INTRODUCTION

High levels of cholesterol in blood are considered the main modifiable risk factor for cardiovascular disease. A large body of scientific evidence supports this premise by unambiguously establishing that reductions of low-density lipoprotein cholesterol (LDL-c), through lifestyle changes and/or use of medicaments have a major impact in lifetime, in reduction of cardiovascular events and mortality1.

The "point-of-care testing" (POCT) method is intended to provide rapid and accurate results. The evaluation of the complete lipid profile on a single reagent strip using capillary whole blood provides results in less than two minutes. This agility allows us to anticipate the beginning of clinical treatment. For example, physicians in their office can identify early the individuals at risk for cardiovascular disease, monitor their therapeutic response to the medication prescribed, adjust the dose of medication, and monitor target achievement and treatment compliance2.

Through the data obtained in this study, we aimed to evaluate the advantages of the POCT measure in comparison to the traditional methodology and its viability in the clinical routine of the medical offices.

METHODS

Study design and patient selection

For this study, we recruited 111 patients who sought, for any reason, the private cardiology and endocrinology clinics participating in this study. Patients who met the inclusion and exclusion criteria after being informed by the physician about the procedures, risks, benefits and rights were considered eligible to participate in the protocol, with all their doubts clarified. All agreed to sign the informed consent form.

The study required two collections of blood samples on the same day: 1) in the office, through finger puncture, to collect a capillary blood drop; and 2) in the clinical analysis laboratory, in a conventional way, by venipuncture. For both samples, 8 to 12 fasting hours was required, and the interval between the two collections was less than 60 minutes.

The laboratory parameters determined were total cholesterol (TC), high-density lipoprotein cholesterol (HDL-c) and triglycerides (TG); the LDL-c values were calculated by the Friedewald formula3 and the POCT analyzer provided them automatically.

Diagnostic methodology

Total capillary blood samples obtained by the clinics were analyzed on CardioChek^® PA (CCPA) (PTS Diagnostics, Indianapolis, USA) equipment on lipid panel test strips. The guidelines of the manufacturer's protocol were observed and the operation of the electronic and optical parts of the analyzer was verified with ChekMateTM at all the wavelengths used by the equipment. The lipid panel test strips were tested using the quality control of the CardioChek^® Level 1 and Level 2.

The reactive strips for the lipid profile present an initial membrane that removes the red blood cells and, by the horizontal flow, the plasma lipids are determined by a dry chemical reaction. TC and HDL-c evaluations use the same enzymatic reaction. HDL lipoprotein is separated from the other plasma lipoproteins in the presence of phosphotungstic acid and magnesium chloride. The HDL resulting fraction in plasma reacts with surfactants and enzymes for the determination of the cholesterol concentration. The TG measure is performed by an enzymatic colorimetric method, using lipoprotein lipase, glycerol kinase, glycerolphosphate oxidase and peroxidase. The Cardiochek analyzer employs reflectance photometry4.

Blood samples from the venipuncture were collected and analyzed in clinical laboratories (LAB) that present internal and external quality control, with certification. The methodology for the analysis of TC, HDL-c, TG and LDL-c has the same principle as the reactive strips.

Statistical analysis

Data analysis was performed using the Microsoft Excel (2010). The mean values of each lipid profile variable obtained by CCPA and LAB were calculated. Linear regression was used to determine the existence of correlation between the two methods. Statistical significance was defined as p < 0.05.

RESULTS

The mean values of each variable of the lipid profile from the 111 participating patients, obtained by both CCPA and LAB methods, are presented in Table 1.

The graphs presented in Figures 1, 2, 3 and 4 demonstrate the existence of correlation between the two methods for the variables TC, HDL-c, TG and LDL-c, respectively.

Table 2 shows the statistical data for the calculation of the correlation coefficients (R) and the coefficient of determination (R²) by the linear regression analysis.

DISCUSSION

Our results demonstrate a positive relationship between the values obtained by the POCT methodology and the conventional laboratory for all the variables of the lipid profile, as demonstrated in a previous Brazilian study that, evaluating the clinical correlation between the CCPA and the clinical reference laboratory of the Hospital of the Universidade Federal de São Paulo, Escola Paulista de Medicina (Unifesp/EPM)5, confirmed that the analytical performance of this POCT equipment is suitable for use in population screening programs and as a service in healthcare systems, providing fast and reliable results. Other studies that compared the performance of CCPA with that of the conventional LAB, in different populations showed results similar to those found in our study. Panz et al. (2005), evaluated 100 South African patients with familial hypercholesterolemia (HF), and found a significant correlation between the methods6. Yang et al. (2013), in 1,263 Chinese patients over 40 years of age demonstrated the effectiveness of CCPA in detecting the lipid levels of patients at high cerebrovascular risk7.

Our data, extracted from the routine use of CCPA in private medical practices, supports the substantial contribution of the POCT methodology in the detection of the main cardiovascular risk factors, representing a new tool and excellent diagnostic option.

CONCLUSION

The POCT CardioChek PA analyzer is an easy-to-operate tool with adequate analytical performance and very good correlation with the results of the conventional laboratory method, therefore reliable.

REFERENCES

Xavier HT, Izar MC, Faria Neto, et al. V Diretriz Brasileira de Dislipidemias e Prevenção da Aterosclerose. Arq Bras Cardiol. 2013 Oct; 101(4 Suppl 1): 1-20.

Sociedade Brasileira de Patologia e Medicina Laboratorial. Diretriz para gestão e controle de qualidade de Testes Laboratoriais Remotos (TLR) da SBPC/ML, 2013. Available at: http://sbpc.org.br/

Friedewald WT, Levy RI, Fredrickson DS. Estimation of the concentration of low-density lipoprotein cholesterol in plasma, without use of the preparative ultracentrifuge. Clin Chem. 1972; 18: 499-502.

The CardioChek^®, CardioChek^® PA and associated test strips are covered by one or more of the following patents. Polymer Technology Systems, Inc.7736 Zionsville Rd. Indianapolis, IN 46268 EUA.

Ferreira CES, França CN, Correr CJ, et al. Clinical correlation between a point-of-care testing system and laboratory automation for lipid profile. Clin Chim Acta. 2015; 446(2015): 263-6.

Panz VR, Raal FJ, Paiker J, Immelman R, Miles H. Performance of the CardioChekTM PA point-of-care analysers compared to clinical diagnostic laboratory methods for the measurement of lipids. Cardiovasc J South Afr. 2005.

Yang P, Su Li NA, Zhu Y, et al. Evaluation on lipid detection of CardioChek PA blood analyzer and its application in lipid screening in high risk stroke group. CJCNN. 2013; 13(4).

Author notes

Corresponding author: Hermes Toros Xavier, Avenida Ana Costa, 374, cj. 61; Gonzaga, CEP: 11060-002; Santos-SP, Brasil. e-mail: hermes.xavier@litoral.com.br