Abstract
Analytical calibration using ordinary least squares (OLS) is the most widely applied response function for calibration in all type of laboratories. However, this calibration function is not always the most adequate and its indiscriminant use can lead to obtain biased estimates of unknowns. Students need to be taught about the practical requirements needed to obtain good results with OLS and when this fitting method is not accurate. Different experimental calibration curves were obtained in laboratory sessions using two common instrumental techniques: chromatography and atomic absorption spectrometry. After discussion seminars evaluating the data obtained by students, they were able to understand that linear fitting was not the most accurate model using atomic absorption spectrometry and a quadratic fitting provided most accurate estimates. Linearity was confirmed in chromatographic calibrations, but data presented heteroscedasticity, which is very common in calibrations done in chemical and biological analyses. A simple experiment was applied to show students how the use of the regression coefficients obtained by OLS with heteroscedastic data lead to highly biased estimates near the quantification limits of the calibration curve. The results obtained allowed to show students that, despite being widely used, OLS is not the most adequate fitting model to obtain accurate and precise results with many calibration methods routinely used in chemical and biological laboratories.
Highlights
Many chemistry and biological experiments are devoted to the estimation of an unknown sample concentration
This study presents a discussion about the practical requirements to take into account for analytical calibrations done in chemistry and biological analyses, with emphasis in the most common problems and misconceptions observed during different university laboratory sessions where calibrations were used to determine estimates of unknowns
Calibration curves obtained for five analytical methods using two different detection techniques were evaluated
Summary
Many chemistry and biological experiments are devoted to the estimation of an unknown sample concentration. For this purpose, a well-designed and interpreted response function (y=f(x), where y is the dependent variable, usually an instrumental signal, and x is the independent variable, commonly a concentration) is essential. The function is defined by: yy = bb0 + bb1xx where b0 and b1 are the regression coefficients, called the intercept with the y-axis or origin (b0) and the slope or sensitivity (b1). OLS estimates these coefficients with the goal of minimizing the sum of the square residuals generated between each experimental response (yi) and its predicted y-value from the generated function (y yii = bb0 + bb1xxii ):
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