The study was a retrospective study. The study was conducted from April to June 2014. Two hundred and six samples obtained from intensive care unit patients of Pondicherry Institute of Medical Sciences were included in the study. Out of the 206 samples, 126 were from male patients and 80 were from female patients. Only those patient samples were included in the study where the arterial and venous electrolytes results were available. The arterial and venous electrolyte values were obtained from the laboratory records. The time of receiving the samples by the laboratory was noted. The time was matched for both venous and arterial samples of patients and only those patients were included where the difference between receiving of venous and arterial electrolytes did not exceed 20 min. The arterial and venous samples of patients which were received by the laboratory beyond 20 min interval were excluded from the study. The venous electrolytes were measured by Easylyte electrolyte analyser from transasia. The electrolytes in arterial sample were measured by Cobas B121 ABG analyser from Roche diagnostics.

The statistics in the study were descriptive statistics which included mean, standard deviation, minimum and maximum values. The data of sodium and potassium was entered in Microsoft excel for windows. Arterial sodium was correlated with venous sodium by spearman’s correlation. Arterial potassium was correlated with venous potassium by Pearson correlation. Scatter plot was employed to represent arterial and venous sodium and potassium. Scatter plot was used to derive the formula for predicting venous electrolyte values from arterial electrolytes.

The results of the study are illustrated in [Table/Fig-2,3].

The mean arterial sodium was 134 and the mean venous sodium was 137. The mean arterial potassium was 3.6 and the mean venous potassium was 4.1. The correlation coefficient for sodium was 0.787 and the correlation coefficient for potassium was 0.701. There was positive correlation of arterial sodium and arterial potassium with venous sodium and venous potassium. The arterial and venous sodium are illustrated through scatter plot in [Table/Fig-4]. The arterial and venous potassium are illustrated through scatter plot in [Table/Fig-5]. Scatter plot for sodium illustrates that venous sodium can be derived from arterial sodium by the formula, Venous sodium = 0.81 x arterial sodium + 28.4. Scatter plot for potassium is illustrated in [Table/Fig-5]. Scatter plot for potassium illustrates that venous potassium can be derived from arterial potassium by the formula, Venous potassium = 0.68 x arterial potassium + 1.6.

[Table/Fig-4]:

The venous sodium values (in mEq/L) are plotted in y axis and arterial sodium values are plotted in X axis

[Table/Fig-5]:

The venous potassium values (in mEq/L) are plotted in y axis and arterial potassium values are plotted in X axis

Development in technology in point of care analysers has led to measurements of multiple parameters in whole blood. Point of care testing analysers has gained lot of importance because of low TAT which is desirable in management of critically ill patients [2]. In the present study, the mean values of arterial sodium and arterial potassium values were found to be lower than venous sodium and venous potassium. Johnston and Murphy observed higher levels of potassium in arterial sample when compared to venous sample which was not comparable to the findings of the present study [2]. Mehta V et al., observed that venous values of potassium were higher than arterial levels which was comparable with the findings of the present study [6].

S Rajavi et al., observed higher levels of sodium and potassium in serum when compared to sodium and potassium in arterial blood. According to S Rajavi et al., the lower arterial values could be explained by dilutional effect of heparin since arterial samples are collected in heparinized containers [7]. In the present study, the value of venous sodium could be calculated from arterial sodium by the formula, venous sodium = 28.4 ± 0.81 x arterial sodium. The value of venous potassium in the present study could be calculated by the formula, venous potassium = 1.6 ± 0.68 x arterial potassium. S Rajavi et al., observed in their study that venous sodium could be calculated by the formula 106 + 0.23 x arterial sodium and venous potassium could be calculated by the formula 1.96 + 0.69 x arterial potassium [7].

Wongyingsinn M et al., observed a good correlation between arterial and venous potassium and they stated that arterial potassium can replace measurement of venous potassium [8]. Chhapola V et al., observed that arterial blood gas analysers underestimate sodium and potassium levels if arterial samples are collected in liquid heparinized containers [9]. The underestimation of electrolytes due to liquid heparin can be avoided by use of lyophilized heparinized containers for collection of arterial blood. Fu P et al., studied on potassium levels in patients with diabetic ketoacidosis and concluded that arterial potassium cannot be used as a substitute to serum potassium in patients with diabetic ketoacidosis [10]. Flegar Mestric Z et al., observed that electrolytes measured in whole blood by point of care analyser were comparable to electrolytes measured in plasma or venous serum samples [5].

Anunya Jain et al., observed that there was no significant difference between potassium measured in ABG analyser and potassium measured by routine chemistry auto analyser but they observed significant difference between sodium measured by ABG analyser and sodium measured by chemistry autoanalyser. According to Jain A et al., the cause for lower values of electrolytes in arterial blood is because of binding of heparin to electrolytes [11]. R King et al., observed that there was good agreement between the sodium and potassium values measured by ABG analyser and chemistry autoanalyser [12]. Binila Chacko et al., observed that there was significant difference between arterial and venous sodium levels and arterial and venous potassium levels which was not comparable with the findings of the present study. Binila Chacko et al., suggested such studies to be conducted in each center and a correction factor need to be established which needs to be added to the arterial electrolyte values to derive the accurate electrolyte values [13]. According to Chacko B et al., the reasons for such differences between the arterial and serum electrolytes could be attributed to difference in sample, whole blood and serum, difference in the type of electrode used and difference in the use of calibrators [13]. Herrington WG et al., observed that potassium values of arterial samples were in agreement with the potassium values measured in serum [14]. Shilpi Awasthi, et al., observed that there was a strong correlation between the arterial sodium and potassium and venous sodium and potassium which were similar to the findings of the present study [15].

In the present study, the bias for sodium was 0.9 and for potassium was 0.3 which is within the acceptable bias as per Clinical Laboratory Improvement Amendment (CLIA) guidelines. As per CLIA guidelines, the acceptable bias for sodium is target value + 4 mEq/L and for potassium, the acceptable bias is target value ± 0.5 mEq/L. Budak YU et al., observed a bias of 4.9 for sodium and a bias of 0.25 for potassium. According to Budak YU et al., one of the causes for high serum potassium levels when compared to arterial potassium levels was the release of potassium from platelets during the clotting process [16].

Sodium and potassium analysed in point of care ABG analyser is comparable to the sodium and potassium levels measured in electrolyte analyser and ABG electrolytes can be used as a replacement to electrolytes measured in electrolyte analyser.