Percutaneous Peripheral Nerve Stimulation of Gluteus Nerves to Improve Hip Strength and Power

This study delves into the comparative efficacy of two modalities of nerve stimulation for enhancing muscular strength and power: the percutaneous application of electrical current via acupuncture needles versus traditional transcutaneous electrical nerve stimulation (TENS). The overarching objective is to discern whether percutaneous peripheral nerve stimulation (pPNS), guided by ultrasound, facilitates superior gains in muscle strength and power in the gluteal muscles compared to conventional TENS.

Participants, suffering from chronic knee pain, were systematically randomized into two cohorts: the experimental group underwent ultrasound-guided pPNS targeting the superior and inferior gluteal nerves, whereas the control group received TENS. The experimental setup was meticulously designed to ensure the sole variable of distinction between groups was the method of electrical stimulation applied. pPNS was delivered using a biphasic asymmetric electric current, set to a frequency of 10 Hz, a pulse width of 240 microseconds, and an intensity tailored to achieve maximal muscle contraction without inducing pain, based on a protocol of ten 10-second stimulations interspersed with 10-second rest periods. This regimen was predicated on prior findings demonstrating its efficacy in augmenting isometric strength following femoral nerve stimulation. The control group was subjected to a parallel protocol, differing only in the application technique, wherein electrodes replaced needles, adhering to the same stimulation parameters.

The therapeutic efficacy of both interventions was assessed through a rigorous evaluation of strength and power before and after the administration of therapy. This assessment employed a linear encoder to measure peak strength and concentric power during the Hip Thrust exercise, a method chosen for its reliability in quantifying these parameters. The procedure entailed performing the exercise under three different loads (30%, 50%, and 70% of the participant's maximum capacity, 1RM), with the evaluation aimed at capturing the concentric peak power in each repetition until a noticeable decline in performance was observed.

The hypothesis posits that pPNS, by virtue of its targeted and invasive nature, will yield greater improvements in muscle strength and power than TENS, attributed to its more direct stimulation of the nerve fibers and the encompassing muscle groups. The underpinning rationale is that pPNS's ultrasound-guided approach allows for a more precise delivery of electrical current to the nerves, potentially overcoming limitations associated with the superficial and diffuse application of TENS.

For the analysis of the collected data, an initial evaluation of distribution characteristics will be performed utilizing visual tools such as Q-Q plots and density plots, complemented by statistical measures of kurtosis and skewness to understand the data's underlying structure. The Shapiro-Wilk test will be applied to assess the normality of residuals, ensuring the validity of subsequent statistical tests. Descriptive statistics, including the mean, median, mode, and standard deviation of the collected quantitative measures, will be thoroughly examined to summarize the data effectively. Additionally, the homogeneity of these variables across the dataset will be scrutinized.

Regarding inferential statistics, an exploratory approach will be adopted to estimate confidence intervals and discern trends in the data, particularly focusing on pre- and post-treatment differences both within individual subjects and between the groups. Due to the anticipation of non-normal data distribution and the structure of the study design (pretest-posttest control group), non-parametric statistical tests will be employed for the analysis. Specifically, the Mann-Whitney U test will facilitate between-group comparisons, while the Wilcoxon test will be used for related measurements to detect changes within groups over time.

Data analysis and visualization efforts will be supported by SPSS 23.0 software (SPSS Inc., IBM Chicago, IL, USA) and/or GraphPad Software (San Diego, CA, USA). For the interpretation of results, a 95% confidence interval and an alpha level of 0.05 will be established as thresholds for statistical significance. The creation of figures and graphical representations of the findings will be executed using Adobe Illustrator (San José, CA, USA), ensuring that the visual presentation of data is both clear and informative. This comprehensive approach to data analysis and visualization aims to elucidate the potential differences in efficacy between percutaneous peripheral nerve stimulation and transcutaneous electrical nerve stimulation in enhancing muscle strength and power, guiding future research and clinical applications in the field.