*Article* **The Effect of Nonthermal Pretreatment on the Drying Kinetics and Quality of Black Garlic**

**Klaudia Masztalerz <sup>1</sup> , Tomasz Drózd˙ z˙ 2 , Paulina Nowicka <sup>3</sup> , Aneta Wojdyło <sup>3</sup> , Paweł Kiełbasa <sup>2</sup> and Krzysztof Lech 1,\***


**Abstract:** Black garlic is obtained from regular garlic (*Allium sativum* L.) through the aging process and consequently gains many health-promoting properties, including antidiabetic and antioxidant. However, the material is still prone to microbiological deterioration and requires a long time to dry due to its properties. Therefore, this study aimed to investigate the effect of various drying methods on the quality of black garlic as well as determine the influence of selected nonthermal pretreatments on the drying kinetics and quality of black garlic, which is especially important in the case of the materials that are difficult to dry. The Weibull model was chosen to describe drying kinetics. Additionally, color, water activity together with antioxidant activity, phenolic compounds, and antidiabetic potential were determined. This study found that the application of a pulsed electric field (PEF), a constant electric field (CEF) as well as a magnetic field (MF) significantly reduced the time of drying (by 32, 40, and 24 min for a PEF, a CEF, and a MF, respectively, compared to combined drying without the pretreatment), and resulted in high antidiabetic potential. However, the highest content of phenolic compounds (1123.54 and 1125.36 mg/100 g dm for VMD125 and CD3h-VMD, respectively) and antioxidant capacity (ABTS = 6.05 and 5.06 mmol Trolox/100 g dm for VMD500 and CD6h-VMD, respectively) were reported for black garlic treated by vacuum-microwave drying and combined convective pre-drying followed by vacuum-microwave drying. Overall, the nonthermal pretreatment decreased the time of drying and showed very good efficiency in maintaining the antidiabetic potential of black garlic, especially in the case of the materials pretreated by a constant electric field (IC<sup>50</sup> = 99 and 56 mg/mL, for α-amylase and α-glucosidase, respectively).

**Keywords:** antidiabetic potential; antioxidant capacity; constant electric field; drying; magnetic field; pretreatment; pulsed electric field; total phenolic content
