Clinical Utility of Stewart's Method in Diagnosis and Management of Acid-Base Disorders

Asghar Rastegar

doi:10.2215/CJN.01820309

This article has a correction. Please see:

Erratum - August 01, 2010

Abstract

For the past 5 decades, a bicarbonate-based approach has been the dominant method used for the diagnosis and treatment of acid-base disorders. This approach, however, has been criticized by some as (1) qualitative and not quantitative in nature and (2) incapable of detecting important diagnoses. Stewart, using principals of electroneutrality and conservation of mass, developed a “new” approach to the diagnosis and management of these disorders. The proponents of Stewart's approach believe that it not only offers a mechanistic explanation for the disorders but also provides the tool to make a more accurate diagnosis. Although Stewart's approach has been largely ignored by nephrologists and renal physiologists, it is increasingly used by anesthesiologists and intensivists. This review discusses the clinical utility of Stewart's method compared with the traditional bicarbonate-based approach. Although Stewart's method proposes a different, however not new, approach, it does not improve our ability to diagnose more accurately or manage these disorders. Stewart's method also does not provide the tool to prognosticate any better than the traditional method.

Peter Stewart, a biochemist at Brown University, published his seminal work on acid-base disorders in an article in 1978 and as a book in 1981 (1,2). Using fundamental biochemical and mathematical concepts, Stewart challenged the traditional bicarbonate-based method of diagnosing and treating acid-base disorders and proposed an approach based primarily on charge differences between strong cations and anions. This approach, however, did not attract much attention until the early 1990s, when it was simplified by several investigators to allow its use in clinical setting (3–6). This was followed by publication of a number of studies comparing the utility of the traditional and Stewart's approaches as a diagnostic and prognostic tool. It is interesting that until recently, Stewart's method has been largely ignored by nephrologists and renal physiologists, with only a rare article appearing in renal journals (7,8). This, however, should change as Stewart's method is increasingly used in clinical settings where nephrologists work side by side with intensivists and anesthesiologists who routinely use this method. Nephrologists should be familiar with Stewart's contribution to our understanding of acid-base disorders and its utility in clinical setting.

A recent article discussed the mathematical and biochemical basis of Stewart's method in detail and challenged the basic concept that Stewart has created a new paradigm (8), a paradigm that is compared by some to Copernicus's discovering that Earth rotates around the sun and not vice versa (9)! In addition, it challenges the claim that Stewart's approach provides a mechanistic explanation for acid-base disorders (8). This review will not deal with this issue, and readers who are interested in a more in-depth understanding of the biochemical and mathematical basis of Stewart's method are referred to this (8) as well as other reviews (3,4,6,7). This review focuses primarily on the clinical utility of Stewart's method, assessing its strengths and weaknesses as a diagnostic and prognostic tool. To do so, a brief history of key events leading to the development of the present approach to acid-base disturbances is in order. Table 1 summarizes the definition of key terms as well as abbreviations used in this article.

View this table:

Table 1.

Definitions and abbreviations^a

Historical Review of Approach to Clinical Acid-Base Disorders

The modern era of acid-base began in 1910 with Lapworth's suggestion that hydrogen was the “universal acid” (10). This was extended by the work of Lowry in Cambridge (11) and Brönsted in Copenhagen (12), who defined an acid as a substance that is capable of donating hydrogen to and base as one capable of accepting hydrogen from a solution. This definition helped explain the natural avidity of acid and base and the role of weak acids and their salt in creation of buffer systems. Henderson (13) was first to recognize the unique role that bicarbonate-carbonic acid buffer system plays in stabilizing the acid-base equilibrium in body fluid. This led to the development of the Henderson-Hasselbalch formula: $\text{[math]}$ which became the foundation for future advances in this field. The clinical application of this formula was greatly advanced by Hasselbalch's invention of an electrode capable of measuring H ion concentration in body fluids (14).

Beginning in the second decade of the 20th century, Van Slyke and Peters as well as other investigators helped to develop the bicarbonate-based approach to acid-base disorders (15). This approach was slightly modified by other investigators through the introduction of base excess (BE) and base deficit (BD) to quantify changes in bicarbonate concentration secondary to metabolic disorders (16,17). The use of BE and BD was criticized, however, because it represented measurements done on whole blood and did not accurately represent the whole-body behavior. This could lead to erroneous diagnosis, especially in patients with chronic respiratory acidosis, for whom the compensatory elevation in bicarbonate could be misdiagnosed as primary metabolic alkalosis (18). This criticism resulted in what was termed the “great transatlantic debate” between Copenhagen and Boston schools and the introduction of standard BE (SBE) and standard BD (SBD) to account for whole-body response to alterations in Pco₂ (19). Interesting, whereas BD and BE are used clinically by intensivists and anesthesiologists, they are rarely used by nephrologists and renal physiologists. In this article, the term traditional approach is used to encompass both the original bicarbonate-base approach and its modification using BE and BD.

The traditional approach is based on the centrality of H ion concentration and its dependence on the concentration of whole-body buffers as represented by bicarbonate and carbonic acid. Several investigators including Peters and Van Slyke, although accepting Henderson-Hasselbalch's formula, believed that a “more complete description of the acid-base balance should include concentration of all of the anions and cations” (20). In the late 1940s, Singer and Hasting presented their acid-base nomogram and introduced the concept of buffer base (BB) as the difference between all of the cations (termed total base) and anions (termed total fixed acid) (16). On the basis of this terminology, cations such as sodium, potassium, and calcium are considered to be base and anions such as chloride and phosphate to be acid. This concept, discarded by basic chemists decades before, was challenged by several investigators and was finally abandoned by clinical chemists (21,22). During the next 2 decades, the traditional approach gained greater strength through the publication of many well-designed studies that defined the clinical and biochemical parameters that are critical to the diagnosis and management of acid-base disorders. These parameters became the foundations of our approach to clinical acid-base disorders for the past 4 decades (23).

Stewart's Approach to Acid-Base Disorders

As indicated, the traditional approach has been criticized as (1) descriptive rather than mechanistic in nature and (2) limited in scope and therefore unable to make complete diagnosis in patients with complex disorders. In contrast, proponents of Stewart's approach believe it to be mechanistic in nature and comprehensive in scope, able to detect important hidden disorders (6,24). The fundamental underpinning of Stewart's approach is the concept of independent and dependent variables in acid-base homeostasis. According to Stewart, “Independent variables in any system are those which can be directly altered from outside the system without affecting each other” and “…dependent variables in a system can be thought of as internal to the system. Their values represent the system's reaction to the externally imposed values of the independent variables.” (1). Using principals of conservation of mass, electrical neutrality, and dissociation constant of partially dissociated weak electrolytes, Stewart derived the following fourth-order polynomial formula for H concentration in a fluid compartment containing bicarbonate and CO₂: $\text{[math]}$ where strong ion difference (SID) is the difference between strong cations and anions in solution: $\text{[math]}$ and A_TOT reflects the concentration of total weak acid in solution: $\text{[math]}$

On the basis of Stewart's definition, H⁺ and bicarbonate are dependent variables whose concentrations are determined by the three independent variables, namely SID, Pco₂, and A_TOT. Although the mathematical basis of Stewart's formula has not been challenged, this alone does not prove causality, which must be proved through empirical observations (8).

In Stewart's approach, similar to the traditional approach, respiratory disorders are those that are due to a primary alterations in Pco₂. Metabolic disorders, however, are due to primary alterations in SID or A_TOT and not bicarbonate. By the law of electroneutrality: $\text{[math]}$

This formula can be rearranged as follows: $\text{[math]}$ Therefore, $\text{[math]}$

Under normal conditions, concentration of lactate and other strong ions is very low and can be ignored. The formula could therefore be simplified to $\text{[math]}$

SID therefore can be calculated as the difference between fully dissociated cations and anions or sum of bicarbonate and A⁻ where A⁻ represents total charges contributed by all nonbicarbonate buffers, primarily albumin, phosphate, and, in whole blood, hemoglobin (Figure 1). SID is therefore the same as buffer base concept introduced by Singer and Hasting more than 5 decades ago (16).

Figure 1.

Relationship between SID, anion gap (AG), and bicarbonate in normal individuals.

When an abnormal anion is present, a gap will appear between SID calculated by the difference between strong ions (the so-called “apparent SID”) and calculated by the addition of bicarbonate and nonbicarbonate buffers (so called “effective SID”; Figure 2). This difference, named strong ion gap (SIG), is a marker for the presence of an abnormal anion (25).

Figure 2.

Relationship between strong ion gap (SIG) and ΔAG.

Anion gap (AG) is also calculated on the basis of the principal of electroneutrality as shown as follows: $\text{[math]}$

This can be rearranged as: $\text{[math]}$

In normal state, plasma unmeasured anions reflect charges contributed by the nonbicarbonate anions (A⁻), primarily albumin and phosphate. The unmeasured cations are primarily made up of calcium, magnesium, and, depending on the formula used, potassium. ΔAG, the difference between the abnormal and normal (or baseline) AG, represents the amount of abnormal anion(s) present in plasma. SIG, as pointed out already, also represents the amount of abnormal anion(s) present in plasma and is expected to be mathematically equal to ΔAG (Figure 2). Moviat et al. (26) in studying 50 consecutive patients with metabolic acidosis (defined as BD >5 mM) documented a tight correlation between SIG and ΔAG corrected for albumin and lactate (r = 0.9344; Figure 3). This relationship could have been even stronger if ΔAG were calculated in a more precise manner by using actual baseline values for AG in each patient rather than the mean value of 12 (27). It should be clear from this discussion that specific components of Stewart's formulas, such as SID and SIG, are conceptually and mathematically closely related to specific components of traditional formulas such as bicarbonate, AG, and ΔAG. To help the reader become familiar with the application of commonly used formulas, the appendix summarizes the basic data and pertinent calculations on a patient evaluated by both methods.

Figure 3.

Relationship between ΔAG and SIG. AG was corrected for albumin and lactate. SIG was also calculated correcting apparent SID for lactate. Reprinted from reference (26), with permission.

View this table:

Table 2.

Classification of primary acid-base disturbances^a

View this table:

Table 3.

Summary of studies comparing the prognostic power of the traditional and Stewart's approach^a

View this table:

Appendix.

Data from a patient who developed urosepsis resulting in lactic acidosis and acute kidney injury^a

Clinical Application of Stewart's approach

Classification of Acid-Base Disorders

One important goal of any method used to analyze acid-base disorders is to develop a clinically useful classification. The traditional approach, using a robust body of empirical observations, has developed a classification that contains six primary disorders: Metabolic acidosis, metabolic alkalosis, acute and chronic respiratory acidosis, and acute and chronic respiratory alkalosis. Metabolic acidosis can further be classified as anion gap or hyperchloremic acidosis. In addition, by using compensatory formulas as well as ΔAG, the traditional approach is capable of diagnosing complex acid-base disorders (28). In Stewart's approach, classification of acid-base disorders is based on changes in the three “independent” variables (Table 2) (29). Respiratory disorders, as in the traditional approach, are due to a change in Pco₂, whereas metabolic disorders are due to alterations in either SID or A_TOT. SID is decreased in metabolic acidosis and increased in metabolic alkalosis. By calculating SIG, one can further classify metabolic acidosis. In hyperchloremic metabolic acidosis, both effective and apparent SID decrease equally, as the increase in chloride is counterbalanced by an equal decrease in the bicarbonate concentration. SIG therefore remains at or near 0. In AG metabolic acidosis, apparent SID does not change (as chloride concentration is unchanged), but effective SID decreases (as a result of a decrease in bicarbonate concentration) and SIG therefore becomes positive (29). One major departure from the traditional approach is classification of acid-base disorders as a result of alteration in A_TOT. A_TOT, representing all nonbicarbonate buffers pairs (HA + A⁻), is made up of charges contributed primarily by serum proteins (mainly albumin) with phosphate and other buffers playing a minor role. On the basis of this classification, an increase in serum protein would result in metabolic acidosis and a decrease, metabolic alkalosis (see next section) (29,30).

Clinical Utility of Stewart's Approach in Diagnosing Acid-Base Disorders

In addition to proposed disorders as a result of alterations in A_TOT, the major practical difference between Stewart's and the traditional approach is the use of SID and SIG instead of bicarbonate and AG in the diagnosis of metabolic disorders. As pointed out already, these four variables all are interrelated, but the question remains: “Does Stewart's method uncover disorders that are not diagnosed by the use of the traditional method?” In a study of 152 intensive care unit (ICU) patients, 96% of whom had severe hypoalbuminemia (serum albumin concentration below the mean by 3 SD), Stewart's method uncovered underlying metabolic acidosis in 20 patients with normal BE and 22 patients with normal bicarbonate (29). The authors believe that the normal BE or bicarbonate was due to the presence of a counterbalancing hypoalbuminemic alkalosis. It is important to note, however, that in these patients, use of AG corrected for hypoalbuminemia also leads to the correct diagnosis of mixed metabolic acidosis and alkalosis (29). In a prospective observational study of 935 ICU patients, Stewart's method detected metabolic disorders in 131 (14%) patients with normal bicarbonate and BE, whereas the traditional method made a similar diagnosis in 108 (13%) patients. Stewart's method, however, failed to make an important acid-base diagnosis in 27 (3%) patients compared with the traditional method using corrected AG (31). In another study, 2152 complete sets of laboratory tests in 427 trauma patients were analyzed by the two methods. There was 28% disagreement between the two methods when corrected AG was not used (32). This is similar to the finding in another report in a pediatric population, in which base excess as a result of unmeasured anion was used as a surrogate for SIG (33). In summary, if corrected AG is used, then the traditional method performs at least as well as Stewart's approach in uncovering a hidden metabolic disorder.

The role of hypoalbuminemia in the development of acid-base disorders deserves a comment. One report presents eight ICU patients with near-normal renal function and elevated serum bicarbonate concentration (mean 31.3 ± 1.6 mM) but normal concentration of sodium, chloride, and appropriately low AG. Although other causes of metabolic alkalosis were not ruled out, it was assumed that this disorder was due to a decrease in total weak acid secondary to hypoalbuminemia (33). In contrast, in another study, among 935 ICU patients, only one patient was thought to have hypoalbuminemic alkalosis (31). In an in vitro experiment, a decrease in serum albumin from 4.7 to 2.8 g%, while maintaining constant Pco₂, resulted in an increase in serum bicarbonate from 23.9 to 29.6 mM, whereas an increase in serum albumin to 6.6 resulted in a drop in serum bicarbonate to 19.2 mM (34). This study has been criticized for the use of whole blood rather than plasma and addition of diluting fluid with high bicarbonate content. In addition, the observed changes could be explained by the alteration in ionic strength resulting in a change in Gibbs-Donnan equilibrium and solubility as well as dissociation constant of CO₂ (8). This in vitro observation is also not supported by the clinical observation that patients with nephrotic syndrome and similar degree of hypoalbuminemia have normal serum bicarbonate concentration (35).

Prognostic Value of Stewart's Method Compared with the Traditional Method

The main goal of any proposed acid-base approach is to help clinicians make accurate diagnostic and therapeutic decisions. In this respect, as discussed, Stewart's method has not been shown to be superior to the traditional method. Many studies, however, have attempted to evaluate the ability of specific components of formulas used in either Stewart's or the traditional method in predicting meaningful clinical outcomes such as mortality (32,33,36–40). These studies, all performed on patients who were admitted to the ICU, are summarized in Table 3. As this summary shows, these studies include very different patient populations, study designs, and statistical methods and are therefore difficult to compare or combine. In addition, because most variables of interest are interconnected, these studies are able to use only univariate and not multivariate analysis. Despite these limitations, certain general conclusions can be derived:

Clinical assessment such as APACHE II, injury severity index (ISI), and pediatric index mortality (PIM) are as powerful as the laboratory assessments in predicting clinical outcomes (32,36,39),
Correction of AG for albumin significantly increases its predictive power (38,41,42),
Correction of AG for albumin and SIG, on average, performed equally well in predicting mortality (32,39,40),
In two studies, both in trauma patients, receiver operator characteristic curve for SIG and AG achieved clinically useful levels (38,40). In other studies, reported receiver operator characteristic were too low to be of clinical use.
In no study was SIG compared with ΔAG.
No studies compared the utility of Stewart's method with traditional method in diagnosing and/or managing respiratory disorders.

In general, these types of studies using either the traditional or Stewart's approach, although interesting, are of questionable clinical utility in treating these severely ill and complex patients. The outcome in such patients will depend on multiple independent clinical and laboratory variables, which may or may not include acid-base parameters. We should also recognize the limitation of standard arterial blood gas analysis in informing us about buffering by the bicarbonate system at the tissue level. As pointed out by Gowrishankar et al. (42), this limitation is partly due to the fact that arterial Pco₂, although setting the lower limit for capillary Pco₂, does not accurately reflect the tissue buffering by bicarbonate system, which is better reflected by venous Pco₂.

Conclusions

Stewart, by creating an alternative view of acid-base universe and developing its own vocabulary and formulas, has challenged the traditional approach. This has led to the development of a new classification of acid-base disorders. This approach, however, is not a paradigm shift, as claimed by its proponents, but a variation on the widely known and controversial model using ionic charge differences to analyze acid-base disorders. In addition, the key components of the Stewart's formulas are closely related to the key components of the traditional formulas. Clinically, the traditional approach is intuitive in nature and is supported by a large body of robust empirical observations. The traditional approach should be abandoned only if proponents of Stewart's approach could provide clear empirical observations supporting its superiority as a clinical tool in diagnosing and treating patients with acid-base disorders.

Disclosures

None.

Footnotes

Published online ahead of print. Publication date available at www.cjasn.org.

References

↵
Stewart PA: Independent and dependent variables of acid-base control. Resp Physiol33 :9– 26,1978
OpenUrl CrossRef PubMed
↵
Stewart PA: How to Understand Acid-Base: A Quantitative Acid-Base Primer for Biology and Medicine, New York, Elsevier,1981
↵
Constable PD: A simplified strong ion model for acid-base equilibria: Application to horse plasma. J Appl Physiol83 :297– 311,1997
OpenUrl PubMed
↵
Constable PD: Clinical assessment of acid-base status: Comparison of the Henderson-Hasselbalch and strong ion approaches. Vet Clin Pathol29 :115– 128,2000
OpenUrl PubMed
Kellum JA: Disorders of acid-base balance. Crit Care Med35 :2631– 2636,2007
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↵
Fencl V, Leith DE: Stewart's quantitative acid-base chemistry: Applications in biology and medicine. Respir Physiol91 :1– 16,1993
OpenUrl CrossRef PubMed
↵
Corey EC: Stewart and beyond: New models of acid-base balance. Kidney Int64 :777– 787,2003
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↵
Kurtz I, Kraut J, Ornekian V, Nguyen MK: Acid-base analysis: A critique of the Stewart and bicarbonate-centered approaches. Am J Physiol Renal Physiol294 :F1009– F1031,2008
OpenUrl CrossRef PubMed
↵
Kellum J: Acid Base pHorum, University of Pittsburgh, Department of Critical Care Medicine. Available at: http://www.ccm.upmc.edu/education/resources/phorum.html. Accessed April 15,2009
↵
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Kellum J: Clinical review: Reunification of acid-base physiology. Crit Care9 :500– 507,2005
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Analysis of Acid-Base Disorders in Patients With Chronic Respiratory Failure

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[1] ↵
Stewart PA: Independent and dependent variables of acid-base control. Resp Physiol33 :9– 26,1978
OpenUrl CrossRef PubMed

[2] ↵
Stewart PA: How to Understand Acid-Base: A Quantitative Acid-Base Primer for Biology and Medicine, New York, Elsevier,1981

[3] ↵
Constable PD: A simplified strong ion model for acid-base equilibria: Application to horse plasma. J Appl Physiol83 :297– 311,1997
OpenUrl PubMed

[4] ↵
Constable PD: Clinical assessment of acid-base status: Comparison of the Henderson-Hasselbalch and strong ion approaches. Vet Clin Pathol29 :115– 128,2000
OpenUrl PubMed

[5] Kellum JA: Disorders of acid-base balance. Crit Care Med35 :2631– 2636,2007
OpenUrl

[6] ↵
Fencl V, Leith DE: Stewart's quantitative acid-base chemistry: Applications in biology and medicine. Respir Physiol91 :1– 16,1993
OpenUrl CrossRef PubMed

[7] ↵
Corey EC: Stewart and beyond: New models of acid-base balance. Kidney Int64 :777– 787,2003
OpenUrl CrossRef PubMed

[8] ↵
Kurtz I, Kraut J, Ornekian V, Nguyen MK: Acid-base analysis: A critique of the Stewart and bicarbonate-centered approaches. Am J Physiol Renal Physiol294 :F1009– F1031,2008
OpenUrl CrossRef PubMed

[9] ↵
Kellum J: Acid Base pHorum, University of Pittsburgh, Department of Critical Care Medicine. Available at: http://www.ccm.upmc.edu/education/resources/phorum.html. Accessed April 15,2009

[10] ↵
Lapworth A: An examination of the conception of hydrogen ions in catalysis, salt formation, and electrolyte conduction. J Chem Soc93 :2187– 2203,1908
OpenUrl

[11] ↵
Lowry TM: The uniqueness of hydrogen. Chem Ind42 :43– 47,1923
OpenUrl CrossRef

[12] ↵
Brönsted JN: The acid base function of molecules and its dependency on the electric charge type. J Phys Chem30 :777– 790,1926
OpenUrl CrossRef

[13] ↵
Henderson LJ: The theory of neutrality regulation in the animal organism. Am J Physiol18 :427– 448,1907
OpenUrl

[14] ↵
Hasselbalch KA: The calculation of blood pH via the partition of carbon dioxide in plasma and oxygen binding of the blood as a function of plasma pH [in German]. Biochem Z78 :112– 144,1916
OpenUrl

[15] ↵
Peters JP, Van Slyke DD: Quantitative Chemistry: Volume 1—Interpretations, Baltimore, Williams & Wilkins,1932 , pp868– 997

[16] ↵
Singer RB, Hastings AB: An improved clinical method for the estimation of disturbances of the acid-base balance of human blood. Medicine27 :223– 242,1948
OpenUrl CrossRef PubMed

[17] ↵
Siggaard-Andersen O: The Acid-Base Status of Blood, 4th Ed., Copenhagen, Munksgaard,1974

[18] ↵
Schwartz WB, Relman AS: A critique of the parameters used in the evaluation of acid-base disorders “whole-blood buffer base” and “standard bicarbonate” compared with blood pH and plasma bicarbonate concentration. N Engl J Med268 :1382– 1388,1963
OpenUrl PubMed

[19] ↵
Severinghaus JW: Acid-base balance nomogram-A Boston-Copenhagen detente. Anesthesiology45 :539– 541,1976
OpenUrl PubMed

[20] ↵
Peters JP, Van Slyke DD: Clinical Chemistry Volume 1, Baltimore, Williams & Wilkins,1932 , p868

[21] ↵
Christensen HN: Anions versus cations. Am J Med23 :163– 165,1957
OpenUrl CrossRef

[22] ↵
Relman AS: What are “acids” and “bases”? Am J Med17 :435– 437,1954
OpenUrl CrossRef PubMed

[23] ↵
Goldberg M, Green SB, Moss M, Marbach CB, Garfinkel D: Computer-based instruction and diagnosis of acid-base disorders. JAMA223 :269– 275,1973
OpenUrl CrossRef

[24] ↵
Kellum J: Clinical review: Reunification of acid-base physiology. Crit Care9 :500– 507,2005
OpenUrl CrossRef PubMed

[25] ↵
Kellum J, Kramer DJ, Pinsky MR: Strong ion gap: A methodology for exploring unexplained anions. J Crit Care10 :51– 55,1995
OpenUrl CrossRef PubMed

[26] ↵
Moviat M, van Haren F, van der Hoeven H: Conventional or physicochemical approach in intensive care unit patients with metabolic acidosis. Crit Care7 :R41– R45,2003
OpenUrl PubMed

[27] ↵
Rastegar A: Use of the ΔAG/ΔHCO3 ratio in the diagnosis of mixed acid-base disorders. J Am Soc Nephrol18 :2429– 2431,2007
OpenUrl Abstract/FREE Full Text

[28] ↵
Rastegar A: Mixed acid-base disorders. In: Acid Base Disorders and Their Treatment, edited by Gennari FJ, Adrouge HJ, Galla JH, Madias NE, Boca Raton, Taylor & Francis,2005 , pp681– 696

[29] ↵
Fencl V, Jabor A, Kazda A, Figge J: Diagnosis of metabolic acid-base disturbances in critically ill patients. Am J Respir Crit Care Med162 :2246– 2251,2000
OpenUrl CrossRef PubMed

[30] ↵
Fencl V: Acid base disorders in critical care medicine. Annu Rev Med40 :17– 29,1989
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Clinical Utility of Stewart's Method in Diagnosis and Management of Acid-Base Disorders

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Abstract

Historical Review of Approach to Clinical Acid-Base Disorders

Stewart's Approach to Acid-Base Disorders