The first observations of the effects of pulsed electric fields on biological material date more than 250 years back. But in the past two decades applications of electroporation emerged in medicine, food processing, and biotechnology. The phenomenon of electroporation leads to increased cell membrane permeability. Due to exposure to high voltage electric pulses, the cell membrane becomes permeable to molecules, which otherwise can not cross the membrane. A pulsed power generator termed as electroporator and electrodes are used to expose cells to a pulsed electric field. Electroporator generates electrical pulses with a specific shape, amplitude, duration, number, repetition rate and sequence (bursts of pulses). By applying electrical pulses to the electrodes, which are in direct contact with the tissue, an electric field is generated in tissue with specific distribution and intensity. In order to properly understand the current situation and trends of development on the electroporation field, a thesis begins with a review of commercially available devices, their characteristics, limitations, and weaknesses. Also, expert opinion about the electroporation devices used in skin electroporation was provided. The electroporation device manufacturers are currently hindering the development of electroporation field by concealing the output pulse parameters of their devices, designing them in a way to disable output pulse measuring, specifying characteristics which device cannot deliver, and making devices that do not warn the user when pulse delivery fault occurs. The quality of the pulse delivery was evaluated, by checking if the delivered pulses were adequately addressed and measured in the electroporation studies, with the focus on the field of nanosecond electroporation, where the delivery and measuring are the most challenging. Additionally, recommendations for standardization, mainly focusing on the evaluation of electroporators proper or improper operation were proposed and electronic emulator of the biological load during electroporation, which enables constant and sustainable testing and unbiased comparison of different electroporators operation, was developed. Secondly, we developed a high-frequency high voltage generator by using and improving the latest pulse generator designs. The developed 4 kV pulse generator, generates high voltage pulses with minimized switching time between positive and negative pulse. The minimal pulse duration is 200 ns and maximal repetition rate 2 MHz, it is also able to generate asymmetrical bipolar pulses. The developed device was tested in first in vivo high-frequency electrochemotherapy (HF-ECT), in which HF-ECT with bleomycin and cisplatin was proved to be as effective as well established "classical" ECT with bleomycin and cisplatin. Third, the cost-effectiveness of electrochemotherapy of stage IV and IIIc skin melanoma was calculated for patients treated at the Institute of Oncology in Ljubljana using the Cliniporator device and associated electrodes. The probability of ECT (with hospitalization) being cost-effective for the patient with stage IV and IIIc skin melanoma is just above 50 %, which implies the prices of the device and electrodes should be reduced for successful implementation into clinical practice. However, if patients have bleeding lesions the ECT can be assumed cost-effective (probability rises to 0.97).