Assessment of heavy metals and macromineral in frequently used medicinal plants from Algerian Sahara traditional ethnopharmacopeia.

In this study, a total of 15 elements, both physiological and causing toxic effects, have been determined in 9 medicinal plants collected from their natural environment in the Algerian Sahara regions. The concentrations of elements were determined by inductively coupled plasma optical emission spectrometry (ICP-OES) after acid digestion and by the X-ray fluorescence spectrometry (XRF). By analyzing the spiked test and the reference materials, the accuracy of the measurements was determined. Our findings show differences in elements composition and concentration between the species under investigation, indicating differences in physiological function of the plant as a result of elemental interactions within it. The elements were quantified (in µg/g): Br (0.04-5.44), Cd (1.21-1.34), Co (1.12-64.35), Cr (1.51-59.05), Cu (1.81-9.28), Fe (94.26-668.55), Mn (16.34-70.77), Ni (1.5-53.64), Pb (1.18-2.55), Zn (1.21-310.80) and (in mg/g): Ca (4.23-4.70), Cl (21.98-117.91), P (28.92-30.49), S (4.15-11.95), Si (1.99-2.36). Mean element levels in medicinal plants were established in decreasing order as follows: Zn>Mn>Cu>Cr>Ni>Pb>Cd>Co. Except for nickel, which reached 53.64µg/g in the Capparis spinosa L species, heavy metal concentrations were found to be low in all samples. Based on traditional use, we can cautiously conclude that these medicinal plants pose no risk to users.

Class D amplifier for a power piezoelectric load.

We present a high efficiency inverter (>90%) that can drive an acoustic cavitation reactor with a 2 kW power between 10 and 100 kHz. This reactor is composed of numerous piezoelectric transducers and is particularly used to accelerate various industrial chemical reactions and destroy a variety of organic contaminants in water. The class-D amplifier or inverter is composed of power MOSFETs, type IRFP460, in a full bridge configuration driven by IR2110 circuits in bootstrap mode. The specific nature of the problem comes from the fact that, at frequencies slightly different from a resonant frequency frn, the load is mostly capacitive. The insertion of an appropriate low-pass filter in front of the load allowed an efficient solution to the problem due to the load being capacitive for harmonics. The realized system can provide nearly 2 kW to this type of piezoelectric load, with an efficiency of more than 95%