In vivo antitumor assay showed that SPEF with different selleck compound frequencies had significant antitumor effect in

comparison to the control group. However, we did not observe any difference in antitumor efficiency among different frequencies even if the frequencies reach 5 kHz. Daskalov et al., also revealed similar result, electrochemotherapy with high frequency pulses was performed on basal cell and spin cell carcinoma and on melanoma metastases in patients. No difference in tumor responses was observed between 1-Hz and 1 kHz bipolar rectangular pulses [26]. Heller et al., also reported that the benefits from the use of high frequency electric pulses including overcoming the resistance of target tissue and reaching effective depth of interaction [27]. Furthermore, Chang and coworkers had also reported high efficiency gene SN-38 cost transfection by membrane electroporation using a radio-frequency electric field (40-kHz frequency) [28]. Further study EPZ015938 concentration confirmed that SPEF with 5 kHz could induce apoptosis observed by TEM both

in vitro and in vivo. We proposed that induced apoptotic effect was probably a consequence of scramble effects on the target subcellular organelles by the nanosecond pulse component in high frequency SPEF. Our previous study also demonstrated that SPEF with appropriate parameters could trigger cell apoptosis through intracellular calcium electromanipulation [13]. Another study by Weaver et al., also revealed that high frequency electromagnetic fields could cause mitochondrial electropermeabilization, inhibit energy generation and cell proliferation, further induced apoptosis [1]. Potential Use of High Frequency SPEF in Electrochemotherapy Motor nerves of skeletal muscle in most mammals were mainly composed of myelinated nerve fibres.

The data on the maximum frequency of generated action potentials were calculated to be about Mirabegron 400~2500 Hz (inverse value of the duration of the action potential and the refractory period) regarding to the absolute refractory period which depending on the axonal diameter, myelinated thickness and the number of myelinated nerve fiber [29]. As we know, electrical stimulation during absolute refractory period lead to null muscle contractility. Practically, electric pulse with a train of 8-pulses at standard repetition frequency of 1 Hz has been typically used in traditional electrochemotherapy for many years [17]. However, it deserves to be specially noted that, the limitation of such stimulus is that each individual pulse delivered consecutively can become an active stimulus, activate motor nerves in neuromuscular junctions around the electrodes and then generate an isolated muscle contraction. As reported in the literature, approximately 40 Hz electric stimulation will fuse successive muscle contractions into smooth motion-tetanic contraction [29].