Yan Mi1, Jin Xu1, Xuefeng Tang1, Changhao Bian1, Hongliang Liu2, Qiyu Yang3, Junying Tang3. 1. 1 State Key Laboratory of Power Transmission Equipment and System Security and New Technology, School of Electrical Engineering, Chongqing University, Chongqing, China. 2. 2 Electric Power Research Institute State Grid Beijing Electric Power Company, Beijing, China. 3. 3 First Affiliated Hospital, Chongqing Medical Science University, Chongqing, China.
Abstract
We studied the influence of various parameters of high-frequency nanosecond pulse bursts on the strength of rabbit muscle contractions. Ten unipolar high-frequency pulse bursts with various field intensities E (1 kV/cm, 4 kV/cm, and 8 kV/cm), intraburst frequencies f (10 kHz, 100 kHz, and 1 MHz), and intraburst pulse numbers N (1, 10, and 100) were applied using a pair of plate electrodes to the surface skin of the rabbits' biceps femoris, and the acceleration signal of muscle contraction near the electrode was measured using a 3-axis acceleration sensor. A time- and frequency-domain analysis of the acceleration signals showed that the peak value of the signal increases with the increasing strength of the pulse burst and that the frequency spectra of the signals measured under various pulse bursts have characteristic frequencies (at approximately 2 Hz, 32 Hz, 45 Hz, and 55 Hz). Furthermore, we processed the data through multivariate nonlinear regression analysis and variance analysis and determined that the peak value of the signal scales with the logarithm to the base 10 of EN x, where x is a value that scales with the logarithm to the base 10 of intraburst frequency (f). These results indicate that for high-frequency nanosecond pulse treatment of solid tumors in or near muscles, when the field strength is relatively high, the intraburst frequency and the intraburst pulse number require appropriate selection to limit the strength of muscle contraction as much as possible.
We studied the influence of various parameters of high-frequency nanosecond pulse bursts on the strength of rabbit muscle contractions. Ten unipolar high-frequency pulse bursts with various field intensities E (1 kV/cm, 4 kV/cm, and 8 kV/cm), intraburst frequencies f (10 kHz, 100 kHz, and 1 MHz), and intraburst pulse numbers N (1, 10, and 100) were applied using a pair of plate electrodes to the surface skin of the rabbits' biceps femoris, and the acceleration signal of muscle contraction near the electrode was measured using a 3-axis acceleration sensor. A time- and frequency-domain analysis of the acceleration signals showed that the peak value of the signal increases with the increasing strength of the pulse burst and that the frequency spectra of the signals measured under various pulse bursts have characteristic frequencies (at approximately 2 Hz, 32 Hz, 45 Hz, and 55 Hz). Furthermore, we processed the data through multivariate nonlinear regression analysis and variance analysis and determined that the peak value of the signal scales with the logarithm to the base 10 of EN x, where x is a value that scales with the logarithm to the base 10 of intraburst frequency (f). These results indicate that for high-frequency nanosecond pulse treatment of solid tumors in or near muscles, when the field strength is relatively high, the intraburst frequency and the intraburst pulse number require appropriate selection to limit the strength of muscle contraction as much as possible.
Entities:
Keywords:
acceleration signal; dose effect; function relation; high-frequency nanosecond pulse bursts; rabbit muscle contractions; spectrum distribution
When treating tumors with a pulsed electric field, the undesirable side effect of muscle
contraction inevitably arises.[1,2] Muscle contraction is caused by the direct stimulation of the surrounding muscles and
indirect stimulation of the innervation nerve of the muscle.[3-8] For example, when a tumor is treated using a conventional microsecond pulse, the
animal’s muscles undergo a tetanic contraction, and the contraction frequency is consistent
with the applied pulse frequency.[7] By injecting muscle relaxants, the degree of muscular tetanic contraction can be
reduced to a certain extent but cannot be completely eliminated.[9,10] In the course of the treatment with nanosecond pulses, it is necessary to impose a
pulsed electric field with a relatively high field strength into the tumor tissue by means
of an electrode. The high field strength can easily cause surface discharge on the surface
of the target tissue.[11] These drawbacks adversely affect the smooth progress of the treatment process and the
reliability of the treatment equipment.[1,12,13]To address the abovementioned problems and combine the advantages of traditionally used
microsecond pulses and nanosecond pulses, we proposed a new high-frequency nanosecond pulse form.[14] This new pulse form is proposed based on the following reasons. First, due to the
disadvantage that a high electric field strength can easily cause surface discharge in the
application of ordinary low-frequency nanosecond pulses, it is necessary to reduce the field
strength. Lowering the field strength will reduce the effect of tumor treatment. According
to the theoretically established relationship between biological effects and the field
strength, pulse width, number of pulses, and pulse frequency proposed by Schoenbach
et al,[15] the treatment effect can be improved by increasing the pulse frequency. Considering
that the thermal effect is significant under continuous pulses, we propose the form of
high-frequency nanosecond pulse bursts. In addition, the intraburst pulse numbers can be
appropriately increased to improve the therapeutic effect.This pulse is in the form of microsecond pulse-modulated nanosecond pulses and is expected
to induce both apoptosis and to stimulate irreversible electroporation to achieve the
purpose of treating a tumor. Our previous cell and animal experiments using high-frequency
nanosecond pulses showed that this pulse form can effectively kill tumor cells and inhibit
the growth of tumors in vivo.[16] These findings show that this type of pulse currently has a certain application
potential for the treatment of tumors. To some extent, similar to high-frequency microsecond pulses,[3,4,17,18] the muscle contraction arising from high-frequency nanosecond pulses can be reduced
by optimizing the pulse parameters. Therefore, to provide reference data for the selection
of parameters for high-frequency nanosecond pulsed electric field treatment of tumors, it is
necessary to study the effects of various high-frequency nanosecond pulse-burst parameters
on muscle contraction.At present, there is no systematic study of the strength of muscle contraction under the
action of nanosecond pulses. Multiple experimental studies have been conducted on the
phenomenon of muscle contraction under the action of a microsecond pulsed electric field.
Arena et al
[3] applied one hundred eighty 1000 to 4000 V/cm, 250 kHz/500 kHz high-frequency
microsecond pulses and traditional microsecond pulses to the brain tissue of Fisher 344
rats. In the experiment, the muscle contraction signals were measured using an accelerometer
sutured to the dorsum of each rat, and the muscle contraction signals measured in the 2
cases were compared. The results show that compared to conventional microsecond pulses,
high-frequency microsecond pulses under each parameter do not produce detectable muscle
contractions, but higher field strengths are required to achieve a similar tissue ablation
area. Dong et al
[19] performed rabbit liver ablation experiments using plate electrodes to apply
high-frequency bipolar microsecond pulses with different pulse widths (1-50 μs). In the
experiment, an accelerometer is fixed on the belly of the rabbit to measure the intensity of
muscle contraction. They found that high-frequency bipolar microsecond pulses with a pulse
duration of 5 μs and an electric field intensity of 2000/cm had a good ablation effect and
caused a lesser extent of muscle contractions in the animals. Miklavcic et
al
[7] used a train of eight 100-μs rectangular pulses at various frequencies (1-5 kHz) to
treat Wistar rats. The relationship between the pulse frequency and the muscle contractility
was studied. With increasing frequency, the intensity of muscle contraction first increased
and then decreased. At the same time, the efficiency of the in vivo
treatments of tumors by electrochemotherapy are similar regardless of the pulse frequency
applied. To systematically study the effects of multipulse parameters on muscle contraction
and consider the fact that in vivo experiments can more accurately reflect
muscle contraction strength when treating tumors, we explored the dose effect of an
in vivo muscle contraction with various parameters of high-frequency
nanosecond pulses.Our study is based on the fact that muscle contraction occurs via the effect of leakage
current. Therefore, we hypothesize that through pulse parameter adjustment, the muscle
contraction strength in the actual tumor treatment can be limited to a low level. Many
combinations of pulse-burst parameters exist that can be used to specify high-frequency
nanosecond pulses. Therefore, we explored the influence of various parameters (field
intensity, intraburst frequency, and intraburst pulse number) of high-frequency nanosecond
pulse bursts on the muscle contraction of the biceps femoris in rabbits in
vivo. In addition, the intensity of muscle contraction under a set of microsecond
pulse parameters was measured as a control in this study. The results of this work can
provide a reference for the subsequent selection of parameters for the treatment of tumors
using high-frequency nanosecond pulsed electric fields.
Materials and Methods
Experimental Subjects
Seven male New Zealand white rabbits with body weights between 2.3 and 2.5 kg were used
as the experimental subjects. The rabbits were obtained from the experimental animal
center of Medical University of Chongqing (license number SYXK [Yu] 2012-0001) and were
fed with a mixture of roughage and a nutrition diet in individually ventilated cages in a
temperature-controlled room. All the protocols were approved by the Ethics Committee of
The First Affiliated Hospital of Chongqing Medical University (approval number 20172101),
and the experiment strictly enforced the relevant regulations on the management of
experimental animals in China.
Experimental Procedure In Vivo
Ten minutes before the treatment, the rabbits were anesthetized with pentobarbital sodium
injection (30 mg/mL) at 1 mL/kg dose along the rabbit ear vein. The duration of anesthesia
was approximately 1 hour. After the experiment was completed, the rabbits generally
recovered from the anesthetic within approximately 20 minutes. After recovery, the rabbits
exhibited a normal state of action, and no changes in the motor function of the stimulated
thigh were observed.The selected pulsed electric field stimulation site was the rabbit thigh bicep skin
surface. After the animal was anesthetized, the skin on one side of the thigh was shaved,
and the remaining hair was removed using a depilatory. The animals were placed in a prone
position on an experimental animal holder that constrained their limbs in a natural
position. The surface skin of the biceps femoris was gently lifted and then clamped using
a pair of plate electrodes. The selected electrode was a CUY650P3 plate electrode (BEX Co
Ltd., Itabashi-Ku, Tokyo, Japan) with an electrode diameter of 3 mm. The electrode spacing
was maintained at approximately 1.2 mm as measured using a Vernier caliper.The measurement of muscle contraction signals can be achieved with a variety of sensors.[20,21] Here, we used an accelerometer (ADXL335; Analog Devices Inc, Norwood,
Massachusetts) to measure the acceleration signal to assess the muscle contraction
intensity. The ADXL335 is a 3-axis accelerometer that can be attached to the skin of the
muscle using double-sided adhesive.[20] The original acceleration signal was collected and stored for subsequent analysis
using a MDO3024 oscilloscope (Tektronix Inc, Beaverton, Oregon). Data acquisition lasted
20 seconds at a sampling frequency of 5 kHz. Figure 1 shows a diagram of the experimental system.
To ensure repeatability of the experiment, the relative positions of the animal, the
experimental animal holder, the plate electrode, and the acceleration sensor were kept
fixed as much as possible.
Figure 1.
Diagram of the experimental system.
Diagram of the experimental system.The pulsed electric field was generated using a customized high-frequency nanosecond
pulse generator that can output an independently controlled voltage, intraburst frequency,
and intraburst number of pulses according to the experiment specifications. The output
voltages and currents were measured using a WavePro 760Zi-A oscilloscope (Teledyne LeCroy
Inc, Chestnut Ridge, New York) with a PPE 5 kV high-voltage probe and a Pearson Current
Probe 6600 (Pearson Electronics Inc, Palo Alto, California). In each experiment, we fixed
the applied number of pulse bursts to 10 and the single pulse width to 250 nanoseconds.
The variable pulse parameters were the field strength, intraburst frequency, and
intraburst number of pulses. Figure
2 shows an experimental record of the pulse voltage and current waveform on the
load.
Figure 2.
Measured voltage and current waveforms of the electric pulses.
Measured voltage and current waveforms of the electric pulses.
Pulse Protocols
According to our previous simulation results and related literature,[22-24] at a low field strength, a wide (hundreds of nanoseconds) nanosecond pulse is
required to electroporate the cells to effectively kill the tumor cells. Relative to the 3
parameters of field strength, intraburst frequency, and intraburst pulse number, the pulse
width selection range is narrow. Therefore, the pulse width of the high-frequency
nanosecond pulse is fixed at 250 nanoseconds in this study. We used a 3-factor, 3-level
comprehensive test method to perform the muscle contraction experiment. For each of the 3
parameters, 3 levels were selected (Table 1). Because, an intraburst frequency does not exist for 1 intraburst
pulse, there are a total of 21 valid parameter combinations. Ten bursts of high-frequency
nanosecond pulses were delivered to the skin for electric field stimulation at a 1 Hz
interburst frequency. In the course of each experiment, the left hind leg or the right
hind leg of each experimental rabbit were tested for all 21 parameter combinations. To
prevent errors caused by muscle fatigue on the experimental results, the interval between
conducting 2 adjacent experiments on the same rabbit leg was 2 minutes.
Table 1.
Experimental Factors and Levels.
Factor
Level
1
2
3
Field strength, E/(kV·cm−1)
1
4
8
Intraburst frequency, f/(Hz)
10 k
100 k
1 M
Number of intraburst pulses, N
1
10
100
Experimental Factors and Levels.In addition, to compare the relative strength of muscle contraction induced by
high-frequency nanosecond pulse bursts and conventional microsecond pulses, we selected a
set of microsecond pulse parameters (field strength 2 kV/cm, pulse width 100 μs) as a
control. Accordingly, 10 microsecond pulses were applied to the rabbit skin for electric
field stimulation at a frequency of 1 Hz in each experiment.
Data Processing and Statistical Analysis
Because the original acceleration signal contained a substantial amount of useless noise
interference, we processed the original acceleration signal using MATLAB to obtain a valid
acceleration signal. In each experiment, 10 bursts of high-frequency nanosecond pulses
under each group of parameters resulted in 10 acceleration signals. First, the signal was
digitally filtered through a 1-200 Hz bandpass filter. Next, a 50 Hz digital frequency
trap was used to filter out the power frequency signal interference. We then calculated
the synthetic acceleration module value signal (subsequently referred to as the
acceleration signal) as follows:where a, a, and a are the recorded acceleration values in the x-,
y-, and z-directions, respectively. Finally, the 10
acceleration signals were synchronously averaged to further reduce the random signal
interference. To compare the time–domain response of the acceleration signals under
various pulse parameters, we set a threshold equal to 0.01 g to correspond to the onset of
the averaged acceleration signals. The averaged acceleration signals with durations of 0.6
seconds were used for subsequent analysis. All data were statistically analyzed using SPSS
version 19.0. The data are presented as the mean (standard deviation, [SD]) of 9
independent experiments, and the significance of the indexes between the different
parameter groups was tested.
Results
Time–Domain Waveform of the Muscle Contraction Acceleration Signal
Figure 3 shows the time–domain
signal of muscle contraction measured for all 21 groups of parameters in an independent
experiment. No effective muscle contraction acceleration signal was detected in 8
parameter groups including the parameter group when the intraburst number of pulses was 1
(3 groups in total) and 5 other relatively weak parameter groups. For other parameter
groups, the signals in Figure 3A and
B look very similar and show an increase in Figure 3C. In addition to the 2 groups of parameters
(the third set of parameters in the legend of Figure 3B and the seventh set of parameters in the
legend of Figure 3C), the
acceleration trend of the acceleration signal under different parameters is consistent.
The deviations of the 2 lines are caused by the relatively low or strong amplitude of the
muscle contraction signal, resulting in a different onset of the averaged acceleration
signals. For other independent experiments, the acceleration signal also follows a similar
pattern.
Figure 3.
Typical examples of acceleration signals of muscle contraction at various intraburst
frequencies: (A) 10 kHz, (B) 100 kHz, and (C) 1 MHz. Each curve in the subfigure
represents a single observation. Note that subfigure C is on a different scale on the
ordinate.
Typical examples of acceleration signals of muscle contraction at various intraburst
frequencies: (A) 10 kHz, (B) 100 kHz, and (C) 1 MHz. Each curve in the subfigure
represents a single observation. Note that subfigure C is on a different scale on the
ordinate.
Statistical Histogram of the Peak Value of the Acceleration Signal
The peak value of the acceleration signal was taken as the characteristic quantity to
allow the influence of various pulse parameters on the muscle contraction strength to be
analyzed. Figure 4A-C clearly
shows that the mean value of the peak of the acceleration signal increases as the
intraburst frequency, field strength, and intraburst number of pulses increase. However,
the degree of increase differs at different levels. As shown in Figure 4, the peak value of the muscle contraction
signal increases as the field strength increases, but the significant difference of this
increase is weaker at higher intraburst frequencies; with the increase in the intraburst
number of pulses, the peak value of muscle contraction signal also increases, but the
significant difference of this increase is basically not affected by the intraburst
frequency.
Figure 4.
Peak value of the acceleration signal of the muscle contraction at various intraburst
frequencies: (A) 10 kHz, (B) 100 kHz, and (C) 1 MHz. Note that the results
corresponding to 1 intraburst pulse in subfigures A, B, and C are the same because an
intraburst frequency does not exist in this case (*P < .05,
**P < .01). ‘a’ represents no statistically significant
difference.
Peak value of the acceleration signal of the muscle contraction at various intraburst
frequencies: (A) 10 kHz, (B) 100 kHz, and (C) 1 MHz. Note that the results
corresponding to 1 intraburst pulse in subfigures A, B, and C are the same because an
intraburst frequency does not exist in this case (*P < .05,
**P < .01). ‘a’ represents no statistically significant
difference.In addition, we measured the acceleration signal of muscle contraction under the action
of a conventional microsecond pulse. The peak value statistics are shown in Figure 5. The peak value statistical
results for the high-frequency nanosecond pulse burst with the strongest dose (250 ns, 1
MHz, 8 kV/cm, 100 p) was also presented for comparison. The peak value of the acceleration
signal of the muscle contraction caused by the microsecond pulse is significantly larger
than that of the high-frequency nanosecond pulse burst (P < .01).
Because the pulse parameters used in the experiment are limited, the relationship between
the muscle contraction strength and the parameters can be obtained by numerical
interpolation of the existing experimental data. Figure 6A-C shows that there is no definite change in
the trend of the peak value of the acceleration signal with the increase in the electric
field strength or the intraburst pulse number at the same intraburst frequency.
Figure 5.
Comparison of the peak value of the acceleration signal of the muscle contraction
under a high-frequency nanosecond pulse burst and a conventional microsecond pulse.
The highest dose parameter and a typical parameter that is commonly used in
irreversible electroporation were selected for the high-frequency nanosecond pulse
burst and the microsecond pulse, respectively (**P < .01).
Figure 6.
Three-dimensional relationship among the peak value of the acceleration signal of the
muscle contraction, the electric field intensity and the intraburst number of pulses
at various intraburst frequencies: (A) 10 kHz, (B) 100 kHz, and (C) 1 MHz.
Comparison of the peak value of the acceleration signal of the muscle contraction
under a high-frequency nanosecond pulse burst and a conventional microsecond pulse.
The highest dose parameter and a typical parameter that is commonly used in
irreversible electroporation were selected for the high-frequency nanosecond pulse
burst and the microsecond pulse, respectively (**P < .01).Three-dimensional relationship among the peak value of the acceleration signal of the
muscle contraction, the electric field intensity and the intraburst number of pulses
at various intraburst frequencies: (A) 10 kHz, (B) 100 kHz, and (C) 1 MHz.According to the 3-dimensional (3D) relationship, one can also obtain the contour line
for a certain value of acceleration peak (Figure 7A). During the course of the experiment, when the peak of the
acceleration caused by muscle contraction in rabbits was <0.15 g, weak muscle
contraction or no visible muscle contraction was observed during the course of the
experiment. The region below the contour is the parameter range in which the peak value of
the acceleration signal is less than the threshold value. Furthermore, we obtained a 3D
contour surface as shown in Figure
7B.
Figure 7.
Contour lines and 3D contour surface for the peak value of 0.15 g of the acceleration
signal of the muscle contraction under various electric field intensities, intraburst
frequencies, and intraburst number of pulses: (A) contour lines and (B) 3D contour
surface.
Contour lines and 3D contour surface for the peak value of 0.15 g of the acceleration
signal of the muscle contraction under various electric field intensities, intraburst
frequencies, and intraburst number of pulses: (A) contour lines and (B) 3D contour
surface.
Acceleration Signal in the Frequency Domain Under Various Pulse Parameters
The amplitude spectrum of the acceleration signal (Figure 3) under different parameters can be obtained
via fast Fourier transform as shown in Figure 8. In the frequency domain, the trends of the acceleration signals are
consistent. In addition, the acceleration signal frequency is distributed primarily below
60 Hz. Except for the slight difference in the results for the 2 parameters mentioned
above, the amplitude spectrum of the acceleration signal contains characteristic
frequencies at approximately 2 Hz, 32 Hz, 45 Hz, and 55 Hz. These results show that the
high-frequency nanosecond pulse-induced muscle contraction is determined primarily by the
resonance frequencies of the muscle tissue.[20,25,26] For other independent experiments, the amplitude spectrum of the acceleration
signal follows a similar law.
Figure 8.
Amplitude spectrum of the acceleration signal (Figure 3) of the muscle contraction for the
high-frequency nanosecond pulse bursts of various parameters.
Amplitude spectrum of the acceleration signal (Figure 3) of the muscle contraction for the
high-frequency nanosecond pulse bursts of various parameters.
Relationship Between the Peak Value of the Acceleration Signal of the Muscle
Contraction and the Dose of the Pulsed Electric Field
To further analyze the effect of the 3 parameters on the effect of muscle contraction, we
used the multiparameter variable method to quantitatively analyze the trend of muscle
contraction acceleration intensity and the 3 parameters. Here, we assume that the peak of
the acceleration signal caused by muscle contraction at the same intraburst frequency is
proportional to the injected pulse energy EN(1/2). Taking the logarithm of
pulse energy as the abscissa, we plot the relationship curve under intraburst frequencies
of 10 kHz, 100 kHz, and 1 MHz (Figure
9A). The peak value of the acceleration signal increases with increasing
pulse-injection energy at the frequency of the same intraburst frequency; however, the
proportional relationship between the peak value of the acceleration signal and the
injected energy is not easily detected. In addition, a threshold effect of muscle
contraction is observed; that is, the effective muscle contraction signal is detected when
the pulse-injected energy exceeds a certain value. Similarly, using the logarithm of the
pulse charge EN(1) as the abscissa, we also plot the relationship curve (Figure 9B); the proportional
relationship between the peak value of the acceleration signal and the amount of injected
pulse charge is less pronounced.
Figure 9.
The relationship between the peak value of the acceleration signal of the muscle
contraction and the pulsed electric field dose when using (A) pulse-injection energy,
(B) pulse-injection charge, (C) pulse-injection dose
EN(0.1174*log(f)), and (D) pulse-injection dose
EN(0.1844*log(f)-0.4448) as the abscissa.
The relationship between the peak value of the acceleration signal of the muscle
contraction and the pulsed electric field dose when using (A) pulse-injection energy,
(B) pulse-injection charge, (C) pulse-injection dose
EN(0.1174*log(f)), and (D) pulse-injection dose
EN(0.1844*log(f)-0.4448) as the abscissa.We assume that the peak of the acceleration signal caused by muscle contraction is
proportional to the pulse-injection dose, EN, where the index of the intraburst number of pulses x is a
variable related to the intraburst frequency. According to the relevant literatures,[15,27] the pulse-injection dose here represents an electrical impact dose factor.
Furthermore, we assume that the following function relation is satisfied:where x, y, and z are undetermined
coefficients. The derivation of this equation is based on the combination of the
experimental results and characteristics of the parameter values. Considering that both
the values of intraburst frequency (f) and intraburst pulse number (N) have a 10-fold
relationship, we take the logarithm to the base 10 of the intraburst frequency as well as
the pulse-injection dose EN. Moreover, from the experimental results obtained, we found that the peak value
of the acceleration signal and the pulse–injection dose in logarithm form can be well
fitted by a linear relationship. Using MATLAB, the multivariate nonlinear regression of
the peak data of the effective acceleration signal can be fitted to obtain the
quantitative function:Using the pulse–injection dose in relation to the intraburst frequency
EN(0.1174×log(f)) as the abscissa, we plot the relationship curve (Figure 9C). The experimental data at
different frequencies are well fitted by the function (the R
2 is .8524), and the distribution of experimental data at different frequencies
is also relatively concentrated.The N-index for the function fitting is linearly related to the logarithm of the
intraburst frequency (f). When other indices are selected, a better-fitting relationship
with the experimental data can be obtained. If a coefficient is added to the exponent of
N, the fitting function becomesBy performing multiple nonlinear regression for the peak data of the effective
acceleration signal, the improved fitting function formula is obtained:Figure 9D shows that the
experimental data of the acceleration signal peak coincide better with the fitting curve
(the R
2 is .9309). Correspondingly, Table 2 shows the statistical data arranged
according to the functional relationship for various intraburst frequencies.
Table 2.
The Peak Value Statistics of the Acceleration Signal of Muscle Contraction.
10 kHz
100 kHz
1 MHz
EN(0.2927)/(kV·cm−1)
a/(g)
EN(0.4770)/(kV·cm−1)
a/(g)
EN(0.6613)/(kV·cm−1)
a/(g)
1
0.0039 (0.0002)
1
0.0039 (0.0002)
1
0.0039 (0.0002)
1.962
0.0037 (0.0002)
2.999
0.0042 (0.0006)
4
0.0041 (0.0005)
3.849
0.0041 (0.0006)
4
0.0041 (0.0005)
4.585
0.0068 (0.0077)
4
0.0041 (0.0005)
8
0.0058 (0.0057)
8
0.0058 (0.0057)
7.848
0.0060 (0.0036)
8.995
0.0521 (0.0367)
18.338
0.1176 (0.0366)
8
0.0058 (0.0057)
11.997
0.0805 (0.0352)
21.018
0.1477 (0.0703)
15.696
0.0922 (0.0371)
23.993
0.1390 (0.0563)
36.677
0.1760 (0.0821)
15.398
0.0830 (0.0304)
35.980
0.1630 (0.0437)
84.073
0.2097 (0.0934)
30.796
0.1954 (0.0527)
71.960
0.2040 (0.0651)
168.147
0.3124 (0.0802)
The Peak Value Statistics of the Acceleration Signal of Muscle Contraction.A multiple-factor analysis of variance can be performed on all 27 groups of data to
further analyze the main and interaction effect of the factors as shown in Table 3. Except for the lack of a
significant interaction effect between the field strength and the intraburst frequency,
the main effects of the 3 factors and the second- and third-order interaction effects are
significant. The F-test value of the intraburst number of pulses is the
largest, which indicates that the main effect is the largest, followed by the field
intensity and the intraburst pulse frequency.
Table 3.
Tests of Between-Subject Effects.
Source
Type III Sum of Squares
Degree of Freedom (df)
Mean Square
F-statistic
Sig.
Corrected Model
1.853
26
0.071
42.442
.000
Intercept
1.375
1
1.375
819.093
.000
Electric field strength (E)
.412
2
0.206
122.645
.000
Number of intraburst pulses (N)
.895
2
0.447
266.369
.000
Intraburst frequency (f)
.173
2
0.086
51.419
.000
E × N
.209
4
0.052
31.094
.000
E × f
.013
4
0.003
2.007
.095
N × f
.119
4
0.030
17.789
.000
E × N × f
.032
8
0.004
2.384
.018
Error
.363
216
0.002
Total
3.591
243
Corrected Total
2.216
242
Tests of Between-Subject Effects.
Discussion
Relative to the microsecond pulses with a pulse width of 50 to 100 microseconds, the use of
shorter (submicrosecond or even nanosecond) pulses can significantly inhibit muscle contraction.[4,17] For a pulse form of high-frequency nanosecond pulse bursts, appropriate parameter
selection is particularly important for improving efficacy in the treatment of tumors while
minimizing muscle contractions.An acceleration sensor can be used to evaluate the characteristics of muscle contraction,
the acquisition of motion information, the measurement of the vibration of the object, and
so on.[20,25,26,28-31] Based on this background, we explored the dose effect of various parameters of
high-frequency nanosecond pulse bursts on the muscle contraction strength. We measured the
muscle contraction acceleration signals induced by electric stimulation on the surface skin
of rabbits’ biceps femoris in vivo. Based on the abovementioned
experimental results and analysis, we conclude that the muscle contraction strength
increases with increasing electric field strength, intraburst number of pulses, and
intraburst frequency. This result is different from that of the study by Miklavcic
et al who found that the intensity of muscle contraction first increased
and then decreased with increasing pulse frequency.[7] This difference may be caused by the different pulse protocols applied. The duration
of a single high-frequency nanosecond burst used in this study is relatively short (less
than 10 milliseconds), and muscle contraction generally reflects a cumulative effect that
increases with increasing pulse frequency. Thus, as the intraburst frequency increases, the
peak of the acceleration signal caused by muscle contraction is expected also to increase.
However, the frequency spectra of the acceleration signal measured under different pulse
bursts are similar. This finding demonstrates that high-frequency nanosecond pulse-induced
muscle contraction is determined primarily by the resonance frequencies of the muscle tissue.[20,25,26]A multiparameter regression analysis shows that the muscle contraction strength under
high-frequency nanosecond pulse bursts can be approximated as a function of the
frequency-dependent pulse-injection dose EN. The higher the intraburst frequency, the larger the value of the exponent
x. If linear regression fitting is performed on the peak value of the
effective acceleration signal, then a similar fitness can be achieved. However, the
intraburst frequency has no effect on the pulse form in the case of a single intraburst
pulse, indicating that the intraburst frequency (f) is a better choice as an exponent. In
addition, a saturation effect of muscle contraction is clearly detected as reflected in the
logarithm of the pulse–injection dose in the formula. According to the relationship between
these 3 parameters, we can better guide the selection of pulse parameters in the treatment
of tumors with high-frequency nanosecond pulse bursts.
Conclusion
According to the study results, we draw the following conclusions: with increasing field
intensity, intraburst frequency, and intraburst pulse number, the muscle contraction
strength increases, whereas muscle contraction does not occur with weak parameters. The
amplitude spectra of the acceleration signal are consistent and are distributed primarily
below 60 Hz. From a quantitative perspective, we obtained a dose relationship between the
pulse-burst parameters and the animal muscle contraction strength. The results demonstrated
that muscle contraction under a high-frequency nanosecond pulse burst mainly reflects a
cumulative effect. With the increase in the pulse dose, the muscle contraction intensity
increases; however, a certain saturation effect exists. The results of this study provide a
reference for the selection of a high-frequency nanosecond pulsed electric field in the
treatment of tumors and indicate that the pulse parameters should be considered
systematically in pulse protocols designed to minimize the strength of muscle
contraction.
Authors: Damijan Miklavcic; Gorazd Pucihar; Miran Pavlovec; Samo Ribaric; Marko Mali; Alenka Macek-Lebar; Marko Petkovsek; Janez Nastran; Simona Kranjc; Maja Cemazar; Gregor Sersa Journal: Bioelectrochemistry Date: 2004-12-10 Impact factor: 5.373
Authors: Richard Nuccitelli; Joanne Huynh; Kaying Lui; Ryan Wood; Mark Kreis; Brian Athos; Pamela Nuccitelli Journal: Int J Cancer Date: 2012-10-17 Impact factor: 7.396
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