Chapter 2.1: Definition and classification of AKI
INTRODUCTION
AKI is one of a number of conditions that affect kidney structure and function. AKI
is defined by an abrupt decrease in kidney function that includes, but is not limited
to, ARF. It is a broad clinical syndrome encompassing various etiologies, including
specific kidney diseases (e.g., acute interstitial nephritis, acute glomerular and
vasculitic renal diseases); non-specific conditions (e.g, ischemia, toxic injury);
as well as extrarenal pathology (e.g., prerenal azotemia, and acute postrenal obstructive
nephropathy)—see Chapters 2.2 and 2.3 for further discussion. More than one of these
conditions may coexist in the same patient and, more importantly, epidemiological
evidence supports the notion that even mild, reversible AKI has important clinical
consequences, including increased risk of death.
2, 5
Thus, AKI can be thought of more like acute lung injury or acute coronary syndrome.
Furthermore, because the manifestations and clinical consequences of AKI can be quite
similar (even indistinguishable) regardless of whether the etiology is predominantly
within the kidney or predominantly from outside stresses on the kidney, the syndrome
of AKI encompasses both direct injury to the kidney as well as acute impairment of
function. Since treatments of AKI are dependent to a large degree on the underlying
etiology, this guideline will focus on specific diagnostic approaches. However, since
general therapeutic and monitoring recommendations can be made regarding all forms
of AKI, our approach will be to begin with general measures.
Definition and staging of AKI
AKI is common, harmful, and potentially treatable. Even a minor acute reduction in
kidney function has an adverse prognosis. Early detection and treatment of AKI may
improve outcomes. Two similar definitions based on SCr and urine output (RIFLE and
AKIN) have been proposed and validated. There is a need for a single definition for
practice, research, and public health.
2.1.1: AKI is defined as any of the following (Not Graded):
Increase in SCr by ⩾0.3 mg/dl (⩾26.5 μmol/l) within 48 hours; or
Increase in SCr to ⩾1.5 times baseline, which is known or presumed to have occurred
within the prior 7 days; or
Urine volume <0.5 ml/kg/h for 6 hours.
2.1.2: AKI is staged for severity according to the following criteria (Table 2). (Not
Graded)
2.1.3: The cause of AKI should be determined whenever possible. (Not Graded)
RATIONALE
Conditions affecting kidney structure and function can be considered acute or chronic,
depending on their duration. AKI is one of a number of acute kidney diseases and disorders
(AKD), and can occur with or without other acute or chronic kidney diseases and disorders
(Figure 2). Whereas CKD has a well-established conceptual model and definition that
has been useful in clinical medicine, research, and public health,
42, 43, 44
the definition for AKI is evolving, and the concept of AKD is relatively new. An operational
definition of AKD for use in the diagnostic approach to alterations in kidney function
and structure is included in Chapter 2.5, with further description in Appendix B.
The conceptual model of AKI (Figure 3) is analogous to the conceptual model of CKD,
and is also applicable to AKD.
42, 45
Circles on the horizontal axis depict stages in the development (left to right) and
recovery (right to left) of AKI. AKI (in red) is defined as reduction in kidney function,
including decreased GFR and kidney failure. The criteria for the diagnosis of AKI
and the stage of severity of AKI are based on changes in SCr and urine output as depicted
in the triangle above the circles. Kidney failure is a stage of AKI highlighted here
because of its clinical importance. Kidney failure is defined as a GFR <15 ml/min
per 1.73 m
2
body surface area, or requirement for RRT, although it is recognized that RRT may
be required earlier in the evolution of AKI. Further description is included in Chapter
2.5 and Appendix A.
It is widely accepted that GFR is the most useful overall index of kidney function
in health and disease, and changes in SCr and urine output are surrogates for changes
in GFR. In clinical practice, an abrupt decline in GFR is assessed from an increase
in SCr or oliguria. Recognizing the limitations of the use of a decrease in kidney
function for the early detection and accurate estimation of renal injury (see below),
there is a broad consensus that, while more sensitive and specific biomarkers are
needed, changes in SCr and/or urine output form the basis of all diagnostic criteria
for AKI. The first international interdisciplinary consensus criteria for diagnosis
of AKI were the RIFLE criteria
32
proposed by the ADQI. Modifications to these criteria have been proposed in order
to better account for pediatric populations (pRIFLE)
32
and for small changes in SCr not captured by RIFLE (AKIN criteria).
23
Recommendations 2.1.1 and 2.1.2 represent the combination of RIFLE and AKIN criteria
(Table 3).
Existing evidence supports the validity of both RIFLE and AKIN criteria to identify
groups of hospitalized patients with increased risk of death and/or need for RRT.
2, 5, 25, 28, 29, 30
Epidemiological studies, many multicentered, collectively enrolling more than 500 000
subjects have been used to establish RIFLE and/or AKIN criteria as valid methods to
diagnose and stage AKI. Recently, Joannidis et al.
29
directly compared RIFLE criteria with and without the AKIN modification. While AKI
classified by either criteria were associated with a similarly increased hospital
mortality, the two criteria identified somewhat different patients. The original RIFLE
criteria failed to detect 9% of cases that were detected by AKIN criteria. However,
the AKIN criteria missed 26.9% of cases detected by RIFLE. Examination of the cases
missed by either criteria (Table 4) shows that cases identified by AKIN but missed
by RIFLE were almost exclusively Stage 1 (90.7%), while cases missed by AKIN but identified
by RIFLE included 30% with RIFLE-I and 18% RIFLE-F; furthermore, these cases had hospital
mortality similar to cases identified by both criteria (37% for I and 41% for F).
However, cases missed by RIFLE but identified as Stage 1 by AKIN also had hospital
mortality rates nearly twice that of patients who had no evidence of AKI by either
criteria (25% vs. 13%). These data provide strong rationale for use of both RIFLE
and AKIN criteria to identify patients with AKI.
Staging of AKI (Recommendation 2.1.2) is appropriate because, with increased stage
of AKI, the risk for death and need for RRT increases.
2, 5, 25, 28, 29, 30, 31
Furthermore, there is now accumulating evidence of long-term risk of subsequent development
of cardiovascular disease or CKD and mortality, even after apparent resolution of
AKI.
47, 48, 49
For staging purposes, patients should be staged according to the criteria that give
them the highest stage. Thus when creatinine and urine output map to different stages,
the patient is staged according to the highest (worst) stage. The changes in GFR that
were published with the original RIFLE criteria do not correspond precisely to changes
in SCr. As SCr is measured and GFR can only be estimated, creatinine criteria should
be used along with urine output for the diagnosis (and staging) of AKI. One additional
change in the criteria was made for the sake of clarity and simplicity. For patients
reaching Stage 3 by SCr >4.0 mg/dl (>354 μmol/l), rather than require an acute increase
of ⩾0.5 mg/dl (⩾44 μmol/l) over an unspecified time period, we instead require that
the patient first achieve the creatinine-based change specified in the definition
(either ⩾0.3 mg/dl [⩾26.5 μmol/l] within a 48-hour time window or an increase of ⩾1.5
times baseline). This change brings the definition and staging criteria to greater
parity and simplifies the criteria.
Recommendation 2.1.2 is based on the RIFLE and AKIN criteria that were developed for
average-sized adults. The creatinine change–based definitions include an automatic
Stage 3 classification for patients who develop SCr >4.0 mg/dl (>354 μmol/l) (provided
that they first satisfy the definition of AKI in Recommendation 2.1.1). This is problematic
for smaller pediatric patients, including infants and children with low muscle mass
who may not be able to achieve a SCr of 4.0 mg/dl (354 μmol/l). Thus, the pediatric-modified
RIFLE AKI criteria
32
were developed using a change in estimated creatinine clearance (eCrCl) based on the
Schwartz formula. In pRIFLE, patients automatically reach Stage 3 if they develop
an eCrCl <35 ml/min per 1.73 m2. However, with this automatic pRIFLE threshold, the
SCr change based AKI definition (recommendation 2.1.1) is applicable to pediatric
patients, including an increase of 0.3 mg/dl (26.5 μmol/l) SCr.
32
There are important limitations to these recommendations, including imprecise determination
of risk (see Chapter 2.2) and incomplete epidemiology of AKI, especially outside the
ICU. Clinical judgment is required in order to determine if patients seeming to meet
criteria do, in fact, have disease, as well as to determine if patients are likely
to have AKI even if incomplete clinical data are available to apply the diagnostic
criteria. The application of the diagnostic and staging criteria is discussed in greater
detail, along with specific examples in Chapter 2.4.
The use of urine output criteria for diagnosis and staging has been less well validated
and in individual patients the need for clinical judgment regarding the effects of
drugs (e.g., angiotensin-converting enzyme inhibitors [ACE-I]), fluid balance, and
other factors must be included. For very obese patients, urine output criteria for
AKI may include some patients with normal urine output. However, these recommendations
serve as the starting point for further evaluation, possibly involving subspecialists,
for a group of patients recognized to be at increased risk.
Finally, it is axiomatic that patients always be managed according to the cause of
their disease, and thus it is important to determine the cause of AKI whenever possible.
In particular, patients with decreased kidney perfusion, acute glomerulonephritis,
vasculitis, interstitial nephritis, thrombotic microangiopathy, and urinary tract
obstruction require immediate diagnosis and specific therapeutic intervention, in
addition to the general recommendations for AKI in the remainder of this guideline
(Table 5).
It is recognized that it is frequently not possible to determine the cause, and often
the exact cause does not dictate a specific therapy. However, the syndrome of AKI
includes some patients with specific kidney diseases (e.g., glomerulonephritis) for
which a specific treatment is available. As such, it is always necessary to search
for the underlying cause of AKI (see Chapter 2.3).
Research Recommendations
The role of biomarkers other than SCr in the early diagnosis, differential diagnosis,
and prognosis of AKI patients should be explored. Some important areas in which to
focus include:
Early detection where the gold standard is AKI by clinical diagnosis after the fact
and the biomarker is compared to existing markers (SCr and urine output) at the time
of presentation.
Prognosis where a biomarker is used to predict risk for AKI or risk for progression
of AKI.
Prognosis where a biomarker is used to predict recovery after AKI vs. death or need
for long-term RRT.
The influence of urinary output criteria on AKI staging needs to be further investigated.
Influence of fluid balance, percent volume overload, diuretic use, and differing weights
(actual, ideal body weight, lean body mass) should be considered. Also, it is currently
not known how urine volume criteria should be applied (e.g., average vs. persistent
reduction for the period specified).
The influence of SCr or eGFR criteria on AKI staging needs to be further investigated.
The use of different relative and absolute SCr increments or eGFR decrements at different
time points and with differently ascertained baseline values requires further exploration
and validation in various populations.
Chapter 2.2: Risk assessment
The kidney is a fairly robust organ that can tolerate exposure to several insults
without suffering significant structural or functional change. For this reason, any
acute change in kidney function often indicates severe systemic derangement and predicts
a poor prognosis. Risk for AKI is increased by exposure to factors that cause AKI
or the presence of factors that increase susceptibility to AKI. Factors that determine
susceptibility of the kidneys to injury include dehydration, certain demographic characteristics
and genetic predispositions, acute and chronic comorbidities, and treatments. It is
the interaction between susceptibility and the type and extent of exposure to insults
that determines the risk of occurrence of AKI.
Understanding individual “risk factors” may help in preventing AKI. This is particularly
gratifying in the hospital setting, where the patient's susceptibility can be assessed
before certain exposures as surgery or administration of potentially nephrotoxic agents.
Accordingly, some susceptibility factors may be modified, and contemplated exposures
avoided or tailored to reduce the risk of AKI.
Risk assessment in community-acquired AKI is different from hospital-acquired AKI,
for two main reasons: i) Available evidence on risk factors is largely derived from
hospital data and extrapolation to the community setting is questionable. ii) The
opportunity to intervene, prior to exposure, is quite limited. Most patients are seen
only after having suffered an exposure (trauma, infection, poisonous plant, or animal).
However, there is still room to assess such patients, albeit after exposure, in order
to identify those who are more likely to develop AKI, thereby requiring closer monitoring
and general supportive measures. It may also be helpful to identify such patients
in order to avoid additional injury. A more complete discussion of the approach to
identification and management of risk for AKI is provided in Appendices C and D.
2.2.1: We recommend that patients be stratified for risk of AKI according to their
susceptibilities and exposures. (1B)
2.2.2: Manage patients according to their susceptibilities and exposures to reduce
the risk of AKI (see relevant guideline sections). (Not Graded)
2.2.3: Test patients at increased risk for AKI with measurements of SCr and urine
output to detect AKI. (Not Graded) Individualize frequency and duration of monitoring
based on patient risk and clinical course. (Not Graded)
RATIONALE
There are many types of exposures that may cause AKI (Table 6) and these are discussed
in detail in Appendix C. However, the chances of developing AKI after exposure to
the same insult differ among different individuals. This is attributed to a number
of susceptibility factors which vary widely from individual to individual. Our understanding
of susceptibility factors (Table 6) is based on many observational studies that address
different settings with regards to the type, severity, duration, and multiplicity
of insults. While this heterogeneity provides insight into some susceptibility factors
that are common across various populations, the generalizability of results from one
particular setting to the next is uncertain.
The course and outcome of AKI are modified by other factors, but since these are manifested
within the context of actual disease, they must be categorized as “prognostic” rather
than “risk” factors, hence being discussed separately in Appendix D. Lastly, the fact
that some 30% of patients who recover from AKI remain at increased risk of CKD, cardiovascular
disease, and death calls for the identification of the risk factors that can identify
such patients in the hopes of providing them with timely preventive measures.
50, 51, 52
Finally, it is important to screen patients who have undergone an exposure (e.g.,
sepsis, trauma) and to continue monitor high-risk patients until the risk has subsided.
Exact intervals for checking SCr and in which individuals to monitor urine output
remain matters of clinical judgment; however, as a general rule, high risk in-patients
should have SCr measured at least daily and more frequently after an exposure, and
critically ill patients should have urine output monitoring. This will necessitate
urinary bladder catheterization in many cases, and the risks of infection should also
be considered in the monitoring plan.
A recent clinical practice assessment in the UK concluded that only 50% of patients
with AKI were considered to have received a “good” overall standard of care. This
figure fell to just over 30% if AKI developed during a hospital admission rather than
being diagnosed before admission.
53
The authors also felt that there was an unacceptable delay in recognizing AKI in 43%
of those that developed the condition after admission, and that in a fifth of such
patients its development was predictable and avoidable. Their recommendations were
simple: risk assessment for AKI as part of the initial evaluation of emergency admissions,
along with appropriate serum biochemistry on admission and at frequent intervals thereafter.
53
RESEARCH RECOMMENDATIONS
Better delineation of risk for hospital- and community-acquired AKI is needed.
Better delineation of the effects of age on the risk for AKI is needed.
Studies are needed to develop and validate scoring systems for AKI risk prediction
in various settings, in addition to cardiac surgery and exposure to radiocontrast
material.
Genome-wide association studies are needed to determine risk of AKI in different hospital
settings and with respect to long-term outcomes.
Studies are needed on risk factors for the development of, recovery from, and long-term
outcomes of community-acquired AKI, including sepsis, trauma, tropical infections,
snake bites, and ingestion of toxic plants, etc.
Chapter 2.3: Evaluation and general management of patients with and at risk for AKI
Given that AKI is associated with significant morbidity and mortality, and because
no specific treatment is available to reverse AKI, early recognition and management
is paramount. Indeed, recognition of patients at risk for AKI, or with possible AKI
but prior to clinical manifestations, is likely to result in better outcomes than
treating only established AKI. Chapter 2.2 introduced the approach to risk assessment
with further detail provided in Appendix C. This chapter will concern itself with
the evaluation and general management of patients with, or even at risk for, AKI.
Further detail is provided in Appendix D. We highlight the importance of beginning
management at the earliest point in the development of AKI—in patients with suspected
AKI or even in those at increased risk who have been exposed to the various factors
discussed in Chapters 2.2 and Appendix C.
Although much of the remaining chapters in this guideline pertain to management of
specific aspects of AKI, there are general management principles that are common to
all patients and these will be discussed here and further expounded upon in Appendix
D. Treatment goals in patients with AKI include both reducing kidney injury and complications
related to decreased kidney function.
2.3.1: Evaluate patients with AKI promptly to determine the cause, with special attention
to reversible causes. (Not Graded)
2.3.2: Monitor patients with AKI with measurements of SCr and urine output to stage
the severity, according to Recommendation 2.1.2. (Not Graded)
2.3.3: Manage patients with AKI according to the stage (see Figure 4) and cause. (Not
Graded)
2.3.4: Evaluate patients 3 months after AKI for resolution, new onset, or worsening
of pre-existing CKD. (Not Graded)
If patients have CKD, manage these patients as detailed in the KDOQI CKD Guideline
(Guidelines 7–15). (Not Graded)
If patients do not have CKD, consider them to be at increased risk for CKD and care
for them as detailed in the KDOQI CKD Guideline 3 for patients at increased risk for
CKD. (Not Graded)
RATIONALE
As emphasized in Chapter 2.2, AKI is not a disease but rather a clinical syndrome
with multiple etiologies. While much of the literature examining epidemiology and
clinical consequences of AKI appear to treat this syndrome as a homogeneous disorder,
the reality is that AKI is heterogeneous and often is the result of multiple insults.
Figure 5 illustrates an approach to evaluation of AKI. Further discussion of evaluation
in clinical practice is provided in Appendix D.
The clinical evaluation of AKI includes a careful history and physical examination.
Drug history should include over-the-counter formulations and herbal remedies or recreational
drugs. The social history should include exposure to tropical diseases (e.g., malaria),
waterways or sewage systems, and exposure to rodents (e.g., leptospirosis, hantavirus).
Physical examination should include evaluation of fluid status, signs for acute and
chronic heart failure, infection, and sepsis.
Measurement of cardiac output, preload, preload responsiveness, and intra-abdominal
pressure should be considered in the appropriate clinical context. Laboratory parameters—including
SCr, blood urea nitrogen (BUN), and electrolytes, complete blood count and differential—should
be obtained. Urine analysis and microscopic examination as well as urinary chemistries
may be helpful in determining the underlying cause of AKI. Imaging tests, especially
ultrasound, are important components of the evaluation for patients with AKI. Finally,
a number of biomarkers of functional change and cellular damage are under evaluation
for early diagnosis, risk assessment for, and prognosis of AKI (see Appendix D for
detailed discussion).
Individualize frequency and duration of monitoring based on patient risk, exposure
and clinical course. Stage is a predictor of the risk for mortality and decreased
kidney function (see Chapter 2.4). Dependent on the stage, the intensity of future
preventive measures and therapy should be performed.
Because the stage of AKI has clearly been shown to correlate with short-term
2, 5, 27, 29
and even longer-term outcomes,
31
it is advisable to tailor management to AKI stage. Figure 4 lists a set of actions
that should be considered for patients with AKI. Note that for patients at increased
risk (see Chapters 2.2 and 2.4), these actions actually begin even before AKI is diagnosed.
Note that management and diagnostic steps are both included in Figure 4. This is because
response to therapy is an important part of the diagnostic approach. There are few
specific tests to establish the etiology of AKI. However, a patient's response to
treatment (e.g., discontinuation of a possible nephrotoxic agent) provides important
information as to the diagnosis.
Nephrotoxic drugs account for some part of AKI in 20–30% of patients. Often, agents
like antimicrobials (e.g., aminoglycosides, amphotericin) and radiocontrast are used
in patients that are already at high risk for AKI (e.g., critically ill patients with
sepsis). Thus, it is often difficult to discern exactly what contribution these agents
have on the overall course of AKI. Nevertheless, it seems prudent to limit exposure
to these agents whenever possible and to weigh the risk of developing or worsening
AKI against the risk associated with not using the agent. For example, when alternative
therapies or diagnostic approaches are available they should be considered.
In order to ensure adequate circulating blood volume, it is sometimes necessary to
obtain hemodynamic variables. Static variables like central venous pressure are not
nearly as useful as dynamic variables, such as pulse-pressure variation, inferior
vena cava filling by ultrasound and echocardiographic appearance of the heart (see
also Appendix D).
Note that while the actions listed in Figure 4 provide an overall starting point for
stage-based evaluation and management, they are neither complete not mandatory for
an individual patient. For example, the measurement of urine output does not imply
that the urinary bladder catheterization is mandatory for all patients, and clinicians
should balance the risks of any procedures with the benefits. Furthermore, clinicians
must individualize care decisions based on the totality of the clinical situation.
However, it is advisable to include AKI stage in these decisions.
The evaluation and management of patients with AKI requires attention to cause and
stage of AKI, as well as factors that relate to further injury to the kidney, or complications
from decreased kidney function. Since AKI is a risk factor for CKD, it is important
to evaluate patients with AKI for new onset or worsening of pre-existing CKD. If patients
have CKD, manage patients as detailed in the KDOQI CKD Guideline (Guidelines 7–15).
If patients do not have CKD, consider them to be at increased risk for CKD and care
for them as detailed in the KDOQI CKD Guideline 3 for patients at increased risk for
CKD.
RESEARCH RECOMMENDATIONS
Clinical research aimed at testing early management strategies is urgently needed.
Such trials should also address the risks and benefits of commonly used fluid-management
strategies, including intravenous (i.v.) fluids and diuretics.
Methods to better assess fluid status in critically ill and other hospitalized patients
at risk for AKI are needed.
Research is needed, with follow-up beyond hospital stay, to better understand the
clinical consequences of AKI in patients with and without underlying CKD.
Chapter 2.4: Clinical applications
This chapter provides a detailed application of the AKI definition and staging for
clinical diagnosis and management. The definitions and classification system discussed
in Chapter 2.1 can be used easily in many patients and requires little clinical interpretation.
However, in real time, clinicians do not always have a complete dataset to work with
and individual patients present with unique histories. As discussed in the previous
chapter, it is difficult to distinguish AKI from CKD in many cases. In addition, as
many as two-thirds of all cases of AKI begin prior to hospitalization (community-acquired
AKI). Therefore, clinicians may be faced with patients in whom kidney function is
already decreased and, during the hospitalization, improves rather than worsens. Finally,
many patients do not have a prior measurement of kidney function available for comparison.
This chapter provides detailed examples of the application of these definitions to
the clinical setting.
Examples of application of AKI definitions
Table 7 illustrates a number of examples whereby patients presenting with possible
AKI can be diagnosed. Cases A-F have a measurement of baseline SCr. To simplify decision-making,
baseline estimated glomerular filtration rate (eGFR) exceeds 60 ml/min per 1.73 m
2
in these patients, so none has pre-existing CKD. Cases A-F can all be diagnosed with
AKI by applying the first two criteria in Recommendation 2.1.1. (a documented increase
of at least 0.3 mg/dl (>26.5 μmol/l) [within 48 hours or a 50% increase from presumed
baseline). Note that a patient can be diagnosed with AKI by fulfilling either criterion
1 or 2 (or 3, urine output) and thus cases B,C,D, and F all fulfill the definition
of AKI. Note also that patients may be diagnosed earlier using criterion 1 or 2. Early
diagnosis may improve outcome so it is advantageous to diagnose patients as rapidly
as possible. For example, case A can be diagnosed with AKI on day 2 by the first criterion,
whereas the second criterion is not satisfied until day 3 (increase from 1.3 to 1.9).
However, this is only true because the episode of AKI began prior to medical attention,
and thus the day 1 SCr level was already increased. If creatinine measurements had
available with 48 hours prior to day 1 and if this level had been at baseline (1.0 mg/dl
[88.4 μmol/l]), it would have been possible to diagnose AKI on day 1 using the second
criterion.
Cases F-H do not have a baseline measurement of SCr available. Elevated SCr (reduced
eGFR) on day 1 of the hospitalization is consistent with either CKD or AKD without
AKI. In Case F, baseline SCr can be inferred to be below the day 1 value because of
the subsequent clinical course; thus, we can infer the patient has had an episode
of AKI. In case G, AKI can be diagnosed by application of criterion 2, but the patient
may have underlying CKD. Case H does not fulfill the definition for AKI based on either
criteria, and has either CKD or AKD without AKI.
The example of Case A raises several important issues. First, frequent monitoring
of SCr in patients at increased risk of AKI will significantly improve diagnostic
time and accuracy. If Case A had not presented to medical attention (or if SCr had
not been checked) until day 7, the case of AKI would likely have been missed. Frequent
measurement of SCr in high-risk patients, or in patients in which AKI is suspected,
is therefore encouraged—see Chapter 2.3. The second issue highlighted by Case A is
the importance of baseline SCr measurements. Had no baseline been available it would
still have been possible to diagnose AKI on day 3 (by either using criterion 2 or
by using criterion 1 and accepting the baseline SCr as 1.3); however, not only would
this have resulted in a delay in diagnosis, it would have resulted in a delay in staging
(see Table 7). On day 7, it can be inferred that the patient's baseline was no higher
than 1.0 mg/dl (88 μmol/l) and thus correct staging of Case A as Stage 2 (two-fold
increase from the reference SCr, see below and Table 7) on day 3 could have been determined
in retrospect. However, if a baseline SCr was available to use as the reference, the
correct stage could be determined on day 3.
Case B illustrates why criterion 2 can detect cases of AKI missed by criterion 1.
It also clarifies why these cases are unusual. Had the SCr increased to 1.5 mg/dl
(132.6 μmol/l) as opposed to peaking at 1.4 mg/dl (123.8 μmol/l), it would have been
picked up by criterion 1 as well. By contrast Cases C, D, and even F illustrate how
criterion 2 may miss cases identified by criterion 1. Note that Case F can only be
diagnosed by inference. By day 7, it can be inferred that the baseline was no higher
than 1.0 mg/dl (88 μmol/l) and thus it can be determined that the patient presented
with AKI. However, if the baseline SCr could be estimated it would be possible to
make this inference as early as day 1.
Estimating baseline SCr
Many patients will present with AKI without a reliable baseline SCr on record. Baseline
SCr can be estimated using the Modification of Diet in Renal Disease (MDRD) Study
equation assuming that baseline eGFR is 75 ml/min per 1.73 m
2
(Table 9).
22
This approach has been used in many, but not all, studies of AKI epidemiology using
RIFLE
2, 5, 25, 30, 31, 32, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63
(see Table 8) and has recently been validated.
64
Hence, most current data concerning AKI defined by RIFLE criteria are based on estimated
baseline SCr for a large proportion of patients.
Table 9 shows the range of estimated SCr obtained by back-calculation for various
age, sex, and race categories. When the baseline SCr is unknown, an estimated SCr
can be used provided there is no evidence of CKD (see Appendix B). Fortunately, when
there is a history of CKD, a baseline SCr is usually available. Unfortunately, many
cases of CKD are not identified, and thus estimating the baseline SCr may risk labeling
a patient with AKI when in reality the diagnosis was unidentified CKD. As discussed
further in Appendix B, it is essential to evaluate a patient with presumed AKI for
presence of CKD. Furthermore, CKD and AKI may coexist. By using all available clinical
data (laboratory, imaging, history, and physical exam) it should be possible to arrive
at both an accurate diagnosis as well as an accurate estimate of baseline SCr. Importantly,
excluding some cases of hemodilution secondary to massive fluid resuscitation (discussed
below), the lowest SCr obtained during a hospitalization is usually equal to or greater
than the baseline. This SCr should be used to diagnose (and stage) AKI. For example,
if no baseline SCr was available in Case A, diagnosis of AKI could be made using the
MDRD estimated SCr (Table 9). If Case A were a 70-year-old white female with no evidence
or history of CKD, the baseline SCr would be 0.8 mg/dl (71 μmol/l) and a diagnosis
of AKI would be possible even on day 1 (criterion 1, ⩾50% increase from baseline).
However, if the patient was a 20-year-old black male, his baseline SCr would be estimated
at 1.5 mg/dl (133 μmol/l). Since his admission SCr is lower, this is assumed to be
the baseline SCr until day 7 when he returns to his true baseline, and this value
can be taken as the baseline. These dynamic changes in interpretation are not seen
in epidemiologic studies, which are conducted when all the data are present, but are
common in clinical medicine. Note that the only way to diagnose AKI (by SCr criteria)
in Case H is to use an estimated SCr.
Examples of application of AKI stages
Once a diagnosis of AKI has been made, the next step is to stage it (Recommendation
2.1.2). Like diagnosis, staging requires reference to a baseline SCr when SCr criteria
are used. This baseline becomes the reference SCr for staging purposes. Table 10 shows
the maximum stage for each Case described in Table 7. Staging for Case A was already
mentioned. The maximum stage is 2 because reference SCr is 1.0 mg/dl (88 μmol/l) and
the maximum SCr is 2.0 mg/dl (177 μmol/l). Had the reference SCr been 0.6 mg/dl (53 μmol/l),
the maximum stage would have been 3. Case F was staged by using the lowest SCr (1.0 mg/dl
[88 μmol/l]) as the reference. Of course, the actual baseline for this case might
have been lower but this would not affect the stage, since it is already Stage 3.
Note that if this patient was a 35-year-old white male, his MDRD estimated baseline
SCr would be 1.2 mg/dl (106 μmol/l) (Table 9) and his initial stage on admission (day
1) would be assumed to be 2. However, once his SCr recovered to 1.0 mg/dl (88 μmol/l)
on day 7, it would be possible to restage him as having had Stage 3. Once he has recovered,
there may be no difference between Stage 2 or 3 in terms of his care plan. On the
other hand, accurately staging the severity of AKI may be important for intensity
of follow-up and future risk.
Note that Cases G and H can only be staged if the reference SCr can be inferred. Case
G may be as mild as stage 1 if the baseline is equal to the nadir SCr on day 7. On
the other hand, if this case were a 70-year-old white female with no known evidence
or history of CKD, the reference SCr would be 0.8 mg/dl (71 μmol/l) based on an estimated
baseline (Table 9). In this case, the severity on day 1 would already be stage 2.
Urine output vs. SCr
Both urine output and SCr are used as measures of an acute change in GFR. The theoretical
advantage of urine output over SCr is the speed of the response. For example, if GFR
were to suddenly fall to zero, a rise in SCr would not be detectable for several hours.
On the other hand, urine output would be affected immediately. Less is known about
the use of urine output for diagnosis and staging compared to SCr, since administrative
databases usually do not capture urine output (and frequently it is not even measured,
especially outside the ICU). However, studies using both SCr and urine output to diagnose
AKI show increased incidence, suggesting that the use of SCr alone may miss many patients.
The use of urine output criteria (criterion 3) will also reduce the number of cases
where criterion 1 and criterion 2 are discordant (cases B,C,D, and F in Table 7),
as many of these cases will be picked up by urine output criteria.
Timeframe for diagnosis and staging
The purpose of setting a timeframe for diagnosis of AKI is to clarify the meaning
of the word “acute”. A disease process that results in a change in SCr over many weeks
is not AKI (though it may still be an important clinical entity: see Appendix B).
For the purpose of this guideline, AKI is defined in terms of a process that results
in a 50% increase in SCr within 1 week or a 0.3 mg/dl (26.5 μmol/l) increase within
48 hours (Recommendation 2.1.1). Importantly, there is no stipulation as to when the
1-week or 48-hour time periods can occur. It is stated unequivocally that it does
not need to be the first week or 48 hours of a hospital or ICU stay. Neither does
the time window refer to duration of the inciting event. For example, a patient may
have a 2-week course of sepsis but only develop AKI in the second week. Importantly,
the 1-week or 48-hour timeframe is for diagnosis of AKI, not staging. A patient can
be staged over the entire episode of AKI such that, if a patient develops a 50% increase
in SCr in 5 days but ultimately has a three-fold increase over 3 weeks, he or she
would be diagnosed with AKI and ultimately staged as Stage 3.
As with any clinical criteria, the timeframe for AKI is somewhat arbitrary. For example,
a disease process that results in a 50% increase in SCr over 2 weeks would not fulfill
diagnostic criteria for AKI even if it ultimately resulted in complete loss of kidney
function. Similarly, a slow process that resulted in a steady rise in SCr over 2 weeks,
and then a sudden increase of 0.3 mg/dl (26.5 μmol/l) in a 48-hour period, would be
classified as AKI. Such are the inevitable vagaries of any disease classification.
However, one scenario deserves specific mention, and that is the case of the patient
with an increased SCr at presentation. As already discussed, the diagnosis of AKI
requires a second SCr value for comparison. This SCr could be a second measured SCr
obtained within 48 hours, and if it is ⩾0.3 mg/dl (⩾26.5 μmol/l) greater than the
first SCr, AKI can be diagnosed. Alternatively, the second SCr can be a baseline value
that was obtained previously or estimated from the MDRD equation (see Table 9). However,
this poses two dilemmas. First, how far back can a baseline value be retrieved and
still expected to be “valid” second, how can we infer acuity when we are seeing the
patient for the first time?
Both of these problems will require an integrated approach as well as clinical judgment.
In general, it is reasonable in patients without CKD to assume that SCr will be stable
over several months or even years, so that a SCr obtained 6 months or even 1 year
previously would reasonable reflect the patient's premorbid baseline. However, in
a patient with CKD and a slow increasing SCr over several months, it may be necessary
to extrapolate the baseline SCr based on prior data. In terms of inferring acuity
it is most reasonable to determine the course of the disease process thought to be
causing the episode of AKI. For example, for a patient with a 5-day history of fever
and cough, and chest radiograph showing an infiltrate, it would be reasonable to infer
that the clinical condition is acute. If SCr is found to be ⩾50% increased from baseline,
this fits the definition of AKI. Conversely, a patient presenting with an increased
SCr in the absence of any acute disease or nephrotoxic exposure will require evidence
of an acute process before a diagnosis can be made. Evidence that the SCr is changing
is helpful in establishing acuity.
Clinical judgment
While the definitions and classification system discussed in Chapter 2.1 provide a
framework for the clinical diagnosis of AKI, they should not be interpreted to replace
or to exclude clinical judgment. While the vast majority of cases will fit both AKI
diagnostic criteria as well as clinical judgment, AKI is still a clinical diagnosis—not
all cases of AKI will fit within the proposed definition and not all cases fitting
the definition should be diagnosed as AKI. However, exceptions should be very rare.
Pseudo-AKI
As with other clinical diagnoses defined by laboratory results (e.g., hyponatremia),
the clinician must be cautious to interpret laboratory data in the clinical context.
The most obvious example is with laboratory errors or errors in reporting. Erroneous
laboratory values should obviously not be used to diagnose disease and suspicious
lab results should always be repeated. Another example is when two SCr measurements
are obtained by different laboratories. While the coefficient of variation for SCr
is very small (<5%) by various clinical testing methods, variation (bias) from one
laboratory to the next may be considerably higher, although it is unlikely to approach
50%. Given that the SCr definition of AKI always uses at least two values, the variation
and bias between each measure is further magnified—the coefficient of variation for
comparison of two lab tests is equal to the square root of the sum of each coefficient
squared. Although the international standardization of SCr measurements will largely
eliminate interlaboratory bias in the future, care is needed in interpreting lab values
obtained from different labs. Furthermore, daily variation in SCr due to differences
in diet and activity may be as great as 10%. Finally, endogenous chromogens (e.g.,
bilirubin, ascorbic acid, uric acid) and exogenous chromogens and drugs (e.g., cephalosporins,
trimethoprim, cimetidine) may interfere with the creatinine assay. The cumulative
effect of these various factors influencing precision, bias, and biological variation
may approach the level at which it could impact the diagnosis of AKI. A similar problem
exists with urine output. Particularly outside the ICU, urine output is not often
reported and urine collections may be inaccurate, especially in noncatheterized patients.
Finally, as discussed in Chapter 2.1, a weight-based criterion for urine output will
mean that some very obese patients will fulfill the definition of AKI without any
kidney abnormality. Clinical judgment should always be exercised in interpreting such
data.
Atypical AKI
A complementary problem to pseudo-AKI is the situation where a case of AKI fails to
meet the definition. These cases should be distinguished from conditions in which
data are simply missing (discussed above) and refer to situations in which existing
data are unreliable. For example, a patient might receive very large quantities of
intravascular fluids such that SCr is falsely lowered.
65
Similarly, massive blood transfusions will result in the SCr more closely reflecting
the kidney function of the blood donors than the patient. It is unusual for these
cases not to result in oliguria and, thus, most patients will be diagnosed with AKI
even if SCr is not increased. Nevertheless, the clinician should be cognizant of possibility
that SCr may be falsely lowered by large-volume fluid resuscitation or transfusion;
thus, a normal value may not rule out AKI. Changes in creatinine production are also
well known in conditions such as muscle breakdown where production increases and in
muscle wasting (including advanced liver disease) where production is decreased. Creatinine
production may also be decreased in sepsis
66
possibly due to decreased muscle perfusion.
Chapter 2.5: Diagnostic approach to alterations in kidney function and structure
Definitions of AKI, CKD and AKD
AKI and CKD were defined by separate Work Groups according to different criteria.
The definition for each is based on alterations in kidney function or structure. AKI
and CKD have many causes which may lead to alterations of kidney function and structure
that do not meet the criteria for the definition of either AKI or CKD, yet patients
with these diseases and disorders may need medical attention to restore kidney function
and reverse damage to kidney structure to avoid adverse outcomes. A uniform and systematic
nomenclature could enhance understanding and communication about these diseases and
disorders, and lead to improved medical care, research, and public health. For these
reasons, the Work Group proposed an operational definition for AKD to provide an integrated
clinical approach to patients with abnormalities of kidney function and structure.
Table 11 compares the definitions for AKI, CKD, and AKD. We have also included an
operational definition of “no known kidney disease” (NKD) for those who do not meet
these criteria, with the understanding that clinical judgment is required to determine
the extent of the evaluation that is necessary to assess kidney function and structure.
In the following sections, we will elaborate on each component of these definitions.
GFR and SCr
CKD, AKD, and AKI are defined by parameters expressing the level of kidney function.
Table 12 gives examples of each condition based on GFR and different magnitudes of
increase in SCr.
To illustrate the relationship of changes in SCr to changes in eGFR, we simulated
changes in eGFR that would result from changes in SCr corresponding to the KDIGO definition
of AKI in the Chronic Kidney Disease Epidemiology Collaboration cohort.
67, 68
Figure 6 shows the relationship of these changes in eGFR to the definition and stages
of AKI. Not all patients with AKI would meet the eGFR criteria for the definition
of AKD.
GFR/SCr algorithm
Figure 7 provides a diagnostic algorithm based on a sequential approach through three
questions: i) Is GFR decreased or is SCr increased (according to the criteria in Table
12)?; ii) Is SCr increasing or GFR decreasing (according to the criteria in Table
12)?; and iii) Does the decrease in GFR or increase in SCr resolve within 3 months?
Based on a “yes” or “no” response to these three sequential questions, all combinations
of AKI, AKD, and CKD can be identified. In this section, we review the algorithm and
illustrate its use for classification of patients with acute and chronic kidney disease
in two previously reported cohorts.
The answer to Question 1 requires ascertainment of an index GFR/SCr as well during
the prior 3 months. The index GFR/SCr can be assigned as any of the GFR/SCr measures
during the interval of observation. The answer classifies patients into three categories:
NKD, AKD, and CKD. Question 2 requires repeat ascertainment of kidney function after
the index measure. “No” indicates that the increase in SCr or decrease in GFR after
the index measure does not meet AKI or AKD criteria; “Yes-D” indicates that increase
in SCr and decrease in GFR meets the AKD criteria but not AKI criteria; and “Yes-I”
indicates that increase in SCr meets AKI criteria. Question 3 requires repeat ascertainment
of GFR/SCr 3 months after the index measure. “Yes” indicates GFR >60, indicating NKD.
No indicates GFR <60, and based on prior level of GFR, may indicate stable, new, or
worse CKD.
Oliguria as a measure of kidney function
Although urine flow rate is a poor measure of kidney function, oliguria generally
reflects a decreased GFR. If GFR is normal (approximately 125 ml/min, corresponding
to approximately 107 ml/kg/h for a 70-kg adult), then reduction in urine volume to
<0.5 ml/kg/h would reflect reabsorption of more than 99.5% of glomerular filtrate.
Such profound stimulation of tubular reabsorption usually accompanies circulatory
disturbances associated with decreased GFR. Oliguria is unusual in the presence of
a normal GFR and is usually associated with the non–steady state of solute balance
and rising SCr sufficient to achieve the criteria for AKI. As a corollary, if GFR
and SCr are normal and stable over an interval of 24 hours, it is generally not necessary
to measure urine flow rate in order to assess kidney function.
In principle, oliguria (as defined by the criteria for AKI) can occur without a decrease
in GFR. For example, low intake of fluid and solute could lead to urine volume of
less than 0.5 ml/kg/h for 6 hours or 0.3 ml/kg/h for 24 hours. On the other hand,
severe GFR reduction in CKD usually does not lead to oliguria until after the initiation
of dialysis.
As described in Chapter 2.1, the thresholds for urine flow for the definition of AKI
have been derived empirically and are less well substantiated than the thresholds
for increase in SCr. Urinary diagnostic indices, such as the urinary concentrations
of sodium and creatinine and the fractional reabsorption of sodium and urea, remain
helpful to distinguish among causes of AKI, but are not used in the definition (see
Appendix D).
Kidney damage
Table 13 describes measures of kidney damage in AKD and CKD. Kidney damage is most
commonly ascertained by urinary markers and imaging studies. Most markers and abnormal
images can indicate AKD or CKD, based on the duration of abnormality. One notable
exception is small kidneys, either bilateral or unilateral, indicating CKD, which
are discussed separately below. Kidney damage is not a criterion for AKI; however,
it may be present. Renal tubular epithelial cells and coarse granular casts, often
pigmented and described as “muddy brown”, remain helpful in distinguishing the cause
of AKI, but are not part of the definition.
Small kidneys as a marker of kidney damage
Loss of renal cortex is considered a feature of CKD, and is often sought as a specific
diagnostic sign of CKD. Kidney size is most often evaluated by ultrasound. In a study
of 665 normal volunteers,
69
median renal lengths were 11.2 cm on the left side and 10.9 cm on the right side.
Renal size decreased with age, almost entirely because of parenchymal reduction. The
lowest 10th percentiles for length of the left and right kidney were approximately
10.5 and 10.0 cm, respectively, at age 30 years, and 9.5 and 9.0 cm, respectively,
at age 70 years.
Integrated approach to AKI, AKD, and CKD
Clinical evaluation is necessary for all patients with alterations in kidney function
or structure. The expectation of the Work Group is that the diagnostic approach will
usually begin with assessment of GFR and SCr. However, evaluation of kidney function
and structure is not complete unless markers of kidney damage—including urinalysis,
examination of the urinary sediment, and imaging studies—have been performed. Table
14 shows a summary of the diagnostic approach using measures for kidney function and
structure. Based on interpretation of each measure separately, the clinical diagnosis
indicated by an “X” can be reached.
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KDIGO gratefully acknowledges the following sponsors that make our initiatives possible:
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and Wyeth. KDIGO is supported by a consortium of sponsors and no funding is accepted
for the development of specific guidelines.
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