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A study on effect of lipemia on electrolyte measurement by Direct Ion- Selective Electrode method. Dr. Susruta Sen MD, DNB, PG Dip. Diabetology Consultant.

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Presentation on theme: "A study on effect of lipemia on electrolyte measurement by Direct Ion- Selective Electrode method. Dr. Susruta Sen MD, DNB, PG Dip. Diabetology Consultant."— Presentation transcript:

1 A study on effect of lipemia on electrolyte measurement by Direct Ion- Selective Electrode method. Dr. Susruta Sen MD, DNB, PG Dip. Diabetology Consultant Dept of Lab Medicine The Calcutta Medical Research Institute

2 O Assess renal, endocrine, water balance and acid-base function O Diagnosis and management of Cushing’s and Addison’s disease O Potassium levels are indicated in tachycardia, arrhythmia, cardiac arrest etc. O Comprise approx. 25-30% of routine chemistry tests in any lab O The Laboratory must have the ability to perform these assys quickly & reliably Clinical utility of electrolyte measurement

3 O Direct ISE O No dilution of sample prior to analysis O Fixed electrodes with semi-permeable membranes requiring more frequent replacement (except VITROS slides with disposable electrodes) O Direct methods measure only the free ion giving a more physiologically correct result. O Indirect ISE O Pre-dilution of sample prior to analysis O Artifacts or erroneous results in samples containing high lipids and proteins O In Direct method measure not only the free but also the bound & complexed ions. Methods of Electrolyte Measurement

4 Direct Vs Indirect ISE

5 Electrolyte Exclusion Effect O Both direct & indirect methods produce comparable and accurate results O Indirect - dilutions are based on this “fixed” 93,7 ratio to calculate patient values Normal patient sample 93% 7% Aqueous Solution (Serum) Non-aqueous Solution (Lipids, Proteins) Na+ Abnormal patient sample Less than 93% Greater than 7% Aqueous Solution (Serum) Non-aqueous Solution (Lipids, Proteins) Na+ Indirect methods may underestimate “true” sodium concentrations since the aqueous solution is decreased due to higher than normal lipid or protein concentrations

6 Abnormal Lipids Patients with variety of diseases will have O Increase Lipids O Glycogen Storage diseases O Dyslipidemia O Diabetes – 30 Million diabetics in India O Acute pancreatitis O Hypothyroidism ………..

7 Indirect ISEs Have Been Problematic for a Long Time (References) O 1986 - Rapid measurement of serum water to assess pseudohyponatremia O Clin Chem 32: 983-986 O 1989 - Pseudohyponatremia: a reappraisal O RWJ Med School “can lead to dangerous errors in patient management” O The hyponatremic patient: A systemic approach to lab Diagnosis O CMAJ (2002):166:1056 O Jan 2006 - Effects of hyperlipidemia on Na, K, CL… By indirect ISE Measuring System O Clin Chem Letter to the Editor O Roche Modular - “hyperlipidemia caused errors in indirect electrolyte measurement O Poster on Electrolyte Study, Apollo Ludhiana

8 O Indirect ISEs are prone to pseudohyponatermia O Falsely low sodium results due to high lipids and proteins O Potential Medical Error O Many patients with high lipids and proteins O Lots of patients receiving IVs with lipid infusions O Prone to pseudohyponatermia O Avoid potential medical error by utilizing Direct ISEs Avoid potential medical errors

9 Objectives O To observe whether lipemia affects the measurement of electrolytes using direct potentiometry by increasing concentration of triglyceride on the serum samples in vitro. O To find out (if it affects) the specific concentration at which the effect starts making significant difference in measurement of electrolytes in the study subjects.

10 Methods O Type of study: Laboratory based experimental design. O Study population: subjects admitted in IPD of a tertiary care hospital, Kolkata, WB, India. O Study duration: 3 months, June-August,2014 O Sampling: 120 consecutive serum samples

11 Tools used 1. Clot/red capped vials. 2. Laboratory centrifuge model REMI R-8C. 3. Micro centrifuge tubes 4. Micropipette 5. INTRALIPID® 10%: a sterile fat emulsion containing soya oil, egg lecithin and glycerol. 6. HDC LYTE Electrolyte analyzer. 7. Vitros 250 Chemistry Analyzer

12 Methods contd… Each serum sample: A set of five:- Neat, Neat+5µl, Neat+10µl, Neat+15µl, Neat+20µl, Electrolytes measured in differents slots in the Vitros 250 Dry Chemistry Analyzer and HDC Lyte machines Data anlysed after categorizing in three groups: Hypo/Normo/Hyper natremia

13 Results O Comparison between electrolyte values obtained from two different equipments. O Comparison of electrolyte values at different concentration of triglyceride. O Assessing the drift of electrolyte results with a focus on clinical significance.

14 O 0-350 :Considered as the baseline concentration of IL. O Values obtained in different concentration was digitized. O Compared with baseline concentration by Paired t test. O Independent t test was also used to estimated the difference between values obtained from two equipments in similar concentration.

15 St atistically significant difference compared to baseline of TG 0-350 mg/dl concentration, measuring Na+ Vitros-250HDC-Lyte Natremia HypoNormoHyperHypoNormoHyper 0-350 350-650+++++- 650-1050++++++ 1050- 1550 ++++++ >1550++++++

16 Statistically significant difference compared to baseline of TG 0-350 mg/dl concentration, measuring K + Vitros-250HDC-Lyte Natremia HypoNormoHyperHypoNormoHyper 0-350 350-650 --+++- 650- 1050 ++++++ 1050- 1550 ++++++ >1550 ++++++

17 Comparing the two instruments Triglyceride conecntration (mg/dl) N Mean (mmol/Lt) Std. Deviation Std. Error Meanp-value Na+0-350 Vitros-250 40142.253.550.5610.803 HDC-Lyte 30142.452.9930.546 K+0-350 Vitros-250 404.390.3820.060.305 HDC-Lyte 304.480.3820.07 Na+350-650 Vitros-250 40140.983.6690.580.611 HDC-Lyte 30140.582.4550.448 K+350-650 Vitros-250 404.340.3860.0610.557 HDC-Lyte 304.40.4130.075 Na+650-1050 Vitros-250 40139.484.0570.6420.279 HDC-Lyte 30138.433.8520.703 K+650-1050 Vitros-250 404.280.3830.0610.707 HDC-Lyte 304.310.4270.078 Na+1050-1550 Vitros-250 40137.824.3080.6810.075 HDC-Lyte 30135.844.8260.881 K+1050-1550 Vitros-250 404.240.380.060.646 HDC-Lyte 304.280.450.082 Na+>1550 Vitros-250 40135.283.9350.6220.001 HDC-Lyte 30131.335.571.017 K+>1550 Vitros-250 404.160.370.0580.606 HDC-Lyte 304.120.3660.067

18 Hypernatremic sample Comparision TriglycerideNA+(Vitros)NA+(HD Lyte) 0-350153.125160.725 350-650150.458152.099 650-1050148.812148.982 1050-1550147.187145.981 >1500145.208141.701 Triglyceride Na% diff(Vitros)Na% diff(HD Lyte) 0-35000 350-6501.745.36 650-10502.817.3 1050-15503.879.17 >15005.1711.83

19 Hypernatremic Samples Comparision for K+ TriglycerideK+(Vitros)K+(HD Lyte) 0-3504.7124.914 350-6504.6354.762 650-10504.6144.637 1050-15504.5714.55 >15004.5294.432 Triglyceride K% diff(Vitros)K% diff(HD Lyte) 0-35000 350-6501.633.08 650-10502.125.62 1050-15503.017.41 >15003.899.79

20 Normonatremic Sample Comparision TriglycerideNA+(Vitros)NA+(HD Lyte) 0-350142.251142.451 350-650140.975140.578 650-1050139.475138.427 1050-1550137.825135.853 >1500135.275131.222 Triglyceride Na% diff(Vitros)Na% diff(HD Lyte) 0-35000 350-6500.9661.31 650-10501.952.82 1050-15503.114.63 >15004.917.88

21 Normonatremic Samples Comparision for K+ TriglycerideK+(Vitros)K+(HD Lyte) 0-3504.3874.483 350-6504.3454.401 650-10504.2754.311 1050-15504.2374.282 >15004.1654.118 Triglyceride K% diff(Vitros)K% diff(HD Lyte) 0-35000 350-6500.961.82 650-10502.563.83 1050-15503.414.48 >15005.078.14

22 Hyponatremic Sample Comparision TriglycerideNA+(Vitros)NA+(HD Lyte) 0-350124.725125.922 350-650123.501123.287 650-1050122.451121.229 1050-1550121.201115.805 >1500120.175113.355 Triglyceride Na% diff(Vitros)Na% diff(HD Lyte) 0-35000 350-6500.982.09 650-10501.823.72 1050-15502.828.03 >15003.649.98

23 Hyponatremic Samples comparision for K+ TriglycerideK+(Vitros)K+(HD Lyte) 0-3504.0323.982 350-6504.0113.966 650-10503.9853.926 1050-15503.9573.761 >15003.9473.695 Triglyceride K% diff(Vitros)K% diff(HD Lyte) 0-35000 350-6500.550.4 650-10501.171.39 1050-15501.855.54 >15002.17.18

24 Conclusion O The two instruments are mostly comparable for measuring electrolyte concentration. O However, O Vitros 250 appears to be more consistent with Na+ concentration result compared to HDC lyte in different lipemic state. O Beyond 1550 mg/dl concentration of TG, the difference between electrolyte concentration measured in two instruments varied significantly.

25 Conclusion O The results showed statistically significant difference between electrolyte concentration measured in both instruments at 0-350 mg/dl TG concentration and gradually escalated lipemic states, except: O (Lipemia 350-650 mg/dl) O HDC lyte : Na+ & K+ in hypernatremic group O Vitros250: Na+ in hypo & normonatremic groups

26 Conclusion O Clinically significant drift noted in:  >1050 mg/dl of TG concentration for HDC lyte  >1550 mg/dl of TG concentration for both the instruments.

27 Conclusion O Further studies required to establish a correction factor for measuring electrolyte concentration in regular patient care setting for lipemic samples. O To find out the optimum TG concentration till which the electrolyte results remains unaffected if measured by direct ISE method.

28 QUESTION ???.

29 THANK YOU.

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