Depending on the cause, a proportion of patients (5–10%) will never regain full kidney function, thus entering end-stage kidney failure and requiring lifelong dialysis or a kidney transplant. Patients with AKI are more likely to die prematurely after being discharged from hospital, even if their kidney function has recovered.

The risk of developing chronic kidney disease is increased (8.8-fold).

Mortality after AKI remains high. Overall it is 20%, 30% if the patient is referred to nephrology, 50% if dialyzed, and 70% if on ICU.

If AKI develops after major surgery (13.4% of all people who have undergone major surgery) the risk of death is markedly increased (over 12-fold).

The prognosis depends on the underlying cause and whether any complications occur. Rhabdomyolysis complicated by acute kidney impairment in patients with traumatic injury may have a mortality rate of 20%. Admission to the intensive care unit is associated with a mortality of 22% in the absence of acute kidney injury, and 59% if kidney impairment occurs. Most people who have sustained kidney impairment due to rhabdomyolysis fully recover their kidney function.

As the majority of individuals with hepatorenal syndrome have cirrhosis, much of the epidemiological data on HRS comes from the cirrhotic population. The condition is quite common: approximately 10% of individuals admitted to hospital with ascites have HRS. A retrospective case series of cirrhotic patients treated with terlipressin suggested that 20.0% of acute kidney failure in cirrhotics was due to type 1 HRS, and 6.6% was due to type 2 HRS. It is estimated that 18% of individuals with cirrhosis and ascites will develop HRS within one year of their diagnosis with cirrhosis, and 39% of these individuals will develop HRS within five years of diagnosis. Three independent risk factors for the development of HRS in cirrhotics have been identified: liver size, plasma renin activity, and serum sodium concentration.

The prognosis of these patients is grim with untreated patients having an extremely short survival. The severity of liver disease (as evidenced by the MELD score) has been shown to be a determinant of outcome. Some patients without cirrhosis develop HRS, with an incidence of about 20% seen in one study of ill patients with alcoholic hepatitis.

The "APOL1" gene has been proposed as a major genetic risk locus for a spectrum of nondiabetic renal failure in individuals of African origin, these include HIV-associated nephropathy (HIVAN), primary nonmonogenic forms of focal segmental glomerulosclerosis, and hypertension affiliated chronic kidney disease not attributed to other etiologies. Two western African variants in APOL1 have been shown to be associated with end stage kidney disease in African Americans and Hispanic Americans.

Acute kidney injury (previously known as acute renal failure) – or AKI – usually occurs when the blood supply to the kidneys is suddenly interrupted or when the kidneys become overloaded with toxins. Causes of acute kidney injury include accidents, injuries, or complications from surgeries in which the kidneys are deprived of normal blood flow for extended periods of time. Heart-bypass surgery is an example of one such procedure.

Drug overdoses, accidental or from chemical overloads of drugs such as antibiotics or chemotherapy, may also cause the onset of acute kidney injury. Unlike chronic kidney disease, however, the kidneys can often recover from acute kidney injury, allowing the patient to resume a normal life. People suffering from acute kidney injury require supportive treatment until their kidneys recover function, and they often remain at increased risk of developing future kidney failure.

Among the accidental causes of renal failure is the crush syndrome, when large amounts of toxins are suddenly released in the blood circulation after a long compressed limb is suddenly relieved from the pressure obstructing the blood flow through its tissues, causing ischemia. The resulting overload can lead to the clogging and the destruction of the kidneys. It is a reperfusion injury that appears after the release of the crushing pressure. The mechanism is believed to be the release into the bloodstream of muscle breakdown products – notably myoglobin, potassium, and phosphorus – that are the products of rhabdomyolysis (the breakdown of skeletal muscle damaged by ischemic conditions). The specific action on the kidneys is not fully understood, but may be due in part to nephrotoxic metabolites of myoglobin.

Patients with ESKD are at increased overall risk for cancer. This risk is particularly high in younger patients and gradually diminishes with age. Medical specialty professional organizations recommend that physicians do not perform routine cancer screening in patients with limited life expectancies due to ESKD because evidence does not show that such tests lead to improved patient outcomes.

The exact number of cases of rhabdomyolysis is difficult to establish, because different definitions have been used. In 1995, hospitals in the U.S. reported 26,000 cases of rhabdomyolysis. Up to 85% of people with major traumatic injuries will experience some degree of rhabdomyolysis. Of those with rhabdomyolysis, 10–50% develop acute kidney injury. The risk is higher in people with a history of illicit drug use, alcohol misuse or trauma when compared to muscle diseases, and it is particularly high if multiple contributing factors occur together. Rhabdomyolysis accounts for 7–10% of all cases of acute kidney injury in the U.S.

Crush injuries are common in major disasters, especially in earthquakes. The aftermath of the 1988 Spitak earthquake prompted the establishment, in 1995, of the Renal Disaster Relief Task Force, a working group of the International Society of Nephrology (a worldwide body of kidney experts). Its volunteer doctors and nurses assisted for the first time in the 1999 İzmit earthquake in Turkey, where 17,480 people died, 5392 were hospitalized and 477 received dialysis, with positive results. Treatment units are generally established outside the immediate disaster area, as aftershocks could potentially injure or kill staff and make equipment unusable.

Acute exertional rhabdomyolysis happens in 2% to 40% of people going through basic training for the United States military. In 2012, the United States military reported 402 cases.

Cortical necrosis is a severe and life-threatening condition, with mortality rates over 50%. Those mortality rates are even higher in neonates with the condition due to the overall difficult nature of neonatal care and an increased frequency of comorbid conditions. The extent of the necrosis is a major determinant of the prognosis, which in turn is dependent on the duration of ischemia, duration of oliguria, and the severity of the precipitating conditions. Of those that survive the initial event, there are varying degrees of recovery possible, depending on the extent of the damage.

To minimize the risk for contrast-induced nephropathy, various actions can be taken if the patient has predisposing conditions. These have been reviewed in a meta-analysis. A separate meta-analysis addresses interventions for emergency patients with baseline insufficient kidney function.

Individuals with chronic kidney disease, diabetes mellitus, high blood pressure, reduced intravascular volume, or who are elderly are at increased risk of developing CIN after exposure to iodinated contrast.

A clinical prediction rule is available to estimate probability of nephropathy (increase ≥25% and/or ≥0.5 mg/dl in serum creatinine at 48 h):

Risk Factors:

- Systolic blood pressure <80 mm Hg - 5 points

- Intraarterial balloon pump - 5 points

- Congestive heart failure (Class III-IV or history of pulmonary edema) - 5 points

- Age >75 y - 4 points

- Hematocrit level <39% for men and <35% for women - 3 points

- Diabetes mellitus- 3 points

- Contrast media volume - 1 point for each 100 mL

- Decreased kidney function:

- Serum creatinine level >1.5 g/dL - 4 points

- Estimated Glomerular filtration rate (online calculator)

Scoring:

5 or less points

- Risk of CIN - 7.5

- Risk of Dialysis - 0.04%

6–10 points

- Risk of CIN - 14.0

- Risk of Dialysis - 0.12%

11–16 points

- Risk of CIN - 26.1*

- Risk of Dialysis - 1.09%

>16 points

- Risk of CIN - 57.3

- Risk of Dialysis - 12.8%

CKD increases the risk of cardiovascular disease, and people with CKD often have other risk factors for heart disease, such as high blood lipids. The most common cause of death in people with CKD is cardiovascular disease rather than kidney failure.

Chronic kidney disease results in worse all-cause mortality (the overall death rate) which increases as kidney function decreases. The leading cause of death in chronic kidney disease is cardiovascular disease, regardless of whether there is progression to stage 5.

While renal replacement therapies can maintain people indefinitely and prolong life, the quality of life is negatively affected. Kidney transplantation increases the survival of people with stage 5 CKD when compared to other options; however, it is associated with an increased short-term mortality due to complications of the surgery. Transplantation aside, high-intensity home hemodialysis appears to be associated with improved survival and a greater quality of life, when compared to the conventional three-times-a-week hemodialysis and peritoneal dialysis.

Prompt treatment of some causes of azotemia can result in restoration of kidney function; delayed treatment may result in permanent loss of renal function. Treatment may include hemodialysis or peritoneal dialysis, medications to increase cardiac output and increase blood pressure, and the treatment of the condition that caused the azotemia.

The osmolality of the contrast agent was previously believed to be an important factor in contrast-induced nephropathy. Today it has become increasingly clear that other physicochemical properties play a greater role, such as viscosity. Attention should be paid to using contrast agents of low viscosity. Moreover, sufficient fluids should be supplied to limit fluid viscosity of urine. Modern iodinated contrast agents are non-ionic, the older ionic types caused more adverse effects, and their use has diminished.

Azotemia has three classifications, depending on its causative origin. A BUN/Cr > 20 tends to herald prerenal azotemia (commonly secondary to dehydration but also any other reason perfusion to kidneys is decreased). The BUN-to-creatinine ratio (BUN:Cr) is a useful measure in determining the type of azotemia. A normal BUN:Cr is equal to 15.

Conditions causing increased blood urea fall into three different categories: Prerenal, renal, and postrenal.

Prerenal azotemia can be caused by decreased blood flow through the kidneys (e.g. low blood pressure, congestive heart failure, shock, bleeding, dehydration) or by increased production of urea in the liver via a high protein diet or increased protein catabolism (e.g. stress, fever, major illness, corticosteroid therapy or gastrointestinal bleeding).

Renal causes can be attributed to decreased kidney function. These include acute and chronic kidney failure, acute and chronic glomerular nephritis, tubular necrosis and other kidney diseases.

Post renal causes can be due to decreased elimination of urea. These could be due to urinary outflow obstruction such as by calculi, tumours of the bladder or prostate, or a severe infection.

Patients will require dialysis to compensate for the function of their kidneys.

Uremia results in many different compounds being retained by the body. With the failure of the kidneys, these compounds can build up to dangerous levels. There are more than 90 different compounds that have been identified. Some of these compounds can be toxic to the body and are talked about in the following section. See below for a list of uremic solute groups, examples, their source and characteristics.

Kidney failure is very common in patients suffering from congestive heart failure. It was shown that kidney failure complicates one-third of all admissions for heart failure, which is the leading cause of hospitalization in the United States among adults over 65 years old. These complications led to longer hospital stay, higher mortality, and greater chance for readmission. Another study found that 39% of patients in NYHA class 4 and 31% of patients in NYHA class 3 had severely impaired kidney function. Similarly, kidney failure can have deleterious effects on cardiovascular function. It was estimated that about 44% of deaths in patients with end-stage kidney failure (ESKF) are due to cardiovascular disease.

Acute uric acid nephropathy (AUAN, also acute urate nephropathy) is a rapidly worsening (decreasing) kidney function (renal insufficiency) that is caused by high levels of uric acid in the urine (hyperuricosuria).

Despite expensive treatments, lupus nephritis remains a major cause of morbidity and mortality in people with relapsing or refractory lupus nephritis.

The risk of death in hepatorenal syndrome is very high; consequently, there is a significant emphasis on the identification of patients who are at risk for HRS, and prevention of triggers for onset of HRS. As infection (specifically spontaneous bacterial peritonitis) and gastrointestinal hemorrhage are both complications in individuals with cirrhosis, and are common triggers for HRS, specific care is made in early identification and treatment of cirrhotics with these complications to prevent HRS. Some of the triggers for HRS are induced by treatment of ascites and can be preventable. The aggressive use of diuretic medications should be avoided. In addition, many medications that are either used to treat cirrhotic complications (such as some antibiotics) or other conditions may cause sufficient impairment in kidney function in the cirrhotic to lead to HRS. Also, large volume paracentesis—which is the removal of ascites fluid from the abdomen using a needle or catheter in order to relieve discomfort—may cause enough alteration in hemodynamics to precipitate HRS, and should be avoided in individuals at risk. The concomitant infusion of albumin can avert the circulatory dysfunction that occurs after large-volume paracentesis and may prevent HRS. Conversely, in individuals with very tense ascites, it has been hypothesized that removal of ascitic fluid may improve kidney function if it decreases the pressure on the renal veins.

Individuals with ascites that have become infected spontaneously (termed spontaneous bacterial peritonitis or SBP) are at an especially high risk for the development of HRS. In individuals with SBP, one randomized controlled trial found that the administration of intravenous albumin on the day of admission and on the third day in hospital reduced both the rate of kidney insufficiency and the mortality rate.

The long-term use of lithium, a medication commonly used to treat bipolar disorder and schizoaffective disorders, is known to cause nephropathy.

Renal tuberculosis

And other causes of hypercalcemia (and thus hypercalciuria)

- Immobilization (leading to hypercalcemia and hypercalciuria)

- Milk-alkali syndrome

- Hypervitaminosis D

- Multiple myeloma

The following risk factors have been associated with increased incidence of CRS.

- Older age

- Comorbid conditions (diabetes mellitus, uncontrolled hypertension, anemia)

- Drugs (anti-inflammatory agents, diuretics, ACE inhibitors, ARBs)

- History of heart failure or impaired left ventricular ejection fraction

- Prior myocardial infarction

- New York Heart Association (NYHA) functional class

- Elevated cardiac troponins

- Chronic kidney disease (reduced eGFR, elevated BUN, creatinine, or cystatin)

These conditions can cause nephrocalcinosis in association with hypercalciuria without hypercalcemia:

- Distal renal tubular acidosis

- Medullary sponge kidney

- Neonatal nephrocalcinosis and loop diuretics

- Inherited tubulopathies

- Chronic hypokalemia

- Beta thalassemia