Numerical characterization of the GCPW

The GCPW was modeled using the ANSYS HFSS (v. 15.0) software, as presented in previous work [Reference Paffi, Banin, Denzi, Casciola, Liberti and Apollonio19]. A first analysis was carried out in the time domain with a pulsed signal coming from a 50-Ω feeding coaxial cable excited by a lumped port. The applied signal had a trapezoidal waveform, 10 ns long, with rise and fall time equal to 2 ns, and voltage equal to 1 V (see Fig. 1). The transient solution was sampled every 1 ns.

Fig. 1. Geometric model of the GCPW structure used for numerical characterization applying a 10 ns duration pulse.

The GCPW was fabricated on a three-layer RO4003C laminate, the dielectric substrate has permittivity ɛ _r = 3.55 and a thickness of 1.524 mm. Here, the GCPW has been analyzed alone and with the sample holder used in the experimental characterization. It was modeled as a hollow cylinder of Perspex (ɛ _r = 5.5) with an internal radius of 5.5 and 1 mm thick wall. The holder was filled with 400 μl of saline solution (ɛ _r = 85; σ = 0.7 S/m) and placed on the GCPW, as shown in Fig. 1. The conductivity assigned to the solution in numerical analysis was one of the intermediate values used for the experimental characterization.

A second analysis with ANSYS HFSS (v. 15.0) software was performed in the frequency domain to evaluate the scattering parameters of the empty structure in the frequency range up to 500 MHz, well above the main lobe of the 10 ns pulse (below 100 MHz).

Figure 1 shows the simulated model with the main geometric parameters: L = 120 mm; A = 50 mm; H = 1.524 mm; s = 3.35 mm; w = 2 mm; d = 11 mm; h = 8 mm.

Experimental characterization of the GCPW

A preliminary characterization of the exposure system in the time domain was presented in [Reference Caramazza, Paffi, Liberti and Apollonio1], showing encouraging results in terms of the quality of the signal propagating along the GCPW. In particular, the signal at the output of the generator was measured and results showed a shape similar to the ideal trapezoidal pulse with rise and fall time of 2 ns and a duration of 10 ns (as the duration at half maximum amplitude).

Here, a characterization of the GCPW structure in terms of the scattering parameters was performed with a Vector Network Analyzer (E8363C Agilent), in the frequency range up to 500 MHz, well above the spectral content of 10 ns pulses. Specifically, the set of measurements was performed in the absence and presence of the sample holder filled either with distilled water or with NaCl solution.

Then, a complete and exhaustive characterization of the system was performed using the experimental bench adopted in [Reference Caramazza, Paffi, Liberti and Apollonio1] and briefly reported here in Fig. 2. Figure 2(a) shows the schematics of the setup, Fig. 2(b) shows the setup itself in place, and Fig. 2(c) shows the description of the equipment used as (1) an R&S oscilloscope (RTO2014, Rohde & Schwarz, Germany) to measure and collect the signal in time; (2) a nanosecond pulser (FPG 10-1NM10, FID Technologies, Germany); (3) a high-voltage (HV) coaxial cable and connectors; (4) a couple of HV probes (TT-HV probes 2739, Testec, Germany), able to detect the signal transmitted to the exposure system with a spatial resolution of the field probe of about 1 mm; (5) the exposure system represented by the GCPW; (6) a 50-Ω matching load to close the experimental chain.

Fig. 2. (a) Scheme of the experimental bench. (b) Experimental bench setup in place. (c) Table of the equipment composing the exposure bench and shown in (b).

In accordance with a measurement procedure used for cuvette exposure system, as in [Reference Caramazza, Nardoni, De Angelis, Paolicelli, Liberti, Apollonio and Petralito3, Reference Kenaan, Amari, Silve, Merla, Mir, Couderc, Arnaud-Cormos and Leveque23, Reference Silve, Vézinet and Mir24], in order to obtain the experimental characterization of the bench, authors have performed the following steps: (i) the GCPW has been fed by the nanosecond pulser in a range from 4 to 8 kV to evaluate the transmission of pulses with rise and fall time of 2 ns and a duration of 10 ns; (ii) the signal has been detected along with three positions in the GCPW system, shown in Figs 3(a)–(c), respectively, at 3, 6, and 9 cm from port 1, to evaluate possible distortions; (iii) finally, measurements of the signal inside the Perspex sample holder containing 400 μl solution with conductivity values ranging from 5.6 × 10⁻⁴ up to 1.4 S/m, has been done (see Fig. 4). The conductivity values of each solution sample were previously measured using a Precision LCR Meter E4980A from Agilent, as in [Reference Caramazza, Nardoni, De Angelis, Paolicelli, Liberti, Apollonio and Petralito3, Reference Denzi, della Valle, Esposito, Mir, Apollonio and Liberti6]. This last step has been performed to characterize the exposure system in presence of different host solutions that could contain nanosized lipid vesicles for drug delivery applications.

Fig. 3. Detail of the exposure bench during the experimental characterization along the GCPW line, at 3 cm (a), at 6 cm (b), and at 9 cm (c) from port 1.

Fig. 4. Detail of the exposure bench during the experimental characterization performed in the presence of a 400 μl sample holder placed at the center of the GCPW line.

Modeling the electropulsation of nanosized lipid vesicles

To numerically study the feasibility of electropermeabilize lipid vesicles applying a train of nsPEFs, a microdosimetric model has been used with COMSOL Multiphysics v. 5.3. The geometrical model, described for the first time in [Reference Caramazza, Paffi, Liberti and Apollonio1], is composed of five liposomes randomly distributed, characterized by a 130 nm radius, and 5 nm membrane thickness (implemented in the model using a contact impedance setting). Liposomes are placed in a two-dimensional rectangular box representing the external solution, with dimensions of about 1 μm × 0.7 μm. Moreover, in order to simulate a larger geometrical model, periodic conditions were set at the lateral boundaries of the box (see Fig. 5).

Fig. 5. The geometric model used for the microdosimetric study. The model is ideally repeated in space, due to periodic boundary conditions set at the lateral boundaries.

In this model, the application of a train of nsPEFs on the distribution of liposomes is simulated considering electric field applied of 8.5, 8.7, 8.8, and 9 MV/m, in order to evaluate the number of pulses that has to be applied to obtain electropermeabilization of liposomes. The pulses are delivered at a repetition frequency of 2 Hz.

To perform this set of simulations, three physics were added to the model using three different modules: (i) the electric currents module from AC/DC mode, to solve the quasi-static electromagnetic problem, (ii) the heat transfer in fluids module, to evaluate possible temperature changes in time, and (iii) the boundary ordinary differential equations and differential-algebraic equations, to study the kinetics of pores on the liposomes membrane, as in [Reference Caramazza, Paffi, Liberti and Apollonio1, Reference Caramazza, Nardoni, De Angelis, Paolicelli, Liberti, Apollonio and Petralito3, Reference DeBruin and Krassowska25]. According to the literature, the interaction between lipid vesicles and ultra-short and intense electric fields induces the increase in time of the induced potential across the lipid membrane, known as transmembrane potential (TMP), up to a threshold value, and the simultaneous formation of transient pores across the membrane, determining the consequent increase of membrane conductivity in time. The number of pores is modeled in the literature as a spatial pore density (N) [Reference Caramazza, Nardoni, De Angelis, Paolicelli, Liberti, Apollonio and Petralito3, Reference Mercadal, Vernier and Ivorra26–Reference Krassowska and Filev28], whose kinetics depends on the TMP evolution in time with the following equation:

(1)$$\displaystyle{{dN} \over {dt}} = \alpha e^{{\left({{{TMP( t ) } \over {V_{ep}}}} \right)}^2}\left[{1-\displaystyle{{N( t ) } \over {N_0}}e^{{-}q{\left({{{TMP( t ) } \over {V_{ep}}}} \right)}^2}} \right]\;$$

The parameters in equation (1) are reported in Table 1, as in [Reference DeBruin and Krassowska25].

Table 1. Parameters of the pore density kinetics model [Reference DeBruin and Krassowska25].

In accordance with the literature, to obtain the membrane poration, both the TMP and the spatial pore density should overcome their threshold values of 1 V and 10¹⁴ m⁻², respectively.

Usually, unipolar pulses are used in nsPEFs applications, however, some in vitro studies experimentally investigated the role of bipolar nsPEFs on the electropermeabilization effect [Reference Orlacchio, Carr, Palego, Arnaud-Cormos and Leveque29, Reference Pakhomov, Semenov, Xiao, Pakhomova, Gregory, Schoenbach, Ullery, Beier, Rajulapati and Ibey30]. In this regard, microdosimetric studies could be a powerful tool to understand the phenomena determining the possible decrease of membrane electropermeabilization.

For what concerns unipolar nsPEFs, microdosimetric simulations investigate the effect on the lipid membrane of a single pulse with different durations, determining the electric field value able to porate biological membranes [Reference Denzi, della Valle, Apollonio, Breton, Mir and Liberti5, Reference Denzi, della Valle, Esposito, Mir, Apollonio and Liberti6, Reference Retelj, Pucihar and Miklavcic14]. Recently, in [Reference Caramazza, Nardoni, De Angelis, Paolicelli, Liberti, Apollonio and Petralito3, Reference Lamberti, Romeo, Sannino, Zeni and Zeni31] the authors numerically investigated the response occurring when a train of nsPEFs is applied in order to consider possible cumulative mechanisms; the main issue to study such a train is related to a temporal multiscale problem that determines a huge computational cost.

In particular, the pore density kinetics (see equation (1)) [Reference Neu and Krassowska27, Reference Krassowska and Filev28], describes both pores creation (pulse-ON) and their resealing (pulse-OFF), but the two phenomena occur with two different timescales in the order of ns and s, respectively, for pore formation and pore resealing. This difference in timescale could be considered as a sort of “memory effect” of pore density kinetics and used for electro-stimulate lipid bilayer with a train of nsPEFs with electric field intensity lower than what needed with one single pulse.

Starting from preliminary results reported in [Reference Caramazza, Paffi, Liberti and Apollonio1], the microdosimetric simulations were performed to study liposome nanoporation and pore density kinetics “memory effect” when applying a train of pulses with different electric field amplitudes.

In the model, the conductivity of the solution was chosen as the value of σ = 0.7 S/m in the middle of the range of experimental conductivity values, in line with the numerical characterization of the exposure system (see “Numerical characterization of the GCPW”). All the physical parameters used in these simulations are reported in Table 2, according to the experimental data and the literature [Reference Caramazza, Nardoni, De Angelis, Paolicelli, Liberti, Apollonio and Petralito3–Reference Denzi, della Valle, Apollonio, Breton, Mir and Liberti5, Reference Merla, Denzi, Paffi, Casciola, D'Inzeo, Apollonio and Liberti32, Reference Merla, Liberti, Apollonio and D'inzeo33].

Table 2. Physical quantities reported in the model to simulate the suspension of liposomes.