgery.

Question 78

How does magnesium deficiency affect calcium levels?

Answer 78

Magnesium deficiency can lead to hypocalcemia as magnesium is required for PTH production

Question 79

What role does vitamin D play in calcium levels?

Answer 79

Low vitamin D or disorders of vitamin D metabolism can lead to hypocalcemia due to reduced calcium absorption from the gut.

Question 80

How does renal failure contribute to hypocalcemia?

Answer 80

Renal failure can cause hypocalcemia due to the kidneys not responding to PTH effectively.

Question 81

Why can massive blood transfusions lead to hypocalcemia?

Answer 81

The citrate preservative in blood products can bind calcium, leading to hypocalcemia.

Question 82

What are the target sites of PTH action to increase calcium absorption?

Answer 82

PTH acts on:

• The bones to mobilize calcium
• The kidneys to increase calcium reabsorption
• The gastrointestinal system to enhance calcium absorption

Question 83

Why is magnesium important for PTH function?

Answer 83

Magnesium is essential for the production and secretion of PTH.

Question 84

What is the role of Vitamin D in calcium homeostasis?

Answer 84

Vitamin D facilitates gastrointestinal absorption of calcium.

Question 85

When should ionized calcium (iCa++) levels be checked in the context of blood transfusions?

Answer 85

Check iCa++ after transfusing 4 or more units of packed red blood cells (PRBCs), as you may need to administer calcium to counteract the binding effects of citrate in transfused blood.

Question 86

What are neurological symptoms of hypercalcemia?

Answer 86

Confusion and lethargy.

Question 87

How does hypercalcemia affect muscle tone and reflexes?

Answer 87

Causes hypotonia and decreased deep tendon reflexes (↓DTR).

Question 88

What are gastrointestinal symptoms of hypercalcemia?

Answer 88

Abdominal pain and nausea/vomiting (N/V).

Question 89

What is a characteristic EKG change in hypercalcemia?

Answer 89

Short QT interval (QT-I).

Question 90

What chronic condition can result from elevated calcium levels?

Answer 90

Chronic high calcium levels can lead to hypercalciuria and nephrolithiasis.

Question 91

What sensations are typical in hypocalcemia?

Answer 91

Paresthesias.

Question 92

What behavioral changes might indicate hypocalcemia?

Answer 92

Irritability.

Question 93

How can hypocalcemia affect blood pressure?

Answer 93

Hypocalcemia can cause hypotension (HoTN).

Question 94

What are severe neurological symptoms of hypocalcemia?

Answer 94

Seizures and myocardial depression.

Question 95

What is a characteristic EKG change in hypocalcemia?

Answer 95

Prolonged QT interval (QT-I).

Question 96

What is a life-threatening complication of hypocalcemia post-parathyroidectomy?

Answer 96

Hypocalcemia-induced laryngospasm, which can be a life-threatening complication.

Question 97

Extra caution when extubating parathyroidectomy, always have ____________ plan

Answer 97

Larangospasm

Question 98

What dietary issues can lead to hypomagnesemia?

Answer 98

Low dietary intake or poor absorption can cause hypomagnesemia.

Question 99

How can renal function affect magnesium levels?

Answer 99

Renal wasting can lead to hypomagnesemia.

Question 100

What are muscular symptoms of hypomagnesemia?

Answer 100

Muscle weakness or excitation can occur.

Question 101

What are the neurological effects of hypomagnesemia?

Answer 101

Seizures may be a symptom of hypomagnesemia.

Question 102

What cardiac dysrhythmia is associated with hypomagnesemia?

Answer 102

Polymorphic V-tach or
Torsades De Pointes

Question 103

Where are the kidneys located?

Answer 103

Retroperitoneal T12-L4

Right is slightly caudal to the left to accommodate liver

Question 104

How common is hypermagnesemia and what are its usual causes?

Answer 104

Hypermagnesemia is very uncommon and is generally due to:

Overtreatment
- Pre-eclampsia/eclampsia
- Pheochromocytoma

Question 105

What symptoms are associated with magnesium levels of 4-5 mEq/L?

Answer 105

Lethargy, nausea/vomiting (N/V), and flushing.

Question 106

What symptoms appear when magnesium levels exceed 6 mEq/L?

Answer 106

Hypotension (HoTN) and decreased deep tendon reflexes (↓DTR).

Question 107

What are the severe symptoms of magnesium levels over 10 mEq/L?

Answer 107

Paralysis, apnea, heart blocks, and cardiac arrest.

Question 108

What are the treatment options for hypermagnesemia?

Answer 108

Treatment includes diuresis, intravenous calcium (to stabilize cell membranes), and dialysis.

Question 109

What is the nephron?

Answer 109

The nephron is the primary structural and functional unit of the kidney. Each kidney contains approximately 1 million nephrons.

Question 110

What are the main components of a nephron?

Answer 110

A nephron consists of the:
* glomerulus, tubular system
* Bowman’s capsule
* proximal tubule (PCT)
* loop of Henle
* distal tubule (DCT)
* collecting duct.

Question 111

What percentage of cardiac output does the kidney receive?

Answer 111

The kidneys receive 20% of the cardiac output (COP).

Question 112

How much blood do the kidneys filter per minute?

Answer 112

The kidneys filter 1 to 1.25 liters of blood per minute (L/min).

Question 113

What is the outer layer of the kidney called and what percentage of renal blood flow (RBF) does it receive?

Answer 113

The outer layer is called the cortex, and it receives the majority of renal blood flow, about 85-90%.

Question 114

What is the inner layer of the kidney called?

Answer 114

The inner layer of the kidney is called the medulla.

Question 115

Which part of the kidney is particularly vulnerable to necrosis due to hypotension?

Answer 115

The Loop of Henle (LOH) in the medulla is particularly vulnerable to developing necrosis in response to hypotension (decreased kidney perfusion).

Question 116

What do the kidneys regulate in terms of extracellular fluid?

Answer 116

The kidneys regulate extracellular (EC) volume, osmolarity, and composition.

Question 117

How do the kidneys contribute to blood pressure regulation?

Answer 117

he kidneys regulate blood pressure both intermediately and long-term via the renin-angiotensin-aldosterone system (RAAS) and atrial natriuretic peptide (ANP).

Question 118

What is the role of the kidneys in excretion?

Answer 118

The kidneys excrete toxins and metabolites from the body.

Question 119

How do the kidneys maintain acid/base balance?

Answer 119

The kidneys regulate the balance of acids and bases by excreting hydrogen ions and reabsorbing bicarbonate.

Question 120

What hormones are produced by the kidneys?

Answer 120

The kidneys produce several hormones including renin, erythropoietin, calcitriol, and prostaglandins.

Question 121

How do the kidneys assist in blood glucose homeostasis?

Answer 121

The kidneys contribute to blood glucose homeostasis by producing glucose through gluconeogenesis and filtration and reabsorption of glucose

Question 122

What is the normal range for the glomerular filtration rate (GFR)?

Answer 122

The normal GFR range is 125-140 mL/min. It is the best measure of renal function over time and is heavily influenced by hydration status.

Question 123

What is the creatinine clearance range and how is it performed?

Answer 123

Creatinine clearance measures 110-140 mL/min and is obtained from a 24-hour urine test.

Creatinine is freely filtered and not reabsorbed, making this the most reliable measure of GFR.

Question 124

What is the normal range for serum creatinine and what does it indicate?

Answer 124

The normal range for serum creatinine is 0.6-1.3 mg/dL, and it correlates with muscle mass. It can be influenced by high protein diet, supplements, and muscle breakdown.

Question 125

Why is having a baseline serum creatinine important in acute monitoring?

Answer 125

It is important for acute monitoring as serum creatinine (SC) is inversely related to GFR.

In acute cases, a doubling of SC can mean a drop in GFR by 50%.

Question 126

What is the role of the Renin-Angiotensin-Aldosterone system (RAAS)?

Answer 126

RAAS increases sodium and water reabsorption, which helps regulate volume and blood pressure.

Question 127

How does Atrial Natriuretic Peptide (ANP) function in the kidneys?

Answer 127

ANP is secreted from cardiac atria and binds to receptors in the kidney, leading to increased sodium and water excretion to decrease blood volume and pressure.

Question 128

How do the kidneys regulate pH balance?

Answer 128

The kidneys regulate pH balance by the reabsorption and excretion of bicarbonate (HCO3-) and hydrogen ions (H+).

Question 129

What is Erythropoietin’s (EPO) role in renal function?

Answer 129

EPO is involved in red blood cell (RBC) production, and renal patients often require EPO supplementation due to kidney dysfunction.

Question 130

What role does Calcitriol play in renal function?

Answer 130

Calcitriol is crucial for maintaining serum calcium levels.

Question 131

What is the role of prostaglandins (PGs) in the kidneys?

Answer 131

Prostaglandins act as inflammatory modulators and have vasodilatory effects that help maintain renal blood flow.

Question 132

How are the kidneys involved in glucose regulation?

Answer 132

The kidneys contribute to gluconeogenesis and are responsible for the filtration and reabsorption of glucose.

Question 133

What is the normal range for Blood Urea Nitrogen (BUN)?

Answer 133

The normal range for BUN is 10-20 mg/dL.

Question 134

What does a low BUN indicate?

Answer 134

Low BUN could indicate malnutrition or a volume-diluted state.

Question 135

What could cause a high BUN level?

Answer 135

High BUN could be due to a high protein diet, dehydration, GI bleed, trauma, or muscle wasting.

Question 136

What is the normal BUN:Creatinine ratio and what does it signify?

Answer 136

The normal BUN:Creatinine ratio is 10:1, and it’s a good measure of hydration status because BUN is reabsorbed and creatinine is not.

Question 137

What does proteinuria indicate and what is the normal range?

Answer 137

Normal proteinuria is less than 150 mg/dL. More than 750 mg/day could suggest glomerular injury or a urinary tract infection (UTI).

Question 138

What does the specific gravity of urine measure and what is the normal range?

Answer 138

Specific gravity (1.001-1.035) compares the weight of 1ml urine to 1ml distilled water and measures the nephron’s ability to concentrate urine.

Question 139

What should be considered when assessing a patient’s hydration status?

Answer 139

Consider the big picture, including history and physical exam, along with orthostatic pressure changes.

Question 140

Which lab changes might you see with dehydration?

Answer 140

Decreased base excess (↓BE) and increased lactate levels may be indicative of volume loss.

Question 141

What is a late sign of volume loss in renal assessment?

Answer 141

A drop in urine output (UOP) is a late sign of volume loss.

Question 142

What is the normal range for urine output?

Answer 142

Normal UOP is 30 ml/hr or 0.5-1 ml/kg/hr.

Question 143

How is oliguria defined?

Answer 143

Oliguria is defined as less than 500 mL of urine produced in 24 hours.

Question 144

What does a compressed/collapse IVC indicate?

What other way could you have to patient do to determine fluid responsiveness?

Answer 144

50% collapse = Dehydration

Passive leg raise to determine fluid responsiveness

Question 145

How can ultrasound (US) be used in assessing volume status?

Answer 145

Ultrasound is used to assess the inferior vena cava (IVC) for changes in diameter that correlate with volume status.

Slide 28 - extra info added by ChatGPT

Question 146

What do CVP and RAP indicate in volume monitoring?

Answer 146

Central venous pressure (CVP) and right atrial pressure (RAP) are indicators of right-sided heart pressures and can reflect fluid status.

Slide 28 - extra info added by ChatGPT

Question 147

Why are LAP and PCWP important in renal assessment?

Answer 147

Left atrial pressure (LAP) and pulmonary capillary wedge pressure (PCWP) are important as they can be powerful stimuli for renal vasoconstriction, affecting kidney function.

Slide 28 - extra info added by ChatGPT

Question 148

What does pulmonary artery pressure (PAP) indicate?

Answer 148

Pulmonary artery pressure (PAP) can indicate fluid overload, especially in the context of heart failure.

Slide 28 - extra info added by ChatGPT

Question 149

What does stroke volume variation (SVV) measure?

Answer 149

SVV compares inspiratory vs. expiratory pressure to assess fluid responsiveness, particularly in ventilated patients with sinus rhythm.

Slide 28 - extra info added by ChatGPT

Question 150

Over what time period does acute kidney injury develop?

Answer 150

AKI develops over hours to days.

Question 151

What percentage of hospitalized and ICU patients are affected by AKI?

Answer 151

AKI affects 20% of hospitalized patients and 50% of ICU patients.

Question 152

What are common causes of AKI?

Answer 152

AKI can be caused by hypotension/hypovolemia and nephrotoxins.

Question 153

What is azotemia and its significance in AKI?

Answer 153

Azotemia is the buildup of nitrogenous waste products such as urea and creatinine and is a hallmark of AKI.

Question 154

What is the mortality rate of AKI with multi-system organ failure (MSOF) requiring dialysis?

Answer 154

AKI with MSOF requiring dialysis carries a mortality rate greater than 50%.

Question 155

Can AKI be reversible and what intervention may be used?

Answer 155

AKI is reversible with timely interventions and may be managed with Continuous Venovenous Hemodiafiltration (CVVHD) to get through temporary insults.

Question 156

Risk Factors of AKI:

Answer 156

• Pre-existing renal disease
• Advanced age
• CHF
• PVD
• Diabetes
• Sepsis (hypotension)
• Jaundice
• Major operative procedures
• IV Contrast

Question 157

What serum creatinine changes meet the AKI diagnostic criteria?

Answer 157

An increase in serum creatinine by 0.3 mg/dL within 48 hours or an increase by 50% within 7 days.

Question 158

What changes in creatinine clearance indicate AKI?

Answer 158

A decrease in creatinine clearance by 50%.

Question 159

Is oliguria always present in AKI?

Answer 159

Abrupt onset of oliguria is a diagnostic criterion, although it is not always seen in AKI.

Question 160

Can AKI be asymptomatic?

Answer 160

Yes, AKI can be asymptomatic.

Question 161

What general symptoms might a person with AKI experience?

Answer 161

Malaise and hypotension (HoTN) can be symptoms of AKI.

Question 162

What are the volume status symptoms associated with AKI?

Answer 162

Patients may present as hypovolemic or hypervolemic.

Question 163

Prerenal Azotemia Causes:

Answer 163

Pre-renal= ↓ renal perfusion

Hemorrhage
GI fluid loss
Trauma
Surgery
Burns
Cardiogenic shock
Sepsis
Aortic clamping
Thromboembolism

Question 164

Renal Azotemia Causes:

Answer 164

Renal = nephron injury

Acute glomerulonephritis
Vasculitis
Interstitial nephritis
Acute Tubular Necrosis (ATN)
Contrast dye
Nephrotoxic drugs
Myoglobinuria

Question 165

Postrenal Azotemia Causes:

Answer 165

Post-renal = outflow obstruction (easiest to treat)

Nephrolithiasis
Benign Prostatic Hyperplasia (BPH)
Clot retention
Bladder carcinoma

Question 166

What is the prevalence of pre-renal azotemia in AKI cases?

Answer 166

Pre-renal azotemia is the most common form of AKI, accounting for half of hospital-acquired AKI cases.

Question 167

How can anesthesia medications affect renal blood flow?

Answer 167

Anesthesia medications, along with volume and blood loss, can lead to decreased renal blood flow (RBF).

Question 168

What is the typical BUN:Cr ratio in pre-renal AKI?

Answer 168

In pre-renal AKI, the BUN:Creatinine ratio is greater than 20:1.

Question 169

Is pre-renal azotemia reversible?

Answer 169

Yes, pre-renal azotemia is usually reversible as it’s often a volume issue.

Question 170

: What is the relationship between pre-renal azotemia and acute tubular necrosis (ATN)?

Answer 170

Pre-renal azotemia is the most common cause of ATN if not reversed, as the condition can progress from pre-renal to renal azotemia.

Question 171

What happens to sodium and water reabsorption in pre-renal azotemia?

Answer 171

In pre-renal azotemia, the body is still reabsorbing sodium and water efficiently.

Question 172

What is renal azotemia?

Answer 172

Renal azotemia is intrinsic renal disease and is a potentially reversible condition along a continuum of renal injury

Renal AKI BUN:Cr decreased from pre-renal AKI (>20)

Question 173

What are the treatments for pre-renal azotemia?

Answer 173

Treatment includes restoring renal blood flow with fluids, mannitol, diuretics, maintaining mean arterial pressure (MAP), and possibly using pressors.

Question 174

What are late symptoms of renal azotemia related to glomerular filtration rate?

Answer 174

Decreased GFR is a late symptom in renal azotemia, indicating significant impairment in kidney function.

Question 175

How does renal azotemia affect blood urea nitrogen (BUN) levels?

Answer 175

There is decreased urea reabsorption in the proximal tubule, leading to decreased BUN.

Question 176

What happens to blood creatinine levels in renal azotemia?

Answer 176

Decreased creatinine filtration leads to increased blood creatinine levels.

Question 177

What is the typical BUN:Creatinine ratio in renal azotemia?

Answer 177

The BUN:Creatinine ratio often falls below 15:1 in cases of renal azotemia.

Question 178

What is the primary cause of post-renal azotemia?

Answer 178

Post-renal azotemia is caused by outflow obstruction of urine from the kidneys.

Question 179

What effect does post-renal azotemia have on nephron tubular pressure?

Answer 179

It leads to increased nephron tubular hydrostatic pressure.

Question 180

Which diagnostic tool is useful for post-renal azotemia?

Answer 180

Renal ultrasonography is useful for identifying the cause and location of the obstruction.

Question 181

How does the duration of obstruction affect reversibility in post-renal azotemia?

Answer 181

The reversibility of post-renal azotemia is inversely related to the duration of the obstruction.

Question 182

What is the treatment for post-renal azotemia?

Answer 182

The treatment involves removing the obstruction if possible.

Question 183

What can prolonged obstruction lead to in post-renal azotemia?

Answer 183

Persistent obstruction can lead to damage in the tubular epithelium.

Question 184

What causes prerenal AKI and what are its features?

Answer 184

Prerenal AKI is due to true volume loss or decreased effective arterial blood volume. Causes include hypovolemia, decreased arterial supply due to conditions like cardiorenal or hepatorenal syndrome, and certain drugs.

It’s characterized by a

BUN/Cr ratio > 20:1
FeNa (fractional excretion of Na) < 1%
FEurea (Fractional excretion of Urea) < 35%.
Urine [Na] <20
Seditment: Bland and hyaline casts

Slide 38

Question 185

What causes intrinsic AKI and what are its features?

Answer 185

Intrinsic AKI is due to damage to the glomeruli, tubules, or interstitium. Causes include ATN, ischemia, toxic substances, and inflammation.

It’s characterized by a
BUN/Cr ratio < 20:1
FeNa > 2% for ATN (varies for other causes)
FEurea > 50% for ATN.
Urine [Na] >20
Sediment - ATN=Muddy, brown casts; AIN= WBC casts+ Neg Ucx; GN= RBC casts; Abx/chol. emboli= urine E.O.s; NSAIDS= lymphocytes

Slide 38

Question 186

What are the key diagnostic markers for different types of AKI?

Answer 186

Urine sediment in

-prerenal AKI is typically bland with hyaline casts.
-In intrinsic AKI, the urine sediment can show muddy brown casts for ATN and White blood cell casts for acute interstitial nephritis (AIN), among others.
- postrenal AKI urine sediment might contain blood.

Question 187

Neurological complications of AKI

Answer 187

Related to protein/amino acids buildup in blood
Uremic Encephalopathy (Dialysis improves)
Mobility disorders
Neuropathies
Myopathies
Seizures
Stroke

Question 188

What are the cardiovascular complications associated with AKI?

Answer 188

Cardiovascular complications can include systemic hypertension, left ventricular hypertrophy (LVH), congestive heart failure (CHF), pulmonary edema, uremic cardiomyopathy, arrhythmias, and pericarditis with or without effusion.

Question 189

What is the typical progression of cardiovascular complications in AKI?

Answer 189

The typical order of incidence is hypertension (HTN) → LVH → CHF → ischemic heart disease → anemic heart failure → rhythm disturbances → pericarditis with or without effusion → cardiac tamponade → uremic cardiomyopathy.

Question 190

What type of anemia is associated with AKI?

Answer 190

Anemia related to AKI is due to decreased erythropoietin (EPO) production, reduced red blood cell production, and decreased red blood cell survival.

Question 191

How does AKI affect platelet function?

Answer 191

AKI can lead to platelet dysfunction; platelet function assays or thromboelastography (TEG) are valuable for assessing this condition.

Question 192

What role does von Willebrand factor (vWF) play in AKI?

Answer 192

vWF is disrupted by uremia in AKI, which can affect coagulation.

Question 193

What is the role of DDAVP in the management of hematological complications in AKI?

Answer 193

Prophylactic Desmopressin (DDAVP) can increase vWF and Factor VIII levels, which helps improve coagulation in patients with AKI.

Question 194

Why might coagulation factors be affected in AKI?

Answer 194

Uremic conditions in AKI disrupt normal coagulation factor function, necessitating interventions like DDAVP to restore effective coagulation.

Question 195

What electrolyte imbalance is commonly seen in AKI?

Answer 195

Hyperkalemia is a common electrolyte imbalance in AKI due to decreased excretion by the kidneys.

Question 196

What fluid and electrolyte imbalances are associated with AKI?

Answer 196

Water and sodium imbalances are frequent in AKI, leading to conditions such as fluid overload or depletion.

Question 197

Why might hypoalbuminemia occur in AKI?

Answer 197

Hypoalbuminemia can occur if the kidneys allow albumin to escape, which may happen in AKI due to altered glomerular permeability.

Question 198

What type of acid-base imbalance is often seen in AKI?

Answer 198

Metabolic acidosis is common in AKI because the kidneys cannot excrete acid effectively.

Question 199

How does AKI contribute to malnutrition?

Answer 199

AKI can lead to malnutrition due to losses of nutrients and protein through impaired kidney function.

Question 200

What is the connection between AKI and hyperparathyroidism?

Answer 200

Hyperparathyroidism may develop as the parathyroid glands go into overdrive in an attempt to stimulate the kidneys to reabsorb calcium, often a compensatory response to the kidneys’ impaired function in AKI.

Question 201

What initial management steps should be taken for AKI in the context of anesthesia?

Answer 201

Correct fluid, electrolyte, and acid/base status to prevent further renal injury.

Question 202

What type of fluid is preferred for AKI management during anesthesia and why?

Answer 202

Normal Saline (NS) is preferred due to the absence of potassium, which is important for patients at risk of hyperkalemia.

Question 203

What should be considered when using colloids in AKI?

Answer 203

Be cautious with colloids due to the risk of exacerbating fluid overload and affecting osmolarity.

Question 204

What is the target for mean arterial pressure (MAP) maintenance during anesthesia in AKI?

Answer 204

Maintain MAP at least 20% of baseline to ensure adequate renal blood flow.

Question 205

What role do vasopressors play in managing AKI during anesthesia?

Answer 205

Vasopressors, such as Vasopressin and Alpha-agonists, may be used to maintain MAP and renal perfusion.

Question 206

Why is prophylactic sodium bicarbonate administered during anesthesia in the context of AKI?

Answer 206

It helps decrease the formation of free radicals and prevents acute tubular necrosis (ATN) from progressing to renal failure.

Question 207

How does Vasopressin aid in managing AKI compared to alpha agonists?

Answer 207

Vasopressin preferentially constricts the efferent arteriole, which is more effective than alpha agonists for maintaining renal blood flow.

Question 208

What consideration should be given to hemodynamic monitoring in patients with kidney issues?

Answer 208

There should be a low threshold for invasive hemodynamic monitoring to closely track and manage blood pressure and fluid status.

Question 208

What is the preference regarding dialysis before surgery?

Answer 208

Prefer preoperative dialysis to optimize fluid and electrolyte balance, especially if the patient is already on a dialysis regimen

Question 209

What lab values are particularly important to have before anesthesia in patients with kidney issues?

Answer 209

Recent laboratory values, especially potassium (K+), should be reviewed to manage risks of electrolyte imbalance during anesthesia.

Question 210

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What equipment should be readily available for patients with kidney issues undergoing anesthesia?

Answer 210

Point-of-care (POC) equipment should be available for immediate lab testing and monitoring during the perioperative period.

Question 211

How should drug dosing be approached in these patients?

Answer 211

Drug dosing should be tailored to the individual’s renal function, avoiding drugs with active metabolites, those that decrease renal blood flow (RBF), and renal toxins.

Question 212

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What may be required if the patient is unable to clear drugs on their own?

Answer 212

Post-op dialysis

Question 213

What is CKD?

Answer 213

CKD stands for chronic kidney disease. It’s a progressive condition where kidney function declines over time.

Question 214

How does CKD commonly present?

Answer 214

• CKD patients often undergo surgeries for dialysis access
• May require procedures like toe/foot surgeries due to diabetes complications.
• They might also have non-healing wounds and frequent healthcare visits.

Question 215

CKD chart to look at:

Answer 215

Question 216

What is the GFR range for Stage 1 CKD?

Answer 216

Stage 1 CKD is characterized by kidney damage with normal or increased GFR (>90 mL/min/1.73m²).

Question 217

What is the GFR range for Stage 2 CKD?

Answer 217

Stage 2 CKD involves kidney damage with mildly decreased GFR (60-89 mL/min/1.73m²).

Question 218

What is the GFR range for Stage 3 CKD?

Answer 218

Stage 3 CKD indicates moderately decreased GFR (30-59 mL/min/1.73m²).

Question 219

What is the GFR range for Stage 4 CKD?

Answer 219

Stage 4 CKD is characterized by severely decreased GFR (15-29 mL/min/1.73m²).

Question 220

What is the GFR range for Stage 5 CKD?

Answer 220

Stage 5 CKD represents kidney failure with a GFR of less than 15 mL/min/1.73m².

Question 221

What happens to GFR with age?

Answer 221

GFR decreases by 10 per decade starting from age 20.

Question 222

What cardiovascular effects are associated with CKD?

Answer 222

CKD commonly leads to systemic hypertension, which is both a cause and consequence of the disease.

Question 223

What contributes to the development of systemic hypertension in CKD?

Answer 223

• Retention of sodium and water, leading to volume overload leading to the activation of the renin-angiotensin-aldosterone system (RAAS).

Question 224

What are the first-line treatments for hypertension in CKD?

Answer 224

Thiazide diuretics are often the first-line treatment for hypertension in CKD patients.

Additionally, ACE inhibitors (ACE-I) or angiotensin II receptor blockers (ARBs) may be necessary.

Question 225

How do ACE inhibitors (ACE-I) and angiotensin II receptor blockers (ARBs) affect CKD?

Answer 225

ACE-I and ARBs are often used in CKD to:

• Decrease systemic blood pressure and glomerular pressure
• Reduce proteinuria by decreasing glomerular hyperfiltration
• Slow the progression of glomerulosclerosis

Question 226

Why are ACE-I/ARBs typically withheld on the day of surgery for CKD patients?

Answer 226

ACE inhibitors (ACE-I) and angiotensin II receptor blockers (ARBs) are withheld on the day of surgery in CKD patients to reduce the risk of profound hypotension during anesthesia induction.

Question 227

What interventions may be necessary if ACE-I or ARBs are continued up to the day of surgery in CKD patients?

Answer 227

If ACE inhibitors (ACE-I) or angiotensin II receptor blockers (ARBs) are continued up to the day of surgery in CKD patients:

• Vasopressin
• Norepinephrine
• Epinephrine

may be needed to counteract the potential risk of hypotension.

Question 228

What cardiovascular effects are associated with CKD?

Answer 228

CKD is associated with dyslipidemia, often characterized by elevated triglycerides (>500 mg/dL) and LDL cholesterol (>100 mg/dL).

Question 229

What is a common risk associated with dyslipidemia in CKD?

Answer 229

CKD patients are predisposed to “silent MI” (silent myocardial infarction), which may occur without typical symptoms due to peripheral and autonomic neuropathy, leading to blunted sensation.

Question 230

Which populations are at high risk for silent MI in CKD?

Answer 230

Women and individuals with diabetes are high-risk populations for silent myocardial infarction in the context of CKD.

Question 231

What hematologic effects are associated with CKD?

Answer 231

CKD commonly leads to anemia, which is often responsive to exogenous erythropoietin therapy. The target hemoglobin level for CKD patients is typically around 10 g/dL.

Question 232

What are the considerations for platelet dysfunction in CKD?

Answer 232

CKD patients may experience platelet dysfunction, which can impact their coagulation status.

Question 233

What should be considered before transfusing blood in CKD patients?

Answer 233

Transfusion in CKD patients requires careful consideration of risks versus benefits. Excess hemoglobin can lead to sluggish circulation.

Acidosis and hyperkalemia is also associated with blood transfusions.

Question 234

Indications to consider dialysis:

Answer 234

• Volume overload
• Severe hyperkalemia
• Metabolic acidosis
• Symptomatic uremia
• Failure to clear medications

Question 235

What should be considered regarding dialysis modalities?

Answer 235

Hemodialysis (HD) is more efficient than peritoneal dialysis (PD).

However, PD may be more suitable for patients who can’t tolerate fluid shifts, such as those with poor cardiac function.

Question 236

What is the most common side effect of hemodialysis?

Answer 236

Hypotension is the most common side effect of hemodialysis, which may occur due to rapid fluid removal during the procedure.

Question 237

What is a leading cause of mortality in dialysis patients?

Answer 237

Infection is a leading cause of mortality in dialysis patients due to their impaired immune system and delayed wound healing.

Question 238

What considerations are important for anesthesia in patients with end-stage renal disease (ESRD)?

Answer 238

Anesthesia in ESRD patients requires:

• Assessing stability
• Monitoring body weight pre/post dialysis (within 24 hours of surgery)
• Evaluating blood pressure control
• Determining whether medications should be continued
• Managing glucose levels and A1C
• Taking aspiration precautions, especially in patients with diabetes and obesity.

Question 239

What precautions should be taken for uremic bleeding in ESRD patients undergoing anesthesia?

Answer 239

Uremic bleeding risk in ESRD patients requires:

• Assessing normal platelet count & function, PT, and PTT

Treatment options may include:
- Cryoprecipitate
- Factor VIII
- von Willebrand factor (vWF)
- Desmopressin, which peaks at 2-4 hours and lasts 6-8 hours

• Tachyphylaxis should also be considered.

Question 240

How are many anesthetic agents eliminated in patients with renal impairment?

Answer 240

Many anesthetic agents are lipid-soluble and are reabsorbed by renal tubular cells, leading to prolonged effects in patients with renal impairment.

Question 241

What type of anesthetic agents are preferred in patients with renal impairment?

Answer 241

In patients with renal impairment, it is preferable to use anesthetic agents that are not dependent on renal elimination to avoid potential toxicity and prolonged effects.

Question 242

What characteristics make for the best neuromuscular blocking agents (NMB) in patients with renal impairment?

Answer 242

The best neuromuscular blocking agents (NMB) for patients with renal impairment are those that do not rely on renal elimination, as they can be safely used without the risk of accumulation and prolonged effects.

Question 243

Which 2 analgesic medications mentioned in the PPT should be avoided in patients with renal impairment?

Answer 243

avoid analgesic medications such as morphine and Demerol (meperidine) due to the risk of accumulation of active metabolites and potential toxicity.

Question 244

How are lipid insoluble drugs eliminated in patients with renal impairment?

Answer 244

Some medications are eliminated unchanged in urine, leading to prolonged duration of action (DoA) and increased risk of accumulation in patients with renal impairment.

Question 245

How is renal dosing typically determined for medications?

Answer 245

Renal dosing of medications is usually based on glomerular filtration rate (GFR)

Question 246

Give examples of medications that require renal dosing.

Answer 246

• Thiazide diuretics
• Loop diuretics
• Digoxin
• Many antibiotics

Question 247

Name 2 induction drugs that are primarily eliminated by the kidneys.

Answer 247

Phenobarbital

Thiopental

Question 248

Give 2 examples of muscle relaxants eliminated by the kidneys.

Answer 248

Pancuronium

Vecuronium

Question 249

What are 2 cholinesterase inhibitors that undergo renal excretion?

Answer 249

Edrophonium

Neostigmine

Question 250

Name 5 cardiovascular drugs that are excreted renally.

Answer 250

Atropine
Digoxin
Glycopyrrolate
Hydralazine
Milrinone

Question 251

Name 4 antimicrobials are primarily excreted by the kidneys?

Answer 251

Aminoglycosides
Cephalosporins
Penicillins
Vancomycin

Question 252

What morphine metabolites are excreted in the urine? by how much?

Answer 252

• morphine-3 glucuronide
• morphine-6 glucuronide
• 40%

Question 253

What is normeperedine?

What are the main adverse effects of Normeperidine?

Answer 253

Active metabolite of meperedine

The main adverse effect of Normeperidine is neurotoxicity, which can manifest as nervousness, tremors, muscle twitches, and seizures.

Question 254

How does Normeperidine accumulate in the body?

What is its parent drug elimination half-life?

What is normeperedine’s elimiation half-life?

Answer 254

Multiple doses of meperidine result in the accumulation of Normeperidine due to its long elimination half-life (15-30 hours) compared to meperidine (2-4 hours).

Question 255

What is the recommended potassium level for elective surgery?

Answer 255

Potassium should be less than 5.5 mEq/L for elective surgery.

Question 256

What is the recommendation for dialysis patients before elective surgery?

Answer 256

Dialysis patients should undergo dialysis within 24 hours preceding elective surgery.

Question 257

Why is aspiration prophylaxis important, especially in patients with diabetes mellitus (DM)?

Answer 257

Aspiration prophylaxis is crucial, especially in patients with diabetes mellitus (DM), to prevent the risk of aspiration during surgery.

Question 258

How does anesthesia and surgery affect renal blood flow (RBF) and glomerular filtration rate (GFR)?

Answer 258

Anesthesia and surgery decrease renal blood flow (RBF) and glomerular filtration rate (GFR).

Question 259

How does blood loss affect renal blood flow (RBF)?

Answer 259

Blood loss activates baroreceptors, leading to increased sympathetic nervous system (SNS) outflow.

Catecholamines activate α1-receptors, causing afferent arteriole constriction and decreased renal blood flow (RBF).

Question 260

What are the consequences of longer periods of hypotension during surgery?

Answer 260

Longer periods of hypotension, such as during cross-clamping, hemorrhage, or sepsis, lead to decreased renal blood flow (RBF).

Question 261

What clinical signs indicate hypovolemia in the context of hyponatremia?

Answer 261

Decreased skin turgor, flat neck veins, dry mucous membranes, orthostatic hypotension, tachycardia, and oliguria.

Question 262

With a urinary sodium concentration greater than 20 in a hypovolemic patient, what is the likely cause of hyponatremia?

Answer 262

Renal losses, which can be due to:

• Salt-losing nephritis
• Diuretic excess
• Osmotic diuresis
• Mineralocorticoid deficiency
• Ketonuria
• Renal tubular acidosis
• Metabolic alkalosis

Question 263

What does a urinary sodium concentration less than 20 indicate in a hyponatremic and hypovolemic patient?

Answer 263

Extrarenal losses, such as those from vomiting, diarrhea, third space losses (like burns, pancreatitis, or muscle trauma).

Question 264

What are the clinical signs of euvolemia in hyponatremia?

Answer 264

The absence of signs of volume depletion or volume overload; patients appear clinically normal in terms of volume status.

Question 265

In euvolemic hyponatremia, what does a urinary sodium concentration above 20 suggest?

Answer 265

Causes such as:

• Glucocorticoid deficiency
• Hypothyroidism
• High sympathetic drive
• Drugs
• Syndrome of Inappropriate Antidiuretic Hormone secretion (SIADH).

Question 266

For euvolemic hyponatremia with a urinary sodium concentration less than 20, what is the probable cause?

Answer 266

Salt-restricted diet.

Question 267

What are the signs of hypervolemia in a patient with hyponatremia?

Answer 267

Peripheral edema, rales (crackles heard in the lungs), and ascites.

Question 268

In hypervolemic hyponatremia, what does a urinary sodium concentration above 20 indicate?

Answer 268

Renal losses due to conditions like acute renal failure or chronic renal failure.

Question 269

With a urinary sodium concentration less than 20 in a hypervolemic patient, what could be the causes of hyponatremia?

Answer 269

Avid sodium reabsorption due to conditions such as nephrotic syndrome, cardiac failure, or cirrhosis.

Question 270

In the context of hypovolemia and hyponatremia, what does a urinary sodium (U_Na) concentration less than 20 mmol/L suggest?

Answer 270

It suggests extrarenal losses due to conditions such as vomiting, diarrhea, third-space losses (like burns, pancreatitis, or muscle trauma).

Question 271

When assessing a euvolemic patient with hyponatremia, what does a urinary sodium (U_Na) concentration less than 20 mmol/L suggest when paired with symptoms like decreased skin turgor and dry mucous membranes?

Answer 271

It suggests a salt-restricted diet

Question 272

What does a urinary sodium (U_Na) concentration greater than 20 mmol/L indicate in a hypervolemic patient with hyponatremia and signs like peripheral edema and ascites?

Answer 272

Renal losses due to acute renal failure or chronic renal failure.

Question 273

In a hypervolemic patient with hyponatremia, what does a urinary sodium (U_Na) concentration less than 20 mmol/L indicate?

Answer 273

Avid sodium reabsorption, which can be seen in conditions such as nephrotic syndrome, cardiac failure, or cirrhosis.

Question 274

What clinical signs suggest hypovolemia in the context of hypernatremia?

Answer 274

• Decreased skin turgor
• Flat neck veins
• Dry mucous membranes
• Orthostatic hypotension
• Tachycardia
• Oliguria.

Question 275

In a hypovolemic patient with hypernatremia, what does a urinary sodium (U_Na) concentration greater than 20 mmol/L indicate?

Answer 275

Renal salt and water loss due to causes such as
- Osmotic diuretics
- Loop diuretics
- Postrenal obstruction
- Intrinsic renal disease
- Pofound glycosuria

Question 276

For a hypovolemic patient with hypernatremia, what does a urinary sodium (U_Na) concentration less than 20 mmol/L suggest?

Answer 276

Extrarenal salt and water loss, potentially from diarrhea, GI fistulas, burns, or sweating.

Question 277

What does euvolemia in a patient with hypernatremia indicate about their water loss?

Answer 277

It suggests renal water loss due to diabetes insipidus (central, nephrogenic, or gestational)

or

extrarenal water loss from insensible losses through the respiratory tract or skin.

Question 278

What are the signs of hypervolemia in a patient with hypernatremia?

Answer 278

Peripheral edema, rales, and ascites.

Question 279

In a hypervolemic patient with hypernatremia and a urinary sodium (U_Na) concentration greater than 20 mmol/L, what is the likely cause?

Answer 279

Sodium gains due to conditions such as
- Hyperaldosteronism
- Cushing’s syndrome
- Hypertonic dialysis
- Intravenous sodium bicarbonate
- Sodium chloride tablets
- Hypertonic saline enemas
- Hypertonic alimentation
- Salt water drowning

Question 280

What are the possible causes of renal salt and water loss leading to hypovolemic hypernatremia with a urinary sodium concentration greater than 20 mmol/L?

Answer 280

• Osmotic diuretic use
• Loop diuretic use
• Postrenal obstruction
• Intrinsic renal disease
• Profound glycosuria

Question 281

What are some causes of extrarenal salt and water loss leading to hypernatremia with a urinary sodium concentration less than 20 mmol/L in a hypovolemic patient?

Answer 281

• Diarrhea
• Gastrointestinal fistulas
• Burns
• Excessive sweating

Question 282

In the context of euvolemia with hypernatremia, what are the causes of renal and extrarenal water loss when the urinary sodium concentration is variable?

Answer 282

Renal water loss can be due to diabetes insipidus (central, nephrogenic, or gestational), and extrarenal water loss can be due to insensible losses from the respiratory tract or skin.