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Deck 28: Kidney Diseases

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Question
Nutrition therapy for the nephrotic syndrome focuses on ____.

A) increasing the fat content in the diet
B) preventing protein-energy malnutrition and alleviating edema
C) high protein and kcalorie intake
D) high sodium intake
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to flip the card.
Question
A consequence of the nephrotic syndrome is the loss of plasma proteins in the urine, which contributes to ____.

A) an increased risk of blood clotting
B) a fluid shift from interstitial spaces to blood plasma
C) an increased risk of vitamin D toxicity
D) Anabolic buildup of muscle mass
Question
What is the most abundant plasma protein?

A) albumin
B) immunoglobulins
C) vitamin D-binding protein
D) transferrin
Question
Diets high in vitamin D and calcium are recommended for children with nephrotic syndrome to prevent ____.

A) beriberi
B) marasmus
C) nephrosclerosis
D) rickets
Question
What best describes the function of the ureter?

A) storing urine before it is excreted
B) Conducting urine from the kidneys to the bladder
C) transporting urine from the bladder to out side of the body
D) carrying blood from the kidneys back to the heart
Question
For patients with nephrotic syndrome, the recommended daily protein intake is ____ g/kg of body weight.

A) 0.4 to 0.6
B) 0.6 to 0.8
C) 0.8 to 1.0
D) 1.0 to 1.2
Question
In the nephrotic syndrome, urinary protein losses generally average about ____ grams daily.

A) 3 to 3.5
B) 5.5 to 6
C) 9 to 10.5
D) 11 to 12
Question
Proteinuria due to nephrotic syndrome results in a loss of immunoglobulins, which increases the risk for ____.

A) edema
B) infection
C) wasting
D) hypertriglyceridemia
Question
In patients with the nephrotic syndrome, energy intake of about ____ kcal/kg of body weight daily will sustain weight and spare protein.

A) 15
B) 25
C) 35
D) 45
Question
Daily sodium intake should be restricted to about ____ grams for patients with the nephrotic syndrome.

A) 0.5 to 1.0
B) 1.0 to 2.0
C) 2.0 to 3.0
D) 3.0 to 4.0
Question
One large egg contains about ____ mg of sodium.

A) 10
B) 40
C) 60
D) 200
Question
What hormone secreted by the kidneys stimulates the production of red blood cells?

A) erythropoietin
B) renin
C) aldosterone
D) vasopressin
Question
Patients with the nephrotic syndrome may benefit from calcium supplementation of ____ mg daily.

A) 500 to 1000
B) 1000 to 1500
C) 1500 to 2000
D) 2000 to 2500
Question
To regulate blood pressure, the kidneys secrete ____.

A) aldosterone
B) erythropoietin
C) renin
D) vasopressin
Question
A high-protein diet for a client with the nephrotic syndrome is contraindicated because ____.

A) protein foods are usually high in fat
B) energy requirements are decreased with nephrotic syndrome
C) high protein intakes may exacerbate urinary protein losses and further damage the kidney
D) protein levels in nephrotic syndrome are not altered
Question
The cuplike component of the nephron that surrounds the glomerulus and collects the filtrate is called "____."

A) Bowman's capsule
B) the ureter
C) the collecting duct
D) the tubule
Question
Daniel is a 10-year-old boy who has just been diagnosed with the nephrotic syndrome. Which condition might he develop as a result?

A) beriberi
B) pellagra
C) anemia
D) rickets
Question
In the nephrotic syndrome, the kidney's ability to excrete ____ is impaired, contributing to edema.

A) potassium
B) sodium
C) renin
D) calcium
Question
Billy Lewis is a 20-year-old man admitted to the hospital with the nephrotic syndrome. He is 5 ft 11 in., weighs 192 lb, and has edema. His blood values include albumin 1.7 g/dL, K + 3.3 mEq/L, and LDL cholesterol 192 mg/dL. He says he is hungry and wants a snack. The most appropriate food choice is ____.

A) a sausage biscuit
B) a grilled chicken sandwich with lettuce and tomato
C) peanut butter and crackers
D) cottage cheese and canned fruit
Question
The nephrotic syndrome is associated with accelerated atherosclerosis and a sharply increased risk of heart disease and ____.

A) liver disease
B) stomach cancer
C) stroke
D) hypertension
Question
A patient whose height is 5 ft 9 in. and weight 185 lb is admitted to the hospital with acute kidney injury and is started on hemodialysis. What would be the recommended protein intake (in grams) for this patient?

A) 40 to 65
B) 60 to 82
C) 84 to 143
D) 150 to 165
Question
A glomerular filtration rate (GFR) of ____ mL/min is characteristic of kidney failure.

A)
B) 15 to 29
C) 30 to 59
D) 60 to 89
Question
A type of skin change that develops due to uremia from chronic kidney disease is ____.

A) maceration
B) pruritus
C) hives
D) diaphoresis
Question
Diabetes mellitus causes about ____ of chronic kidney disease cases in the United States.

A) 35%
B) 45%
C) 55%
D) 65%
Question
Hyperkalemia occurs when there is excessive ____ in the blood.

A) calcium
B) potassium
C) phosphorus
D) vitamin D
Question
What is a prerenal cause of acute kidney injury?

A) heart failure
B) sickle cell disease
C) diabetes mellitus
D) pregnancy
Question
Which condition often develops as a result of increased secretion of parathyroid hormone in patients with chronic kidney disease?

A) fatty liver disease
B) gastroesophageal reflux
C) dumping syndrome
D) bone loss
Question
The glucose absorbed from the dialysate used in peritoneal dialysis can provide as many as ____ kcalories daily.

A) 200
B) 400
C) 600
D) 1000
Question
In the nephrotic syndrome, the liver attempts to compensate for the loss in protein by ____.

A) decreasing its synthesis of various plasma proteins
B) decreasing glomerular permeability
C) increasing albumin levels
D) increasing its synthesis of various plasma proteins
Question
What is the percentage of sodium that comes from processed foods, unprocessed natural foods, and table salt respectively?

A) 50, 40, 10
B) 75, 10, 15
C) 90, 5, 5
D) 90, 0, 10
Question
In patients with reduced urine production, recovery from acute kidney injury begins with a period of ____, in which large amounts of fluid are excreted.

A) catabolism
B) uremia
C) diuresis
D) oliguria
Question
Edema that develops with acute kidney injury is most often treated with which type of medication?

A) potassium-exchange resins
B) phosphate binders
C) diuretics
D) insulin
Question
Normal urine volume is approximately ____ mL per day.

A) 500 to 1000
B) 1000 to 1500
C) 1500 to 2000
D) 2000 to 2500
Question
The rate at which filtrate is formed within the kidney is normally about ____ mL/min in healthy adults.

A) 15
B) 60
C) 100
D) 125
Question
What is an intrarenal cause of acute kidney injury?

A) food poisoning due to Escherichia coli
B) pregnancy
C) blood clots
D) bladder rupture
Question
Acute kidney injury is characterized by reduced urine output coupled with a progressive rise in serum ___ levels.

A) ammonia
B) creatinine
C) amino acids
D) lipids
Question
What is considered to be the best index of overall kidney function?

A) glomerular filtration rate
B) albumin levels
C) anemia
D) renal osteodystrophy
Question
What is a postrenal cause of acute kidney injury?

A) infection
B) nephrotoxic drugs
C) pregnancy
D) heart attack
Question
The removal of excess fluids and wastes from the blood using the peritoneum as a semipermeable membrane is called "____."

A) chronic dialysis
B) hemodialysis
C) peritoneal dialysis
D) acute dialysis
Question
Why might patients with the nephrotic syndrome be advised to eat foods that are high in potassium?

A) Treatment with certain diuretics results in potassium loss.
B) Protein loss is typically accompanied by potassium loss.
C) They are unable to properly absorb potassium.
D) To reduce bone loss associated with low serum potassium.
Question
Which item is a high-potassium food?

A) honeydew melon
B) watermelon
C) avocado
D) blueberries
Question
Which item contributes to high uric acid levels?

A) oxalate
B) purines
C) cystine
D) magnesium
Question
The movement of solutes from an area of high concentration to one of low concentration is known as ____.

A) osmosis
B) diffusion
C) permeability
D) oncotic pressure
Question
Which interaction is associated with the use of immunosuppressants?

A) Alcohol intake has the potential for toxic effects.
B) Bioavailability of medication is increased when the drug is taken with food.
C) Grapefruit juice can dangerously decrease serum concentrations of the medication.
D) Calcium and magnesium supplements must be taken separately.
Question
Intradialytic parenteral nutrition ____.

A) combines parenteral nutrition with hemodialysis
B) substitutes parenteral nutrition for hemodialysis
C) substitutes hemodialysis for parenteral nutrition
D) delays the need for hemodialysis by manipulating nutrition
Question
The most common method used to evaluate the adequacy of dialysis treatment is ____.

A) blood urea nitrogen
B) urea kinetic modeling
C) weighing a patient predialysis and postdialysis
D) self-report of fluid intake and output
Question
Which food is high in phosphorus?

A) gelatin
B) apple
C) chocolate
D) fish
Question
Approximately ____ of patients with end-stage renal disease receive a kidney transplant.

A) 15%
B) 20%
C) 40%
D) 55%
Question
Struvite stones are composed mainly of ____.

A) magnesium ammonium phosphate
B) bile acid salts
C) urinary citrate
D) purines
Question
Prior to his kidney transplant, John Miller was on dialysis and his sodium intake was restricted to 2000 mg daily. His blood pressure levels have averaged 140/90 mmHg. When Mr. Miller inquires if he should continue to restrict his sodium after his transplant, you reply, ____.

A) "Since your renal function has been restored, you will never need to restrict your sodium intake."
B) "Since your blood pressure is still elevated, you need to restrict your sodium level to 2.0 to 2.4 g/day."
C) "Since you are going to be on diuretics, there is no need to restrict sodium."
D) "Once you are on the immunosuppressants, you will no longer need to restrict sodium intake."
Question
One of the most common complications associated with hemodialysis is ____.

A) hypertension
B)   blood clots
C)   hyperglycemia
D)   joint inflammation
Question
Morgan Simmons, a 74-year-old woman, is on hemodialysis. She wants to continue consuming 3 cups of non-fat milk per day. What is the most appropriate response?

A) "Continue consuming three cups a day; you need calcium and vitamin D."
B) "Increase your milk intake to four cups per day."
C) "Milk contains phosphorus and too much can be harmful for your medical condition."
D) "Do not drink milk at all. Take the vitamin D and calcium supplements instead."
Question
Which factor would most likely predispose a person to development of kidney stones?

A) urinary obstruction
B) increased urine volume
C) decreased protein intake
D) administration of immunosuppressant medications
Question
Supplements of folic acid prescribed for dialysis patients typically supply ____ mg daily.

A) 1
B) 5
C) 10
D) 20
Question
What is the most common complication of peritoneal dialysis?

A) hypoglycemia
B) infection
C) hypotension
D) hernia
Question
The best preventive treatment for all types of kidney stones is to ____.

A) drink plenty of fluids
B) consume a diet high in berries and juices
C) limit plant proteins
D) increase vitamin C intake
Question
What is an advantage of using continuous renal replacement therapy (CRRT)?

A) It does not damage arteries
B)   It does not cause sudden shifts in blood volume
C) It does not lead to blood clots.
D)   It prevents patients from developing hypotension.
Question
Intakes of supplemental vitamin C are restricted to 100 mg/day in patients with chronic renal failure to prevent ____.

A) kidney stones
B) scurvy
C) colds
D) hemochromatosis
Question
Which treatment is used to dialyze patients with acute kidney injury?

A) peritoneal dialysis
B) hemodialysis
C) continuous renal replacement therapy
D) intermittent dialysis
Question
What best describes renal colic?

A) urination urgency as a result of kidney stone obstruction
B) intense pain as a kidney stone passes through the ureter
C) a kidney infection that develops due to struvite kidney stones
D) crystallized urine that has backed up into the kidneys
Question
Charlie Which meal is most appropriate for Charlie?

A) low-fat milk, fried chicken strips, ketchup, French fries, and sliced apples
B) apple juice, shrimp fried rice, duck sauce, and spring roll
C) grape juice, canned chicken noodle soup, cheeseburger with ketchup, and fruit cup
D) low-fat milk, grilled chicken, rice pilaf, and sliced pears
Question
Jasmine Singh Due to her history of hypercalciuria, Jasmine most likely has ____ stones.

A) struvite
B) cystine
C) uric acid
D) calcium oxalate
Question
Match between columns
Premises:
Responses:
excessive amounts of calcium in the urine
Hyperkalemia
excessive amounts of calcium in the urine
Hyperoxaluria
excessive amounts of calcium in the urine
Gout
excessive amounts of calcium in the urine
Hypercalciuria
excessive amounts of calcium in the urine
Cystinuria
excessive amounts of calcium in the urine
Renal osteodystrophy
excessive amounts of calcium in the urine
Struvite
excessive amounts of calcium in the urine
continuous renal replacement therapy
excessive amounts of calcium in the urine
Hematuria
excessive amounts of calcium in the urine
Uremic syndrome
excessive amounts of calcium in the urine
Renal colic
excessive amounts of calcium in the urine
Hypercalcemia
excessive amounts of calcium in the urine
Purines
excessive amounts of calcium in the urine
Hemodialysis
excessive amounts of calcium in the urine
peritoneal dialysis
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hyperkalemia
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hyperoxaluria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Gout
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hypercalciuria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Cystinuria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Renal osteodystrophy
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Struvite
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
continuous renal replacement therapy
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hematuria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Uremic syndrome
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Renal colic
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hypercalcemia
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Purines
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hemodialysis
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
peritoneal dialysis
removal of fluids and wastes by using the peritoneal membrane as a filter
Hyperkalemia
removal of fluids and wastes by using the peritoneal membrane as a filter
Hyperoxaluria
removal of fluids and wastes by using the peritoneal membrane as a filter
Gout
removal of fluids and wastes by using the peritoneal membrane as a filter
Hypercalciuria
removal of fluids and wastes by using the peritoneal membrane as a filter
Cystinuria
removal of fluids and wastes by using the peritoneal membrane as a filter
Renal osteodystrophy
removal of fluids and wastes by using the peritoneal membrane as a filter
Struvite
removal of fluids and wastes by using the peritoneal membrane as a filter
continuous renal replacement therapy
removal of fluids and wastes by using the peritoneal membrane as a filter
Hematuria
removal of fluids and wastes by using the peritoneal membrane as a filter
Uremic syndrome
removal of fluids and wastes by using the peritoneal membrane as a filter
Renal colic
removal of fluids and wastes by using the peritoneal membrane as a filter
Hypercalcemia
removal of fluids and wastes by using the peritoneal membrane as a filter
Purines
removal of fluids and wastes by using the peritoneal membrane as a filter
Hemodialysis
removal of fluids and wastes by using the peritoneal membrane as a filter
peritoneal dialysis
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hyperkalemia
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hyperoxaluria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Gout
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hypercalciuria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Cystinuria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Renal osteodystrophy
removal of fluids and wastes from blood by passing the blood through a dialyzer
Struvite
removal of fluids and wastes from blood by passing the blood through a dialyzer
continuous renal replacement therapy
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hematuria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Uremic syndrome
removal of fluids and wastes from blood by passing the blood through a dialyzer
Renal colic
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hypercalcemia
removal of fluids and wastes from blood by passing the blood through a dialyzer
Purines
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hemodialysis
removal of fluids and wastes from blood by passing the blood through a dialyzer
peritoneal dialysis
blood in the urine
Hyperkalemia
blood in the urine
Hyperoxaluria
blood in the urine
Gout
blood in the urine
Hypercalciuria
blood in the urine
Cystinuria
blood in the urine
Renal osteodystrophy
blood in the urine
Struvite
blood in the urine
continuous renal replacement therapy
blood in the urine
Hematuria
blood in the urine
Uremic syndrome
blood in the urine
Renal colic
blood in the urine
Hypercalcemia
blood in the urine
Purines
blood in the urine
Hemodialysis
blood in the urine
peritoneal dialysis
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hyperkalemia
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hyperoxaluria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Gout
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hypercalciuria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Cystinuria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Renal osteodystrophy
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Struvite
severe, stabbing pain that occurs when a kidney stone passes through the ureter
continuous renal replacement therapy
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hematuria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Uremic syndrome
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Renal colic
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hypercalcemia
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Purines
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hemodialysis
severe, stabbing pain that occurs when a kidney stone passes through the ureter
peritoneal dialysis
crystals of magnesium ammonium phosphate
Hyperkalemia
crystals of magnesium ammonium phosphate
Hyperoxaluria
crystals of magnesium ammonium phosphate
Gout
crystals of magnesium ammonium phosphate
Hypercalciuria
crystals of magnesium ammonium phosphate
Cystinuria
crystals of magnesium ammonium phosphate
Renal osteodystrophy
crystals of magnesium ammonium phosphate
Struvite
crystals of magnesium ammonium phosphate
continuous renal replacement therapy
crystals of magnesium ammonium phosphate
Hematuria
crystals of magnesium ammonium phosphate
Uremic syndrome
crystals of magnesium ammonium phosphate
Renal colic
crystals of magnesium ammonium phosphate
Hypercalcemia
crystals of magnesium ammonium phosphate
Purines
crystals of magnesium ammonium phosphate
Hemodialysis
crystals of magnesium ammonium phosphate
peritoneal dialysis
excessive amounts of oxalate in the urine
Hyperkalemia
excessive amounts of oxalate in the urine
Hyperoxaluria
excessive amounts of oxalate in the urine
Gout
excessive amounts of oxalate in the urine
Hypercalciuria
excessive amounts of oxalate in the urine
Cystinuria
excessive amounts of oxalate in the urine
Renal osteodystrophy
excessive amounts of oxalate in the urine
Struvite
excessive amounts of oxalate in the urine
continuous renal replacement therapy
excessive amounts of oxalate in the urine
Hematuria
excessive amounts of oxalate in the urine
Uremic syndrome
excessive amounts of oxalate in the urine
Renal colic
excessive amounts of oxalate in the urine
Hypercalcemia
excessive amounts of oxalate in the urine
Purines
excessive amounts of oxalate in the urine
Hemodialysis
excessive amounts of oxalate in the urine
peritoneal dialysis
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hyperkalemia
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hyperoxaluria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Gout
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hypercalciuria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Cystinuria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Renal osteodystrophy
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Struvite
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
continuous renal replacement therapy
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hematuria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Uremic syndrome
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Renal colic
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hypercalcemia
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Purines
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hemodialysis
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
peritoneal dialysis
end products of nucleotide metabolism that eventually degrade to uric acid
Hyperkalemia
end products of nucleotide metabolism that eventually degrade to uric acid
Hyperoxaluria
end products of nucleotide metabolism that eventually degrade to uric acid
Gout
end products of nucleotide metabolism that eventually degrade to uric acid
Hypercalciuria
end products of nucleotide metabolism that eventually degrade to uric acid
Cystinuria
end products of nucleotide metabolism that eventually degrade to uric acid
Renal osteodystrophy
end products of nucleotide metabolism that eventually degrade to uric acid
Struvite
end products of nucleotide metabolism that eventually degrade to uric acid
continuous renal replacement therapy
end products of nucleotide metabolism that eventually degrade to uric acid
Hematuria
end products of nucleotide metabolism that eventually degrade to uric acid
Uremic syndrome
end products of nucleotide metabolism that eventually degrade to uric acid
Renal colic
end products of nucleotide metabolism that eventually degrade to uric acid
Hypercalcemia
end products of nucleotide metabolism that eventually degrade to uric acid
Purines
end products of nucleotide metabolism that eventually degrade to uric acid
Hemodialysis
end products of nucleotide metabolism that eventually degrade to uric acid
peritoneal dialysis
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hyperkalemia
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hyperoxaluria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Gout
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hypercalciuria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Cystinuria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Renal osteodystrophy
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Struvite
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
continuous renal replacement therapy
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hematuria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Uremic syndrome
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Renal colic
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hypercalcemia
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Purines
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hemodialysis
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
peritoneal dialysis
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hyperkalemia
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hyperoxaluria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Gout
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hypercalciuria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Cystinuria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Renal osteodystrophy
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Struvite
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
continuous renal replacement therapy
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hematuria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Uremic syndrome
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Renal colic
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hypercalcemia
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Purines
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hemodialysis
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
peritoneal dialysis
elevated serum potassium levels
Hyperkalemia
elevated serum potassium levels
Hyperoxaluria
elevated serum potassium levels
Gout
elevated serum potassium levels
Hypercalciuria
elevated serum potassium levels
Cystinuria
elevated serum potassium levels
Renal osteodystrophy
elevated serum potassium levels
Struvite
elevated serum potassium levels
continuous renal replacement therapy
elevated serum potassium levels
Hematuria
elevated serum potassium levels
Uremic syndrome
elevated serum potassium levels
Renal colic
elevated serum potassium levels
Hypercalcemia
elevated serum potassium levels
Purines
elevated serum potassium levels
Hemodialysis
elevated serum potassium levels
peritoneal dialysis
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hyperkalemia
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hyperoxaluria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Gout
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hypercalciuria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Cystinuria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Renal osteodystrophy
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Struvite
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
continuous renal replacement therapy
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hematuria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Uremic syndrome
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Renal colic
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hypercalcemia
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Purines
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hemodialysis
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
peritoneal dialysis
elevated serum calcium levels
Hyperkalemia
elevated serum calcium levels
Hyperoxaluria
elevated serum calcium levels
Gout
elevated serum calcium levels
Hypercalciuria
elevated serum calcium levels
Cystinuria
elevated serum calcium levels
Renal osteodystrophy
elevated serum calcium levels
Struvite
elevated serum calcium levels
continuous renal replacement therapy
elevated serum calcium levels
Hematuria
elevated serum calcium levels
Uremic syndrome
elevated serum calcium levels
Renal colic
elevated serum calcium levels
Hypercalcemia
elevated serum calcium levels
Purines
elevated serum calcium levels
Hemodialysis
elevated serum calcium levels
peritoneal dialysis
Question
Jasmine Singh is 25 years old. She has had hypercalciuria due to elevated serum levels of parathyroid hormone over the past year. She makes an appointment with her physician after an episode of nausea, vomiting, severe pain in the groin, and pain while urinating. At her doctor's office, Jasmine provides a urine sample. Testing confirms blood in her urine. This indicates ____.

A) renal colic
B) hematuria
C) acute kidney injury
D) ketones
Question
A client is diagnosed with calcium oxalate kidney stones. What is the appropriate diet therapy for her treatment?
Question
Charlie Charlie is prescribed calcium and vitamin D supplements to prevent ____.

A) fluid retention
B) rickets
C) osteopenia
D) renal failure
Question
Explain the nephrotic syndrome and the diet modifications used to treat it.
Question
Describe the events leading to the development of bone disease in patients with chronic kidney disease.
Question
Discuss three of the roles of the kidneys in maintaining our health.
Question
Charlie Which diet is the most appropriate for Charlie?

A) high-kcalorie, high-protein
B) high-carbohydrate, high-fat
C) low-fat, low-carbohydrate
D) adequate-protein, low-sodium, low-fat
Question
Jasmine Singh Which dietary factors are most important to prevent kidney stones in Jasmine's case?

A) adequate calcium, moderate protein, controlled sodium
B) high protein/high kcalorie with fluid restriction
C) low purine with plenty of fluids
D) low protein with fluid restriction
Question
Explain how chronic kidney disease can lead to cardiovascular complications.
Question
Jasmine Singh Jasmine has been diagnosed with a kidney stone. The blood in Jasmine's urine is most likely a result of ____.

A) damage from the stone passing through the ureter
B) irritation of the lining of the rectum
C) infection from the stone obstructing the convoluted tubules
D) ketones in the urine from elevated glucose
Question
Charlie is a 2½-year-old boy with a history of asthma and allergies. He is on several maintenance medications. His parents rush him to the emergency department because of increased lethargy, high fever, edema, and foamy urine. His laboratory results reveal proteinuria, hypoalbuminemia, and hyperlipidemia. What is Charlie suffering from?

A) cystic fibrosis
B) type 1 diabetes
C) nephrotic syndrome
D) uremic syndrome
Question
Jasmine Singh During flu season Jasmine wants to take high-dose vitamin C supplements as prophylaxis. What is the most appropriate response?

A) Take 2000-mg vitamin C supplements twice daily
B) Take a combination of vitamin C supplements and food sources of vitamin C
C) Avoid vitamin C supplements, since they degrade to oxalate, which increases the risk for stones
D) Take high-dose vitamin D supplements along with vitamin C
Question
Charlie Which part of Charlie's body is malfunctioning and causing this condition?

A) beta cells
B) neurons
C) lymphatic system
D) glomerulus
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Deck 28: Kidney Diseases
1
Nutrition therapy for the nephrotic syndrome focuses on ____.

A) increasing the fat content in the diet
B) preventing protein-energy malnutrition and alleviating edema
C) high protein and kcalorie intake
D) high sodium intake
B
2
A consequence of the nephrotic syndrome is the loss of plasma proteins in the urine, which contributes to ____.

A) an increased risk of blood clotting
B) a fluid shift from interstitial spaces to blood plasma
C) an increased risk of vitamin D toxicity
D) Anabolic buildup of muscle mass
A
3
What is the most abundant plasma protein?

A) albumin
B) immunoglobulins
C) vitamin D-binding protein
D) transferrin
A
4
Diets high in vitamin D and calcium are recommended for children with nephrotic syndrome to prevent ____.

A) beriberi
B) marasmus
C) nephrosclerosis
D) rickets
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5
What best describes the function of the ureter?

A) storing urine before it is excreted
B) Conducting urine from the kidneys to the bladder
C) transporting urine from the bladder to out side of the body
D) carrying blood from the kidneys back to the heart
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6
For patients with nephrotic syndrome, the recommended daily protein intake is ____ g/kg of body weight.

A) 0.4 to 0.6
B) 0.6 to 0.8
C) 0.8 to 1.0
D) 1.0 to 1.2
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7
In the nephrotic syndrome, urinary protein losses generally average about ____ grams daily.

A) 3 to 3.5
B) 5.5 to 6
C) 9 to 10.5
D) 11 to 12
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8
Proteinuria due to nephrotic syndrome results in a loss of immunoglobulins, which increases the risk for ____.

A) edema
B) infection
C) wasting
D) hypertriglyceridemia
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9
In patients with the nephrotic syndrome, energy intake of about ____ kcal/kg of body weight daily will sustain weight and spare protein.

A) 15
B) 25
C) 35
D) 45
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10
Daily sodium intake should be restricted to about ____ grams for patients with the nephrotic syndrome.

A) 0.5 to 1.0
B) 1.0 to 2.0
C) 2.0 to 3.0
D) 3.0 to 4.0
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11
One large egg contains about ____ mg of sodium.

A) 10
B) 40
C) 60
D) 200
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12
What hormone secreted by the kidneys stimulates the production of red blood cells?

A) erythropoietin
B) renin
C) aldosterone
D) vasopressin
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13
Patients with the nephrotic syndrome may benefit from calcium supplementation of ____ mg daily.

A) 500 to 1000
B) 1000 to 1500
C) 1500 to 2000
D) 2000 to 2500
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14
To regulate blood pressure, the kidneys secrete ____.

A) aldosterone
B) erythropoietin
C) renin
D) vasopressin
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15
A high-protein diet for a client with the nephrotic syndrome is contraindicated because ____.

A) protein foods are usually high in fat
B) energy requirements are decreased with nephrotic syndrome
C) high protein intakes may exacerbate urinary protein losses and further damage the kidney
D) protein levels in nephrotic syndrome are not altered
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16
The cuplike component of the nephron that surrounds the glomerulus and collects the filtrate is called "____."

A) Bowman's capsule
B) the ureter
C) the collecting duct
D) the tubule
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17
Daniel is a 10-year-old boy who has just been diagnosed with the nephrotic syndrome. Which condition might he develop as a result?

A) beriberi
B) pellagra
C) anemia
D) rickets
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18
In the nephrotic syndrome, the kidney's ability to excrete ____ is impaired, contributing to edema.

A) potassium
B) sodium
C) renin
D) calcium
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19
Billy Lewis is a 20-year-old man admitted to the hospital with the nephrotic syndrome. He is 5 ft 11 in., weighs 192 lb, and has edema. His blood values include albumin 1.7 g/dL, K + 3.3 mEq/L, and LDL cholesterol 192 mg/dL. He says he is hungry and wants a snack. The most appropriate food choice is ____.

A) a sausage biscuit
B) a grilled chicken sandwich with lettuce and tomato
C) peanut butter and crackers
D) cottage cheese and canned fruit
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20
The nephrotic syndrome is associated with accelerated atherosclerosis and a sharply increased risk of heart disease and ____.

A) liver disease
B) stomach cancer
C) stroke
D) hypertension
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21
A patient whose height is 5 ft 9 in. and weight 185 lb is admitted to the hospital with acute kidney injury and is started on hemodialysis. What would be the recommended protein intake (in grams) for this patient?

A) 40 to 65
B) 60 to 82
C) 84 to 143
D) 150 to 165
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22
A glomerular filtration rate (GFR) of ____ mL/min is characteristic of kidney failure.

A)
B) 15 to 29
C) 30 to 59
D) 60 to 89
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23
A type of skin change that develops due to uremia from chronic kidney disease is ____.

A) maceration
B) pruritus
C) hives
D) diaphoresis
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24
Diabetes mellitus causes about ____ of chronic kidney disease cases in the United States.

A) 35%
B) 45%
C) 55%
D) 65%
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25
Hyperkalemia occurs when there is excessive ____ in the blood.

A) calcium
B) potassium
C) phosphorus
D) vitamin D
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26
What is a prerenal cause of acute kidney injury?

A) heart failure
B) sickle cell disease
C) diabetes mellitus
D) pregnancy
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27
Which condition often develops as a result of increased secretion of parathyroid hormone in patients with chronic kidney disease?

A) fatty liver disease
B) gastroesophageal reflux
C) dumping syndrome
D) bone loss
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28
The glucose absorbed from the dialysate used in peritoneal dialysis can provide as many as ____ kcalories daily.

A) 200
B) 400
C) 600
D) 1000
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29
In the nephrotic syndrome, the liver attempts to compensate for the loss in protein by ____.

A) decreasing its synthesis of various plasma proteins
B) decreasing glomerular permeability
C) increasing albumin levels
D) increasing its synthesis of various plasma proteins
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30
What is the percentage of sodium that comes from processed foods, unprocessed natural foods, and table salt respectively?

A) 50, 40, 10
B) 75, 10, 15
C) 90, 5, 5
D) 90, 0, 10
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31
In patients with reduced urine production, recovery from acute kidney injury begins with a period of ____, in which large amounts of fluid are excreted.

A) catabolism
B) uremia
C) diuresis
D) oliguria
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32
Edema that develops with acute kidney injury is most often treated with which type of medication?

A) potassium-exchange resins
B) phosphate binders
C) diuretics
D) insulin
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33
Normal urine volume is approximately ____ mL per day.

A) 500 to 1000
B) 1000 to 1500
C) 1500 to 2000
D) 2000 to 2500
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34
The rate at which filtrate is formed within the kidney is normally about ____ mL/min in healthy adults.

A) 15
B) 60
C) 100
D) 125
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35
What is an intrarenal cause of acute kidney injury?

A) food poisoning due to Escherichia coli
B) pregnancy
C) blood clots
D) bladder rupture
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36
Acute kidney injury is characterized by reduced urine output coupled with a progressive rise in serum ___ levels.

A) ammonia
B) creatinine
C) amino acids
D) lipids
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37
What is considered to be the best index of overall kidney function?

A) glomerular filtration rate
B) albumin levels
C) anemia
D) renal osteodystrophy
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38
What is a postrenal cause of acute kidney injury?

A) infection
B) nephrotoxic drugs
C) pregnancy
D) heart attack
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39
The removal of excess fluids and wastes from the blood using the peritoneum as a semipermeable membrane is called "____."

A) chronic dialysis
B) hemodialysis
C) peritoneal dialysis
D) acute dialysis
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40
Why might patients with the nephrotic syndrome be advised to eat foods that are high in potassium?

A) Treatment with certain diuretics results in potassium loss.
B) Protein loss is typically accompanied by potassium loss.
C) They are unable to properly absorb potassium.
D) To reduce bone loss associated with low serum potassium.
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41
Which item is a high-potassium food?

A) honeydew melon
B) watermelon
C) avocado
D) blueberries
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42
Which item contributes to high uric acid levels?

A) oxalate
B) purines
C) cystine
D) magnesium
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43
The movement of solutes from an area of high concentration to one of low concentration is known as ____.

A) osmosis
B) diffusion
C) permeability
D) oncotic pressure
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44
Which interaction is associated with the use of immunosuppressants?

A) Alcohol intake has the potential for toxic effects.
B) Bioavailability of medication is increased when the drug is taken with food.
C) Grapefruit juice can dangerously decrease serum concentrations of the medication.
D) Calcium and magnesium supplements must be taken separately.
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45
Intradialytic parenteral nutrition ____.

A) combines parenteral nutrition with hemodialysis
B) substitutes parenteral nutrition for hemodialysis
C) substitutes hemodialysis for parenteral nutrition
D) delays the need for hemodialysis by manipulating nutrition
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46
The most common method used to evaluate the adequacy of dialysis treatment is ____.

A) blood urea nitrogen
B) urea kinetic modeling
C) weighing a patient predialysis and postdialysis
D) self-report of fluid intake and output
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47
Which food is high in phosphorus?

A) gelatin
B) apple
C) chocolate
D) fish
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48
Approximately ____ of patients with end-stage renal disease receive a kidney transplant.

A) 15%
B) 20%
C) 40%
D) 55%
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49
Struvite stones are composed mainly of ____.

A) magnesium ammonium phosphate
B) bile acid salts
C) urinary citrate
D) purines
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50
Prior to his kidney transplant, John Miller was on dialysis and his sodium intake was restricted to 2000 mg daily. His blood pressure levels have averaged 140/90 mmHg. When Mr. Miller inquires if he should continue to restrict his sodium after his transplant, you reply, ____.

A) "Since your renal function has been restored, you will never need to restrict your sodium intake."
B) "Since your blood pressure is still elevated, you need to restrict your sodium level to 2.0 to 2.4 g/day."
C) "Since you are going to be on diuretics, there is no need to restrict sodium."
D) "Once you are on the immunosuppressants, you will no longer need to restrict sodium intake."
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51
One of the most common complications associated with hemodialysis is ____.

A) hypertension
B)   blood clots
C)   hyperglycemia
D)   joint inflammation
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52
Morgan Simmons, a 74-year-old woman, is on hemodialysis. She wants to continue consuming 3 cups of non-fat milk per day. What is the most appropriate response?

A) "Continue consuming three cups a day; you need calcium and vitamin D."
B) "Increase your milk intake to four cups per day."
C) "Milk contains phosphorus and too much can be harmful for your medical condition."
D) "Do not drink milk at all. Take the vitamin D and calcium supplements instead."
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53
Which factor would most likely predispose a person to development of kidney stones?

A) urinary obstruction
B) increased urine volume
C) decreased protein intake
D) administration of immunosuppressant medications
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54
Supplements of folic acid prescribed for dialysis patients typically supply ____ mg daily.

A) 1
B) 5
C) 10
D) 20
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55
What is the most common complication of peritoneal dialysis?

A) hypoglycemia
B) infection
C) hypotension
D) hernia
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56
The best preventive treatment for all types of kidney stones is to ____.

A) drink plenty of fluids
B) consume a diet high in berries and juices
C) limit plant proteins
D) increase vitamin C intake
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57
What is an advantage of using continuous renal replacement therapy (CRRT)?

A) It does not damage arteries
B)   It does not cause sudden shifts in blood volume
C) It does not lead to blood clots.
D)   It prevents patients from developing hypotension.
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58
Intakes of supplemental vitamin C are restricted to 100 mg/day in patients with chronic renal failure to prevent ____.

A) kidney stones
B) scurvy
C) colds
D) hemochromatosis
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59
Which treatment is used to dialyze patients with acute kidney injury?

A) peritoneal dialysis
B) hemodialysis
C) continuous renal replacement therapy
D) intermittent dialysis
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60
What best describes renal colic?

A) urination urgency as a result of kidney stone obstruction
B) intense pain as a kidney stone passes through the ureter
C) a kidney infection that develops due to struvite kidney stones
D) crystallized urine that has backed up into the kidneys
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61
Charlie Which meal is most appropriate for Charlie?

A) low-fat milk, fried chicken strips, ketchup, French fries, and sliced apples
B) apple juice, shrimp fried rice, duck sauce, and spring roll
C) grape juice, canned chicken noodle soup, cheeseburger with ketchup, and fruit cup
D) low-fat milk, grilled chicken, rice pilaf, and sliced pears
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62
Jasmine Singh Due to her history of hypercalciuria, Jasmine most likely has ____ stones.

A) struvite
B) cystine
C) uric acid
D) calcium oxalate
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63
Match between columns
Premises:
Responses:
excessive amounts of calcium in the urine
Hyperkalemia
excessive amounts of calcium in the urine
Hyperoxaluria
excessive amounts of calcium in the urine
Gout
excessive amounts of calcium in the urine
Hypercalciuria
excessive amounts of calcium in the urine
Cystinuria
excessive amounts of calcium in the urine
Renal osteodystrophy
excessive amounts of calcium in the urine
Struvite
excessive amounts of calcium in the urine
continuous renal replacement therapy
excessive amounts of calcium in the urine
Hematuria
excessive amounts of calcium in the urine
Uremic syndrome
excessive amounts of calcium in the urine
Renal colic
excessive amounts of calcium in the urine
Hypercalcemia
excessive amounts of calcium in the urine
Purines
excessive amounts of calcium in the urine
Hemodialysis
excessive amounts of calcium in the urine
peritoneal dialysis
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hyperkalemia
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hyperoxaluria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Gout
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hypercalciuria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Cystinuria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Renal osteodystrophy
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Struvite
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
continuous renal replacement therapy
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hematuria
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Uremic syndrome
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Renal colic
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hypercalcemia
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Purines
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
Hemodialysis
metabolic disorder that results in excessive uric acid in the blood and urine, and uric acid deposits in and around the joints causing acute joint inflammation
peritoneal dialysis
removal of fluids and wastes by using the peritoneal membrane as a filter
Hyperkalemia
removal of fluids and wastes by using the peritoneal membrane as a filter
Hyperoxaluria
removal of fluids and wastes by using the peritoneal membrane as a filter
Gout
removal of fluids and wastes by using the peritoneal membrane as a filter
Hypercalciuria
removal of fluids and wastes by using the peritoneal membrane as a filter
Cystinuria
removal of fluids and wastes by using the peritoneal membrane as a filter
Renal osteodystrophy
removal of fluids and wastes by using the peritoneal membrane as a filter
Struvite
removal of fluids and wastes by using the peritoneal membrane as a filter
continuous renal replacement therapy
removal of fluids and wastes by using the peritoneal membrane as a filter
Hematuria
removal of fluids and wastes by using the peritoneal membrane as a filter
Uremic syndrome
removal of fluids and wastes by using the peritoneal membrane as a filter
Renal colic
removal of fluids and wastes by using the peritoneal membrane as a filter
Hypercalcemia
removal of fluids and wastes by using the peritoneal membrane as a filter
Purines
removal of fluids and wastes by using the peritoneal membrane as a filter
Hemodialysis
removal of fluids and wastes by using the peritoneal membrane as a filter
peritoneal dialysis
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hyperkalemia
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hyperoxaluria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Gout
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hypercalciuria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Cystinuria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Renal osteodystrophy
removal of fluids and wastes from blood by passing the blood through a dialyzer
Struvite
removal of fluids and wastes from blood by passing the blood through a dialyzer
continuous renal replacement therapy
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hematuria
removal of fluids and wastes from blood by passing the blood through a dialyzer
Uremic syndrome
removal of fluids and wastes from blood by passing the blood through a dialyzer
Renal colic
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hypercalcemia
removal of fluids and wastes from blood by passing the blood through a dialyzer
Purines
removal of fluids and wastes from blood by passing the blood through a dialyzer
Hemodialysis
removal of fluids and wastes from blood by passing the blood through a dialyzer
peritoneal dialysis
blood in the urine
Hyperkalemia
blood in the urine
Hyperoxaluria
blood in the urine
Gout
blood in the urine
Hypercalciuria
blood in the urine
Cystinuria
blood in the urine
Renal osteodystrophy
blood in the urine
Struvite
blood in the urine
continuous renal replacement therapy
blood in the urine
Hematuria
blood in the urine
Uremic syndrome
blood in the urine
Renal colic
blood in the urine
Hypercalcemia
blood in the urine
Purines
blood in the urine
Hemodialysis
blood in the urine
peritoneal dialysis
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hyperkalemia
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hyperoxaluria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Gout
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hypercalciuria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Cystinuria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Renal osteodystrophy
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Struvite
severe, stabbing pain that occurs when a kidney stone passes through the ureter
continuous renal replacement therapy
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hematuria
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Uremic syndrome
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Renal colic
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hypercalcemia
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Purines
severe, stabbing pain that occurs when a kidney stone passes through the ureter
Hemodialysis
severe, stabbing pain that occurs when a kidney stone passes through the ureter
peritoneal dialysis
crystals of magnesium ammonium phosphate
Hyperkalemia
crystals of magnesium ammonium phosphate
Hyperoxaluria
crystals of magnesium ammonium phosphate
Gout
crystals of magnesium ammonium phosphate
Hypercalciuria
crystals of magnesium ammonium phosphate
Cystinuria
crystals of magnesium ammonium phosphate
Renal osteodystrophy
crystals of magnesium ammonium phosphate
Struvite
crystals of magnesium ammonium phosphate
continuous renal replacement therapy
crystals of magnesium ammonium phosphate
Hematuria
crystals of magnesium ammonium phosphate
Uremic syndrome
crystals of magnesium ammonium phosphate
Renal colic
crystals of magnesium ammonium phosphate
Hypercalcemia
crystals of magnesium ammonium phosphate
Purines
crystals of magnesium ammonium phosphate
Hemodialysis
crystals of magnesium ammonium phosphate
peritoneal dialysis
excessive amounts of oxalate in the urine
Hyperkalemia
excessive amounts of oxalate in the urine
Hyperoxaluria
excessive amounts of oxalate in the urine
Gout
excessive amounts of oxalate in the urine
Hypercalciuria
excessive amounts of oxalate in the urine
Cystinuria
excessive amounts of oxalate in the urine
Renal osteodystrophy
excessive amounts of oxalate in the urine
Struvite
excessive amounts of oxalate in the urine
continuous renal replacement therapy
excessive amounts of oxalate in the urine
Hematuria
excessive amounts of oxalate in the urine
Uremic syndrome
excessive amounts of oxalate in the urine
Renal colic
excessive amounts of oxalate in the urine
Hypercalcemia
excessive amounts of oxalate in the urine
Purines
excessive amounts of oxalate in the urine
Hemodialysis
excessive amounts of oxalate in the urine
peritoneal dialysis
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hyperkalemia
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hyperoxaluria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Gout
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hypercalciuria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Cystinuria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Renal osteodystrophy
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Struvite
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
continuous renal replacement therapy
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hematuria
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Uremic syndrome
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Renal colic
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hypercalcemia
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Purines
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
Hemodialysis
cluster of symptoms associated with inadequate kidney function; complications include fluid, electrolyte and hormonal imbalances, altered heart function, neuromuscular disturbances, and reduced immunity
peritoneal dialysis
end products of nucleotide metabolism that eventually degrade to uric acid
Hyperkalemia
end products of nucleotide metabolism that eventually degrade to uric acid
Hyperoxaluria
end products of nucleotide metabolism that eventually degrade to uric acid
Gout
end products of nucleotide metabolism that eventually degrade to uric acid
Hypercalciuria
end products of nucleotide metabolism that eventually degrade to uric acid
Cystinuria
end products of nucleotide metabolism that eventually degrade to uric acid
Renal osteodystrophy
end products of nucleotide metabolism that eventually degrade to uric acid
Struvite
end products of nucleotide metabolism that eventually degrade to uric acid
continuous renal replacement therapy
end products of nucleotide metabolism that eventually degrade to uric acid
Hematuria
end products of nucleotide metabolism that eventually degrade to uric acid
Uremic syndrome
end products of nucleotide metabolism that eventually degrade to uric acid
Renal colic
end products of nucleotide metabolism that eventually degrade to uric acid
Hypercalcemia
end products of nucleotide metabolism that eventually degrade to uric acid
Purines
end products of nucleotide metabolism that eventually degrade to uric acid
Hemodialysis
end products of nucleotide metabolism that eventually degrade to uric acid
peritoneal dialysis
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hyperkalemia
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hyperoxaluria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Gout
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hypercalciuria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Cystinuria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Renal osteodystrophy
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Struvite
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
continuous renal replacement therapy
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hematuria
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Uremic syndrome
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Renal colic
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hypercalcemia
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Purines
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
Hemodialysis
bone disorder in patients with chronic renal failure as a result of increased parathyroid hormone secretion, reduced serum calcium, acidosis, and impaired vitamin D activation by the kidney
peritoneal dialysis
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hyperkalemia
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hyperoxaluria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Gout
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hypercalciuria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Cystinuria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Renal osteodystrophy
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Struvite
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
continuous renal replacement therapy
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hematuria
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Uremic syndrome
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Renal colic
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hypercalcemia
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Purines
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
Hemodialysis
genetic disorder characterized by elevated urinary excretion of several amino acids, including cysteine
peritoneal dialysis
elevated serum potassium levels
Hyperkalemia
elevated serum potassium levels
Hyperoxaluria
elevated serum potassium levels
Gout
elevated serum potassium levels
Hypercalciuria
elevated serum potassium levels
Cystinuria
elevated serum potassium levels
Renal osteodystrophy
elevated serum potassium levels
Struvite
elevated serum potassium levels
continuous renal replacement therapy
elevated serum potassium levels
Hematuria
elevated serum potassium levels
Uremic syndrome
elevated serum potassium levels
Renal colic
elevated serum potassium levels
Hypercalcemia
elevated serum potassium levels
Purines
elevated serum potassium levels
Hemodialysis
elevated serum potassium levels
peritoneal dialysis
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hyperkalemia
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hyperoxaluria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Gout
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hypercalciuria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Cystinuria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Renal osteodystrophy
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Struvite
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
continuous renal replacement therapy
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hematuria
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Uremic syndrome
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Renal colic
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hypercalcemia
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Purines
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
Hemodialysis
slow, continuous method of removing solutes and fluid from blood by gently pumping blood across a filtration membrane over a prolonged period of time
peritoneal dialysis
elevated serum calcium levels
Hyperkalemia
elevated serum calcium levels
Hyperoxaluria
elevated serum calcium levels
Gout
elevated serum calcium levels
Hypercalciuria
elevated serum calcium levels
Cystinuria
elevated serum calcium levels
Renal osteodystrophy
elevated serum calcium levels
Struvite
elevated serum calcium levels
continuous renal replacement therapy
elevated serum calcium levels
Hematuria
elevated serum calcium levels
Uremic syndrome
elevated serum calcium levels
Renal colic
elevated serum calcium levels
Hypercalcemia
elevated serum calcium levels
Purines
elevated serum calcium levels
Hemodialysis
elevated serum calcium levels
peritoneal dialysis
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64
Jasmine Singh is 25 years old. She has had hypercalciuria due to elevated serum levels of parathyroid hormone over the past year. She makes an appointment with her physician after an episode of nausea, vomiting, severe pain in the groin, and pain while urinating. At her doctor's office, Jasmine provides a urine sample. Testing confirms blood in her urine. This indicates ____.

A) renal colic
B) hematuria
C) acute kidney injury
D) ketones
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65
A client is diagnosed with calcium oxalate kidney stones. What is the appropriate diet therapy for her treatment?
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66
Charlie Charlie is prescribed calcium and vitamin D supplements to prevent ____.

A) fluid retention
B) rickets
C) osteopenia
D) renal failure
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67
Explain the nephrotic syndrome and the diet modifications used to treat it.
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68
Describe the events leading to the development of bone disease in patients with chronic kidney disease.
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69
Discuss three of the roles of the kidneys in maintaining our health.
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70
Charlie Which diet is the most appropriate for Charlie?

A) high-kcalorie, high-protein
B) high-carbohydrate, high-fat
C) low-fat, low-carbohydrate
D) adequate-protein, low-sodium, low-fat
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71
Jasmine Singh Which dietary factors are most important to prevent kidney stones in Jasmine's case?

A) adequate calcium, moderate protein, controlled sodium
B) high protein/high kcalorie with fluid restriction
C) low purine with plenty of fluids
D) low protein with fluid restriction
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72
Explain how chronic kidney disease can lead to cardiovascular complications.
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73
Jasmine Singh Jasmine has been diagnosed with a kidney stone. The blood in Jasmine's urine is most likely a result of ____.

A) damage from the stone passing through the ureter
B) irritation of the lining of the rectum
C) infection from the stone obstructing the convoluted tubules
D) ketones in the urine from elevated glucose
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74
Charlie is a 2½-year-old boy with a history of asthma and allergies. He is on several maintenance medications. His parents rush him to the emergency department because of increased lethargy, high fever, edema, and foamy urine. His laboratory results reveal proteinuria, hypoalbuminemia, and hyperlipidemia. What is Charlie suffering from?

A) cystic fibrosis
B) type 1 diabetes
C) nephrotic syndrome
D) uremic syndrome
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75
Jasmine Singh During flu season Jasmine wants to take high-dose vitamin C supplements as prophylaxis. What is the most appropriate response?

A) Take 2000-mg vitamin C supplements twice daily
B) Take a combination of vitamin C supplements and food sources of vitamin C
C) Avoid vitamin C supplements, since they degrade to oxalate, which increases the risk for stones
D) Take high-dose vitamin D supplements along with vitamin C
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76
Charlie Which part of Charlie's body is malfunctioning and causing this condition?

A) beta cells
B) neurons
C) lymphatic system
D) glomerulus
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