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 Nutrition
Education Curriculum Contents
Section Six: Nutrition and Renal Disease
The kidneys’ job is to keep the body’s fluids,
electrolytes, and organic solutes in a healthy balance. Their functional
units are the million or so nephrons in the renal cortex which filter
most constituents of the blood other than red blood cells and protein,
reabsorb needed substances, secrete hydrogen ions to maintain acid-base
balance, and secrete wastes.1
Urine formation consists of three basic
processes: glomerular filtration, tubular secretion, and tubular
reabsorption. Several disease conditions can interfere with these
functions. Inflammatory and degenerative diseases can involve the
small blood vessels and membranes in the nephrons. Urinary tract
infections and kidney stones can interfere with normal drainage,
causing further infection and tissue damage. Circulatory disorders,
such as hypertension, can damage the small renal arteries. Other
diseases, such as diabetes, gout, and urinary tract abnormalities
can lead to impaired function, infection, or obstruction. Toxic
agents such as insecticides, solvents, and certain drugs may also
harm renal tissue.
Nephrotic Syndrome
In nephrotic syndrome, an
injury to the glomerular basement membrane causes an increased glomerular
permeability, resulting in the loss of albumin and other plasma
proteins in the urine. Urinary protein losses greater than 3-3.5
grams per day usually indicate nephrotic syndrome.
Although albumin synthesis in the liver
is increased in nephrotic syndrome, it is not enough to compensate
for losses in the urine. The loss of albumin leads to edema.
Low albumin levels also trigger cholesterol
and lipoprotein synthesis in the liver, resulting in hyperlipidemia.
At the same time, hepatic catabolism of serum lipoproteins is reduced
and urinary excretion of HDL is increased. These lipid abnormalities
can be exacerbated by medications often used to treat nephrotic
syndrome, such as steroids, diuretics, and anti-hypertensive agents.
Diet for Nephrotic Syndrome
A well-planned
diet can replace lost protein and ensure efficient utilization of
ingested proteins through provision of adequate calories. Dietary
changes can also help control hypertension, edema, and hyperlipidemia,
and slow the progression of renal disease.
Protein: High-protein diets are not recommended
as they may encourage damage to the nephrons, leading to a progression
of renal insufficiency. Since albumin losses in nephrotic patients
are due to increased catabolism, rather than a reduction in protein
synthesis, low-protein diets, which decrease catabolism, may be more
beneficial.2
The
optimal amount of dietary protein necessary to prevent protein catabolism
and progression of renal disease has not been established. A common
recommendation is 0.6 grams of protein per kilogram of ideal body
weight, adjusted depending on the glomerular filtration rate and
nutritional status, plus gram-for-gram replacement of urinary protein
losses.
A vegetarian diet, often used for lipid-lowering,
also offers a convenient way to provide adequate, but not excessive,
protein. In a 1992 study, a group of 20 nephrotic syndrome patients
were put on a vegetarian diet for eight weeks. Protein intake averaged
0.7 grams per kilogram per day, which was more appropriate to their
needs than the 1.15 grams per kilogram provided in their usual diet.3
Sodium and Fluid: A limit on sodium of 1-3
grams per day is usually recommended to control edema and hypertension.
Diuretics may also be used. A fluid restriction is not warranted unless
renal failure occurs.
Lipids: A diet low in saturated fat and cholesterol,
combined with loss of excess weight, is recommended to reduce the
risk of cardiovascular disease. Many clinicians recommend limiting
cholesterol to less than 300 milligrams per day and fat intake to
30 percent of calories. However, research has shown that such recommendations
lead to only minimal lipid lowering. As noted in detail in Section
1, low-fat vegetarian diets are much more effective for lipid
control and usually lead to the reversal of atherosclerotic disease.
Cholesterol-lowering drugs can be used adjunctively if needed.
An eight-week trial in 13 men and 7 women
with hyperlipidemia and nephrotic syndrome showed that a vegetarian
diet significantly reduced cholesterol, triglycerides, and phosphorus.3
Energy: Calorie intake should be adequate
to achieve and maintain ideal body weight and maintain protein stores.
Foods rich in complex carbohydrates should provide the majority of
calories.
Supplements: Patients with nephrotic syndrome
are often low in B vitamins and zinc, and can benefit from supplements.
In addition, since a significant portion of serum calcium is protein-bound,
it tends to be low when serum proteins are reduced. No modification
is routinely needed for potassium, but potassium losses due to secondary
hyperaldosteronism may require replacement.4
The following clinical values should
be monitored:4
- Serum albumin and total protein
- Urinary protein
- Glomerular filtration rate
- Dietary protein, fat, and cholesterol
- Daily weights
- Serum lipids
Acute Renal Failure
Acute renal failure, manifested by oliguria or
anuria, usually occurs suddenly and is often reversible. It is marked
by a reduction in the glomerular filtration rate and a modification
in the kidneys ability to excrete metabolic wastes. Its
causes can be prerenal, intrinsic, and postrenal. Prerenal causes
include severe dehydration and circulatory collapse. Causes intrinsic
to the kidney include acute tubular necrosis, nephrotoxicity, vascular
disorders, and acute glomerulonephritis. Obstructive (postrenal)
causes include benign prostatic hypertrophy and bladder or prostate
cancer.1
The most common form of intrinsic renal
disease is acute tubular necrosis, accounting for about 75 percent
of cases. Acute tubular necrosis may be due to posttraumatic or
surgical shock or to the toxic effects of drugs, metals, or organic
compounds.
Nutrition strategies in acute tubular
necrosis vary depending on its stage. During phase one, oliguria,
less than 400 milliliters of urine is produced per day. This phase
usually lasts one to three weeks. Signs and symptoms include nausea,
vomiting, fluid overload, and elevation of BUN, creatinine, phosphorus,
and potassium levels. Dialysis may be needed during this stage to
reduce acidosis, control hyperkalemia, and correct uremia.
The diuretic phase of acute tubular necrosis
lasts one to two weeks, and is characterized by increased urine
output and a return of the ability to eliminate wastes. Fluid and
electrolyte balance should be monitored and replacements made as
necessary. The convalescent phase occurs over the next two to six
months.1,2
Diet in Acute Renal
Failure
Diet plays
a critical role in the care of patients with acute renal failure.
Clinicians should plan diets with an eye toward the possibility
of uremia, metabolic acidosis, fluid and electrolyte imbalances,
infection, and tissue destruction. Nutritional support of dialysis
will be discussed below in the section on chronic renal failure.
Protein: A low-protein diet (0.5-0.6 grams
per kilogram) is recommended initially. Protein may be increased in
the diet as the glomerular filtration rate increases to normal. If
dialysis is initiated, the protein level may be increased to 1.0-1.5
grams per kilogram per day if necessary to compensate for protein
losses in the dialysate.
Calories: Calorie needs are generally elevated
(35-50 kilocalories per kilogram) in order to provide positive nitrogen
balance under stressful conditions. As protein is usually quite
restricted, calorie needs may be met by providing greater amounts
of carbohydrate and fat in the diet.
Sodium and Fluid: Sodium is restricted depending
on urinary excretion, edema, serum sodium levels, and dialysis needs.
During the oliguric phase, sodium may be restricted to 500-1000 milligrams
per day, and fluid requirements are based on replacing losses via
urine, vomitus, and diarrhea, plus approximately 500 milliliters per
day.
Potassium: Potassium requirements
vary depending on hemodynamic status and the degree of hypermetabolism
due to stress, infection, or fever. High potassium levels are treated
by dialysis or with kayexalate, an exchange resin which substitutes
sodium for potassium in the gastrointestinal tract. During the oliguric
phase, potassium may be restricted to 1,000 milligrams per day.3
Chronic Renal Failure
Approximately
90 percent of cases of end-stage renal disease are attributable
to diabetes mellitus, glomerulonephritis, or hypertension. Kidney
failure results in fluid and electrolyte imbalances, the build up
of nitrogenous wastes, and reduced ability to produce renal hormones.
The two treatment options are transplantation or dialysis.1
Mild renal insufficiency is defined as
40-80 percent of renal function. Moderate insufficiency is defined
as 15-40 percent, and severe renal insufficiency is below these
figures.2
Diet in Chronic
Renal Failure
Low-protein
diets may slow the progression of mild and moderate renal insufficiency.
Therapeutic diets using plant sources of protein are more effective
in delaying the progression of renal insufficiency, compared to
those using animal proteins.5
Vegan (pure vegetarian) diets have been
shown to provide adequate protein. A study of 22 patients with mild
renal failure compared a vegan diet to a conventional low-protein
diet. All patients were followed for at least six months. There
was no sign of protein insufficiency and inorganic phosphorus levels
remained normal.6
Dialysis Patients
Dialysis changes dietary
needs. Patients undergoing typical hemodialysis, involving about
three treatments per week, follow diets that are restricted in protein,
sodium, potassium, phosphorus, and fluid. Patients on continuous
ambulatory peritoneal dialysis, involving several dialysate exchanges
per day, can be more liberal in protein, sodium, potassium, and
fluid intake.
Sodium: Sodium intake must be modified to
prevent hypertension, congestive heart failure, and pulmonary edema.
Limiting intake will help avoid thirst and maintain acceptable fluid
balance. Restrictions range from 1,000-3,000 milligrams per day with
hemodialysis and 2,000-4,000 milligrams per day for peritoneal dialysis.
Major salt sources are described below.
Fluid: Fluid consumption should
be controlled to avoid congestive heart failure, pulmonary edema,
hypertension, and swelling of the legs and feet. Fluid allowances
are 1,000-1,5000 milliliters per day and are based on urine output
and type of dialysis.
Protein: Protein requirements range from
1.1-1.5 grams per kilogram, depending on the type of dialysis used
and the patient’s nutritional status. It is important to ensure
sufficient protein to maintain visceral protein stores, but to avoid
excesses that could lead the accumulation of nitrogenous waste products
in the blood (uremia).
Phosphorus: Kidney failure causes
high levels of phosphorus to build up in the blood and disrupts
calcium/phosphorus balance. Elevated phosphorus levels can lead
to metastatic calcification (soft tissue calcification), secondary
hyperparathyroidism, and renal osteodystrophy. Recommended intakes
usually range from 800-1,000 milligrams per day with hemodialysis
and less than 1,200 milligrams per day with periotoneal dialysis.
Potassium: Potassium restrictions depend
on serum potassium levels, the type of dialysis, medications, and
residual renal function. Patients on hemodialysis are usually restricted
to 2,000-3,000 milligrams per day to prevent hyperkalemia between
treatments. Patients on peritoneal dialysis may follow a more liberal
dietary potassium intake, as potassium is lost in the dialysate solution
during daily exchanges. Some high- and low-potassium foods are listed
in Table 1, Section 5. Kidney
Stones
About 12 percent of Americans develop a kidney
stone at some point in their lives. Stones usually result from the
crystallization of calcium (which originally came in foods or supplements)
and oxalate, a part of many plant foods. Some people have a tendency
to lose excessive amounts of calcium or oxalate through their kidneys,
and they have a greater likelihood of a stone.7-10 Kidney
stones can also form from uric acid, which is a breakdown product
of protein, or from struvite (ammoniomagnesium phosphate) or cystine.
The prevalence of kidney stones is three
times higher in men than women, and is higher among Caucasians than
Asians or African Americans, for reasons that are not clear. They
are especially likely to strike between the ages of 40 and 60.
Nutritional steps are important in preventing
stones and can also help prevent recurrences, which is important
given that 30-50 percent of people diagnosed with a renal stone
have a recurrence within five years.
Preventing stones is like keeping a salt
crystal from forming in a glass of salty water. You can either reduce
the concentration of salt or add more water. Epidemiologic studies
have shown that certain parts of the diet help reduce the amount
of calcium that filters into the urine. It is a simple matter to
put these factors to work clinically.
WHAT’S
IN A STONE? 7 |
| Calcium oxalate |
72% |
| Uric acid |
23% |
| Ammoniomagnesium phosphate
(struvite) |
5% |
| Cystine |
<1% |
Protective Foods
Certain parts of the diet clearly help
reduce the risk. The first is no surprise.
Water. Water dilutes the
urine and keeps calcium, oxalates, and uric acid in solution. In research
studies, those subjects whose total fluid intake (from all sources)
over 24 hours was roughly 2.5 liters, the risk of a stone was about
one-third less than that of subjects drinking only half that much.7
(They do not need to drink 2.5 liters of water per day; rather this
is the total fluid consumption, including juices, soups, etc.) Patients
need to understand that their thirst sense can lag behind their hydration
status, and they may need to develop a routine for extra water consumption.
High-Potassium Foods.
A study of 46,000 men conducted by Harvard University researchers
found that a high potassium intake can cut the risk of kidney stones
in half. Potassium helps the kidneys retain calcium, rather than
sending it out into the urine. Potassium supplements are not generally
necessary. Rather, a diet including regular servings of fruits,
vegetables, and beans supplies plenty of potassium.
Calcium. Although most stones contain calcium,
the calcium in foods does not necessarily contribute to stones. Calcium
supplements taken between meals may increase the risk of stones, because
about 8 percent of any extra dietary calcium passes into the urine.9,11
On the other hand, calcium consumed with meals has the opposite effect,
reducing the risk of stones. The reason, apparently, is that calcium
binds to oxalates in foods and holds them in the digestive tract,
rather than allowing them to be absorbed.
Caffeine. Caffeinated beverages
reduce the risk of stones. Caffeine’s diuretic effect causes
the loss of both water and calcium, but the water loss is apparently
the predominant effect. Similarly, alcoholic beverages are associated
with a reduced risk of kidney stones, again presumably due to a
diuretic effect. This is not a compelling reason to drink either
coffee or alcohol, but their diuretic actions do present this advantage.
Problem Foods
Animal Protein. Animal proteins cause calcium
to be leached from the bones and excreted in the urine where it
can form stones. Diets rich in animal proteins also increase uric
acid excretion. In a controlled research study, published in the
American Journal of Clinical Nutrition, research subjects
on a diet eliminating animal protein had less than half the calcium
loss that they had on their baseline diet.12
The Harvard study mentioned earlier found
that even a modest increase in animal protein, from less than 50
grams to 77 grams per day, was associated with a 33 percent increased
risk of stones in men.7 The same is true for women. The
Nurses’ Health Study, a long-term study of health factors in
a large group of women, revealed an even greater risk of stones
from animal protein than was found in previous studies in men.9
The association between animal proteins
and stones probably relates both to the amount of protein they contain
and to their content of the sulfur-containing amino acids. In particular,
the sulfur in cystine and methionine is converted to sulfate, which
tends to acidify the blood. As a part of the process of neutralizing
this acid, bone is dissolved, and bone calcium ends up in the urine.
Meats and eggs contain two to five times more of these sulfur-containing
amino acids than are found in grains and beans.11,13
Between 1958 and the late 1960s, there
was a sharp increase in the incidence of kidney stones in Great
Britain. During that period, there was no substantial change in
the amount of calcium or oxalate-containing foods consumed. However,
the consumption of vegetables decreased, and the use of poultry,
fish, and red meat increased. Statistical analyses showed a strong
relationship between the incidence of stones and animal protein
consumption.14
Sodium. Sodium increases the passage of
calcium through the kidney and increases the risk of stones.9
When people cut their salt (sodium chloride) intake in half, they
reduce their daily need for calcium by about 160 milligrams.15
Plants of any kind—grains, vegetables,
legumes, and fruits—contain almost no sodium at all unless
it is added during canning or other processing. Dairy products and
meats contain more salt than plant products, and table salt, frozen
meals, and canned and snack foods are the highest-sodium food products.
For more information, see the sodium/potassium chart in Section
5.
Sugar. Sugar accelerates calcium losses
through the kidney.16 In the Nurses’ Health Study,
those who consumed, on average, 60 grams or more of sugar (sucrose)
per day had a 50 percent higher risk of stones than those who consumed
only about 20 grams.9
SUGAR
IN COMMON FOODS (grams) |
| Candy bar (2 ounces) |
22-35 |
| Cookies (3) |
|
| Corn flakes (1 cup,
28 grams) |
2 |
| Frosted corn flakes
(1 cup, 41 grams) |
17 |
| Crackers (5) |
1 |
| Fruit cocktail (1/2
cup, 124 grams) |
14 |
| Grape jam (1 tablespoon) |
13 |
| Ice cream (1/2 cup,
106 grams) |
21 |
| Soda
(12 ounces) |
40 |
| White bread (2 slices) |
1 |
Source: package
information |
Climate. Kidney stones are also more common
in warm climates, presumably because perspiration leads to dehydration
and a more concentrated urine, and because sunlight increases
the production of vitamin D in the skin which, in turn, increases
calcium absorption from the digestive tract.17
Surprisingly, oxalate-rich foods, such
as chocolate, nuts, tea, and spinach, are not associated with a
higher risk of renal stones,7 nor is vitamin C, even
though it can be converted to oxalate. A large study of men taking
vitamin C supplements found that they had no more kidney stones
than men who do not take them.8
Helping Patients Avoid
Kidney Stones
Here are simple steps to help your patients avoid
kidney stones.
- Encourage patients to drink plenty of water
or other fluids, staying ahead of their thirst.
- Diets including generous amounts of vegetables,
fruits, and beans are rich in potassium and very low in sodium.
- If you prescribe calcium supplements, encourage
patients to take them with meals, rather than between meals.
- Encourage patients to avoid animal products.
Their proteins and sodium content increase the risk of stones.
- Patients should keep salt and sugar use modest.
Cranberry Juice:
An Old Remedy Is Clinically Tested
Cranberry juice has long been used as a folk remedy
for urinary infections. A 1994 report in the Journal of the American
Medical Association showed that it does indeed have at least
a preventive effect. In a test involving 153 elderly women in Boston,
half the subjects drank 300 milliliters (about one and one-quarter
cups) of cranberry juice cocktail each day, using the same bottled
beverage that is commonly sold in grocery stores.18 The
other subjects consumed a drink that looked and tasted like cranberry
juice, but had no real juice in it.
Over the next six months, urine samples
were collected and tested for signs of bacteria. The women consuming
cranberry juice had only 42 percent as many urinary infections as
the control group. The number of cases that had to be treated by
antibiotics was also only about half, which is a real advantage,
since antibiotics can sometimes lead to yeast infections and other
problems. It takes about four to eight weeks for the preventive
effect to be seen.
The explanation for the effect of cranberry
juice is probably not an acidification of the urine, because the
placebo drink also reduced urinary pH. Rather, cranberries contain
a substance that stops bacteria from being able to attach to cells,
and this is probably true whether the cranberry juice reaches the
bacteria in the digestive tract or the urinary tract. Substances
that interfere with bacterial adhesion have also been found in blueberry
juice, but not in orange, grapefruit, pineapple, mango, or guava
juice.
Nutrition and Renal
Disease Study Questions
- What are some of the main problems of nephrotic
syndrome?
- Why are high protein diets not recommended
with nephrotic syndrome? What are the alternatives?
- What type of dietary restrictions are used
in acute renal failure?
- What are the treatment options for chronic
renal failure? How do dietary regimens differ between hemodialysis
and peritoneal dialysis?
- What steps can be taken to prevent kidney
stones?
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References
1. Mahan LK, Arlin M. Krause’s Food, Nutrition, and Diet
Therapy. W.B. Saunders, Philadelphia, 1992.
2. The American Dietetic Association. Handbook of Clinical Dietetics,
second edition. Yale University Press, 1992.
3. D’Amico G, Gentile MG, Manna G, et al. Effect of vegetarian
soy diet on hyperlipidemia in nephrotic syndrome. Lancet 1992;339:1131-4.
4. The American Dietetic Association. Manual of Clinical Dietetics,
fifth edition. American Dietetic Association, Chicago, 1996.
5. Gretz N, Meisinger M, Strauch M. Does a low protein diet really
slow down the rate of progression of chronic renal failure? Blood
Purif 1989;7:33:33-8.
6. Barsotti G, Morelli E, Cupisti A, Meola M, Dani L, Giovannetti
S. A low-nitrogen, low-phosphorus vegan diet for patients with chronic
renal failure. Nephron 1996;74:390-4.
7. Curhan GC, Willett WC, Rimm EB, Stampfer MJ. A prospective study
of dietary calcium and other nutrients and the risk of symptomatic
kidney stones. N Engl J Med 1993;328:833-8.
8. Curhan GC, Willett WC, Rimm EB, Spiegelman D, Stampfer MJ. Prospective
study of beverage use and the risk of kidney stones. Am J Epidemiol
1996;143:240-7.
9. Curhan GC, Willett WC, Speizer FE, Spiegelman D, Stampfer MJ.
Comparison of dietary calcium with supplemental calcium and other
nutrients as factors affecting the risk for kidney stones in women.
Ann Int Med 1997;126:497-504.
10. Soucie JM, Thun MJ, Coates RJ, McClellan W, Austin H. Demographic
and geographic variability of kidney stones in the United States.
Kidney Int 1994;46:893-9.
11. Lemann J. Composition of the diet and calcium kidney stones.
N Engl J Med 1993;328:880-2.
12. Remer T, Manz F. Estimation of the renal net acid excretion
by adults consuming diets containing variable amounts of protein.
Am J Clin Nutr 1994;59:1356-61.
13. Breslau NA, Brinkley L, Hill KD, Pak CYC. Relationship of animal
protein-rich diet to kidney stone formation and calcium metabolism.
J Clin Endocrinol 1988;66:140-6.
14. Robertson WG, Peacock M, Hodgkinson A. Dietary changes and the
incidence of urinary calculi in the U.K. between 1958 and 1976.
J Chron Dis 1979;32:469-76.
15. Nordin BEC, Need AG, Morris HA, Horowitz M. The nature and significance
of the relationship between urinary sodium and urinary calcium in
women. J Nutr 1993;123:1615-22.
16. Lemann J Jr, Adams ND, Gray RW. Urinary calcium excretion in
human beings. N Engl J Med 1979;301:535-41.
17. Soucie JM, Coates RJ, McClellan W, Austin H, Thun MJ. Relation
between geographic variability in kidney stones prevalence and risk
factors for stones. Am J Epidemiol 1996;143:487-95.
18. Avorn J, Monane M, Gurwitz JH, Glynn RJ, Choodnovskiy I, Lipsitz
LA. Reduction of bacteriuria and pyuria after ingestion of cranberry
juice. JAMA 1994;271:751-4.
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