Introduction
Homeostasis is an essential mechanism that must be preserved in all organic systems, including skeletal muscle since it plays a magnanimous role in maintaining their integrity. Skeletal muscle, which we will study in the present research, undergoes continuous dynamical changes in response to injuries, ageing processes, pathologies, and physical exercise per se [1]. A common underlying feature for all these processes of them is inflammation. The inflammatory response has two main phases, the pro-inflammatory phase, with infiltration of leukocytes and the anti-inflammatory phase, where skeletal muscle regenerates [2,3]. Recovery of damaged tissue is primarily controlled by macrophages, which orchestrate the inflammatory response [4–6]. Cytokines, chemokines, pro-and anti-inflammatory proteins, leukocytes, and phagocytes act in the inflammatory process after muscle injury [4,7].
There are two main inflammatory processes: acute and chronic inflammation. Acute inflammation has a fast onset and an equally fast resolution. However, chronic inflammation does not achieve complete recovery, with macrophages and lymphocytes being the primary cells involved [8,9]. Both are responsible for producing cytokines and chemokines as the primary chemical mediators of this type of inflammation. In fact, in chronic inflammation and contractile dysfunction, IL-1β (Interleukin 1β) and TNFα (Tumour Necrosis Factor α) play a crucial role [10]. In addition, ROS (Reactive Oxygen Species) derived from muscle and NO (Nitric Oxide) play a part in force decrement, causing muscle atrophy [11]. On the other hand, IL-6 (Interleukin 6) is a critical inflammatory cytokine in the inflammatory process that facilitates muscle atrophy by decreasing its anabolism [1]. If the agent causing the inflammation cannot be removed, or if there is any interference with the healing process, an acute inflammatory response can progress to the chronic stage. Repeated episodes of acute inflammation can also lead to chronic inflammation. The response to sudden body damage is to send inflammatory cells to the injury. These cells start the healing process. In chronic inflammation, the body continues to send inflammatory cells even when there is no danger from the outside. Techniques that can reduce or eliminate chronic inflammation by repairing the damaged area in the future should be a priority in bodily injury research [8,9].
Cytokines and chemokines are small proteins released by our cells that act as messengers between the different cells of the immune system. They are responsible for coordinating an effective immune response according to infection and regulating inflammation. They could activate, attract, and direct diverse families of circulating leukocytes to damaged sites [12,13]. Cytokines and Chemokines not only participate in the coordination of leukocyte movement in inflammatory processes but are also important in multiple physiological and pathological processes: development of the immune system; surveillance, memory, immune response, and regulation; inflammation; embryogenesis, angiogenesis, and organogenesis; nervous system development and function; germ cell migration; cancer development and metastasis [12,13].
Coordination between inflammatory and regenerative processes would be necessary to reduce the inflammatory response to increase functional muscle recovery. In recent years, physical therapists and medical specialists have used Ultrasound-guided electrolysis (USGET). This technique produces a non-thermal electrolytic ablation that induces a controlled inflammatory response, allowing the activation of cellular mechanisms involved in phagocytosis and regeneration of damaged soft tissue [14,15]. USGET technique is a recovery method to improve performance. The technique uses a galvanic current to produce a chemical reaction, which causes the dissociation of sodium chloride and water molecules [15–17]. Moreover, it facilitates wound healing in the patellar tendon and damaged muscle in rats [16,17]. Furthermore, the main and most current accepted theory is that galvanic current has been found to activate the inflammasome to promote the production of type I collagen in the tendon. [14]. Nonetheless, there are not many studies on the action of the USGET technique at a biochemical and physiological level that can explain the effects previously indicated. Therefore, this study aimed to explore the effects of the USGET technique on muscle damage and inflammation. Our experimental study aimed at seven days of Notexin-induced injury, determining the action of the USGET technique in recovering from muscle damage. Notexin (from snake venom), a pre-synaptic phospholipase A2 neurotoxin, is known to induce both destruction and regeneration of skeletal muscle fibres, giving a reliable model of skeletal muscle injury-regeneration in rat [7,18–20] and mouse [21]. Although notexine has neurotoxic effects due to its presynaptic action, myotoxic effects and myoglobinuria have also been described. In addition, it can act as a procoagulant causing prothrombin cleavage. This procoagulant action precedes the muscular toxic effects [22–24]. Furthermore, we tested if the application of USGET after notexin-induced muscle damage could act as a defensive technique on rat muscle. Another aspect studied was the inflammatory state and the possible recovery in exercise performance after applying the USGET technique.
Material and methods
Notexin administration and USGET technique
Twenty female Wistar rats (weight 200–250 g; age 7 months) (a minimum of 20 rats were necessary for environment and protein expression measurement) were randomly divided into 3 groups with 5 in each group, including: control (C), notexin (NOT), and notexin with USGET (6 mA) (NOT+USGET). The rats (with and without notexin) were fed ad libitum on a standard diet (Letica, Barcelona, Spain) and were kept on a 12-h light/12-h dark cycle with room temperature maintained at 22ºC. When notexin was used, only one leg was injected (to prevent a double notexin injection). The application of notexin, by intramuscular injection, was carried out in the central zone of the quadriceps muscle. 200 μl of notexin were injected intramuscularly at 10 μg/ml in the quadriceps to produce muscle injury. Notexin was injected 7 days before USGET application. The rats in control group were injected with 200 μl of saline solution.
The treatment with USGET was carried out during the following 7 days after notexin administration and applied once on the 7th day and once on the 11th day. These days are applied since sufficient days must be left for the notexin to act chronically at the muscular level. The application of electrolysis on day 7 will give an idea of the fast action and 11 days of its later action. Before the injection of notexin and USGET treatment, rats were anesthetized via inhalation (5% inofluoran by induction and 2% maintenance). The application of the USGET was carried out in the same area where the notexin was applied and consisted in the administration of a continuous current of 4 pulses at an intensity of 6 mA for 5 seconds conveyed to the muscle. An acupuncture needle with a 0.32 mm diameter was used as electrode. In experiments not included in the manuscript, different intensities were used (2, 3, 6 and 8 mA), showing that the most suitable was 6 and 8 mA. The seconds were also varied (2, 5, 10), highlighting that it was best to use 5 seconds. Animals were euthanized at the end of the study (pentobarbital 50 mg/Kg) and quadriceps muscle was removed (14th day after notexin administration) and the central area was used to biochemistry determination. All animal procedures were carried out in accordance with the European legislation on the use and care of laboratory animals (EEC 86/609).
Balance beam test
This test was used to assess sensorimotor function and balance in rats. The animals had to pass through a narrow beam (1 x 100 cm) elevated 1’5 m above the floor, reaching a dark box at the end of it. To evaluate the rats’ ability in this test, they were forced by illuminating the beginning of the beam with white light. The time required to reach the escape box at the end of the beam and the number of forelimb and hind-limb paw slips were both recorded. Paw slips are defined as any paw coming off the beam’s top or side. The same day that the test was affected, four trials were performed to familiarize the rats with the beam and the dark box at the end of it. After each trial, the beam and box were cleaned with ethanol.
Grip strength
Grip strength was measured non-invasively by taking advantage of the rat’s instinct to hold on while being pulled backwards gently. This method can evaluate limb grip using a 0.1 cm diameter horizontal bar attached to a force transducer. The time interval the rat was able to hold the bar was recorded, and the latency of grip loss was considered an indirect measure of grip strength [25], holding a maximum cut-off time of 60 seconds. The advantages are that grip strength is reproducible and can be measured repeatedly in rats to detect progressive motor deficits, therapy value and genetic modifications.
Western-blot analysis
Protein extracts from quadriceps were mixed with equal volumes of SDS buffer (0.125 M Tris-HCl, pH 6.8, 2% SDS, 0.5% (v/v) 2-mercaptoethanol, 1% protease inhibitors, 1% bromophenol blue and 19% glycerol) and then boiled for five minutes. Protein concentration was determined using a modified Lowry method [26]. Proteins were separated using SDS-PAGE gels and transferred to polyvinylidene difluoride membranes. These membranes were previously impregnated with methanol in a humid environment using a transfer buffer (25 mM Tris, 190 mM glycine and 20% methanol). Membranes were blocked with 5% BSA in TBS containing 0.05% Tween-20 and then incubated overnight with the corresponding antibodies following the manufacturer’s recommendations. The blots were washed three times with a washing buffer (phosphate-buffered saline, 0.2% Tween 20) for 5 min each and then incubated for one hour with a secondary horseradish peroxidase-linked anti-mouse IgG antibody (Cell Signalling Technologies, Barcelona, Spain). As mentioned above, the blots were washed three times and developed using the enhanced chemiluminescence (ECL) procedure as specified by the manufacturer (Amersham Biosciences, Barcelona, Spain). Auto-radiographic signals were assessed using ImageJ software (NIH Image, National Institutes of Health, Bethesda, MD, USA). The antibodies: monoclonal anti-CCR5 (1:500), monoclonal anti-CCR8 (1:500), monoclonal anti-NFᴋB (1:500), and monoclonal anti-IᴋB (1:500) antibodies were from Abcam Biotechnology, and the monoclonal α-tubulin (1:1000) from Santa Cruz Biotechnology (Madrid, Spain).
Real-time polymerase chain reaction analyses
Quadriceps samples were collected from each rat into an RNAlater solution (Ambion, Austin, TX, USA), an RNA stabilization reagent, following the manufacturer’s instructions. Total RNA was extracted with a Tripure isolation reagent (Roche Molecular Biochemical, Basel, Switzerland). Its concentration and integrity were assessed in RNA 6000 Nano Labchips using Agilent 2100 Bio-analyzer (Agilent Technologies, Foster City, CA, USA). Ready-to-use primers and probes from the assay-on-demand service of Applied Biosystems were used for the quantification of selected target gene: CCL3 (Mm00441259_g1), CCL4 (Mm00443111_m1), CCL5 (Mm01302428_m1), CCR5 (Mm01963251_s1), CCL1 (Mm99999220_Mh), CCR8 (Mm99999115_s1) and endogenous reference gene β-actin (Mm00607939_s1). RNA samples were reverse transcribed using random hexamers and MultiScribe reverse transcriptase (Applied Biosystems). After complementary DNA synthesis, real-time polymerase chain reaction (RT-PCR) was carried out using the ABI Prism 7900HT Sequence Detection System (Applied Biosystems). Samples were run in triplicate, and expression changes were generated by calculating 2-ΔΔCt [27]
Determination of cytokines IL-6, IL-13, and IL-10
Plasma was obtained from the rats and used to determine IL-16, IL-13, and IL-10 cytokine concentrations (pg/ml) using ELISA kits (Pierce Biotechnology, Inc.). The blood was obtained from the lateral vein of the tail (1 ml) post anaesthesia. First, plasma was obtained, using afterwards 100 μl of it for each test.
Data analysis and statistics
All values are expressed as means ± SD. The differences between rat groups were determined with unpaired Student’s t-test. All statistical analyses were performed using Graph-Pad Prism software (GraphPad Software Inc., San Diego, CA, USA). The data were analyzed by parametric ANOVA (the variances are homogeneous). In addition to this, the Scheffe method was used to determine post-hoc pair-wise comparisons. Statistical significance was accepted at a p-value < 0.05.
Results
Motor function
The rat’s ability to pass through a narrow beam showed the difference of activity between control (C), notexin (NOT) and notexin+USGET (NOT+USGET) rats using the beam-walking test. Grip strength test showed that NOT rats presented a significant time reduction compared to C rats. In NOT+USGET rats, a significant time increase was detected compared with the NOT group (Fig 1A). In addition, the number of foot fouls was higher in the NOT group compared with C and NOT+USGET group (Fig 1B). The ability to complete the beam-walking test is shown in Fig 1C. The NOT group spent more time completing this test than the C group. The use of the USGET technique resulted in a reduction of time to complete the test compared with the NOT group (Fig 1C).
[Figure omitted. See PDF.]
A: Grip Strength (time in 60 seconds). B: number of foot faults. C: Time to cross the beam (sec). *p<0.01 vs. control. #p<0.01 vs. notexin.
Expression of IL-6, IL-13, and IL-10 cytokines
Serum from the rats (C, NOT and NOT+USGET) was assayed to determine the cytokines by ELISA. Fig 2A shows that NOT induced a significant increase in IL-6 pro-inflammatory cytokine compared to C rats. Conversely, in NOT+USGET rats, a significant reduction was detected compared with the NOT group. Under our experiments, neither anti-inflammatory cytokines IL-13 nor IL-10 expressed significant differences between C and NOT groups. On the contrary, NOT+USGET showed a significant increase compared with C and NOT groups (Fig 2).
[Figure omitted. See PDF.]
IL-6 (A), IL-13 (B), and IL-10 (C) were determined by ELISA. Values are means ± SD from five independent experiments. *p<0.03 vs. control. #p<0.03 vs. notexin.
Expression of CCL3, CCL4 and CCL5 chemokines
To determine the expression of CCL3, CCL4 and CCL5 pro-inflammatory chemokines, we measured mRNA expression by real-time RT-PCR in quadriceps from rats. The expression in all chemokines analyzed was higher in the NOT group compared to the C group. In addition, chemokine expression (CCL3, CCL4 and CCL5) significantly decreased in the NOT+USGET group compared to the NOT group (Fig 3).
[Figure omitted. See PDF.]
Values are means ± SD from five independent experiments. *p<0.05 vs. control. #p<0.05 vs. notexin.
Protein expression of the CCR5 receptor
CCR5 is the receptor of CCL3, CCL4 and CCL5 chemokines. Western-blot and RT-PCR techniques were used to determine the expression of this receptor. Fig 4 shows that CCR5 expression significantly increased in NOT and NOT+USGET groups compared to the C group. Moreover, CCR5 expression significantly diminished in the NOT+USGET group compared to the NOT group (Fig 4).
[Figure omitted. See PDF.]
A representative immunoblot is shown in the panel. CCR5 and Tubulin cropped from different parts of the different gels. Values are means ± SD from five independent experiments. *p<0.04 vs. control. #p<0.04 vs. notexin.
Protein expression of CCL1 chemokines and its CCR8 receptor
To determine the expression of CCL1 chemokine, we measured mRNA expression by real-time RT-PCR. NOT group presented a significantly reduced expression of CCL1 in comparison with the C group. Furthermore, the NOT+USGET group shows an increment of this chemokine concerning the NOT group. CCR8 is the receptor of CCL1 chemokine. Western-blot and RT-PCR techniques were used to determine the expression of this receptor. Fig 5 shows that CCR8 expression was significantly increased in NOT and NOT+USGET groups compared to C rats. Furthermore, CCR8 expression significantly diminished in the NOT+USGET group compared to the NOT group (Fig 5).
[Figure omitted. See PDF.]
CCR8 and Tubulin cropped from different parts of the different gels. Data are means ± SD from five independent experiments. *p<0.04 vs. control. #p<0.04 vs. notexin.
Protein expression of NFᴋB and IᴋB
The expression of both proteins was tested using the Western-blot technique. Fig 6 shows that the transcription factor NFᴋB was significantly increased after notexin addition compared with the control group. On the contrary, in the NOT+USGET group, significant decrement was detected compared with the NOT group. Moreover, the NOT group presented a decrease in IᴋB protein compared with the control group. On the other hand, when USGET was used, a diminished expression was noted (Fig 6).
[Figure omitted. See PDF.]
NFᴋB, IᴋB and tubulin cropped from different parts of the different gels. Data are means ± SD from five independent experiments. *p<0.05 vs. control. #p<0.05 vs. notexin.
Discussion
The present study evaluated the changes produced using the USGET technique on rats’ damaged muscle induced by notexin. It focuses on the USGET technique’s effect on muscle tissue showing biomolecular mechanism and motor functions. We hypothesize that this technique could protect the damaged muscle from further inflammation, reducing pro-inflammatory proteins and increasing anti-inflammatory proteins, favouring tissue regeneration, motor function, and exercise performance.
In the last years, it has been published that the application of USGET in humans does not show adverse effects on sports performance [28,29], and the technique can be used to improve recovery after muscle damage [15]. Animal studies demonstrated that percutaneous electrolysis applied in an experimentally induced model of Achilles tendinopathy could increase the expression of some genes associated with collagen regeneration and extracellular matrix remodelling [30]. In a human study, high-intensity percutaneous electrolysis was applied (3 shifts of 3 mA × 3 s) and its effects on pain were determined [31], showing that strong electroacupuncture can induce greater analgesic effects than weak electroacupuncture (0.3 mA × 90 s). Supporting our experimental conditions, the protocol that used 3 mA for three seconds and three repetitions in rats was the most effective than other protocols with less mA and less time [32]. In our study (6 mA × 5 sec), after administration of notexin, we noted that USGET treatment reverses inflammatory processes. USGET diminished the expression of pro-inflammatory cytokine (IL-6), chemokines (CCL3, CCL4 and CCL5), and CCR5 and CCR8 receptor expression after notexin addition. Furthermore, USGET treatment decreased transcription factor NF-ᴋB compared with the notexin group. Moreover, an increase of anti-inflammatory mediators such as IL-13 and IL-10 were detected.
The entry of inflammatory cells after muscle injury favours regeneration through the absorption and digestion of necrotic cells and the elimination of waste [33]. In addition, inflammatory cells can produce cytokines, chemokines, and growth factors involved in the muscle damage process and sometimes in posterior regeneration [10,34]. In an early stage of muscle regeneration, inflammation of the damaged muscle can aid regeneration. However, a continuous or excessive inflammation can lead to muscle fibrosis [35,36]. Using techniques to reduce inflammation and its prolongation over time could lead to more significant functional recovery from the injury. In melanoma, neuroblastoma cells and muscle tissue, deleterious notexin action was demonstrated [7,37]. In decreased myogenic expression and subsequent myotube formation, changes in cytokine expression are the most likely explanation. Potentially mitogenic substances for myoblasts are driven by IL-6, IL-1, and TNF-α pro-inflammatory mediators [38,39]. It has also been published that these pro-inflammatory mediators act as myogenic differentiation inhibitors [40].
Furthermore, the addition of IL-6 cytokine to myoblasts in culture increases their proliferation but not cell fusion [41]. The genetic ablation of IL-6 slows muscle growth in a model of compensatory muscle hypertrophy. The gastrocnemius tendon was sectioned to rise packing and growth in the synergistic plantaris muscle in these mice. Furthermore, these authors demonstrate that ablation of IL-6 diminishes muscle growth [42,43]. The decrement in IL-6 expression by USGET treatment will improve muscle regeneration and functional muscle recovery by reducing the inflammatory response. However, the contradiction between our results and the data exposed before is apparent. USGET technique produces, in the beginning, destruction of tissue by cytochrome c and SMAC/diablo [16,17] to eliminate destroyed cells by the injury. However, after a time, USGET contributed to recovery the of muscle damage.
M1 macrophages are pro-inflammatory and responsible for inflammatory signalling, while M2 are anti-inflammatory macrophages that participate in the resolution of the inflammatory process and produce anti-inflammatory cytokines, thereby contributing to tissue healing [44]. M2 macrophages arrive at their peak concentration in muscle regeneration activated by anti-inflammatory cytokines, such as IL-10 and IL-13 [44,45]. Furthermore, IL-10 concentrations increase in muscle, decreasing myofiber injury, when regulatory T cells increase [46]. Our data showed up-regulation of IL-10 mRNA level in tibialis anterior injected with nitric oxide was detected on notexin-induced muscle damage [47].
Chemokines regulate the movement of leukocytes in response to injury and disease. They are small molecules that are liberated to activate the inflammation state. Furthermore, chemokines and their receptors are highly expressed after muscle injury [43,48]. In HIV (human immunodeficiency virus) infection, the role of CCR5 has been mainly studied [49]. This receptor is a major co-receptor for the entry of HIV into target cells [50,51]. Moreover, CCR5 is expressed in other tissues, such as in the CNS [52–54]. Myoblasts constitutively express the CCR5 receptor, and cell proliferation occurs when stimulated with chemokines, CCL3 and CCL4 [55]. An increment in CCL3, CCL4 and CCR5 in injured muscle was detected by different authors [56–58], as shown in our study after notexin addition. Using the USGET technique, we demonstrate a decrease in CCR5 and its chemokines (CCL3, CCL4 and CCL5), showing a possible muscle recovery produced by this technique.
CCL1 was detected after USGET treatment demonstrating muscle recuperation by controlling inflammation and perhaps improving its recovery after damage. Activated monocytes and lymphocytes secrete CCL1. This chemokine is the ligand of CCR8 and is a potent chemoattractant in this kind of cells [59,60]. Our experiments noted changes in CCR8 expression and its chemokine, CCL1, in skeletal muscle after notexin damage compared to the control group. We also detected changes using the PIE technique after notexin damage. We demonstrate an increase in CCL1 expression in NOT+USGET compared to the notexin group and a decrease in its receptor (CCR8) expression. This data indicates a reduction in CCR8 receptor expression to supply upregulation of its chemokine, CCL1.
Additionally, the increase in CCR8 expression after notexin damage contributes to pain development [61]. So, our data indicate that USGET treatment could produce a pain reduction in skeletal muscle damage. The combination of 1α,25-dihydroxyvitamin D3 and prostaglandin E2 (PGE2) produce a high CCR8 expression, showing the importance of tissue environments in maintaining cellular immune surveillance networks within different tissues [62]. However, our study has not analyzed muscle damage caused by physical exercise. Consequently, we cannot compare damage induced by notexin with damage induced by physical exercise.
The NF-κB is sequestered in the cytoplasm by IκB and keep it in an inactive state. On the other hand, degradation of IκB activates NF-κB [63,64]. In our results, after notexin addition a decrease of IκB and an increase in NF-κB were detected. The transcription factor NFᴋB is upregulated in inflammation conditions and regulates innate and adaptive immune functions [65]. This factor induces the expression of cytokines and chemokines participating in inflammasome regulation. In inflammatory situations, the activation of NFᴋB contributes to the pathogenic processes [66,67] as we detected after notexin injection. After the application of PIE technique, an increase in IκB expression occurs, sequestering NF-κB and inhibiting it, and preventing so the development of secondary inflammatory processes [65]. Therefore, developing therapeutic strategies based on NFᴋB inhibition would be the next step to diminish inflammation muscle damage. In this work, we demonstrate a decrease in NFᴋB protein expression in NOT+USGET compared with the notexin group, indicating the possible efficacy of this technique for that purpose.
All changes detected by the USGET technique used in inflammation have been corroborated by the recovery of motor functions detected in this study. To sum up, our study demonstrated an increase in inflammation and decreased motor function after notexin addition in the quadriceps muscle (Fig 7). Furthermore, significant improvements after USGET technique application were detected, with a decrease in pro-inflammatory proteins and an increase of anti-inflammatory mediators. Furthermore, all positive effects of USGET lead to a recovery of decreased motor function produced by notexin. This investigation explains the effectiveness of USGET treatment detected in humans (Fig 8). In any case, therapeutic interventions, such as percutaneous intra-tissue electrolysis and pulsed-dose radiofrequency, appear promising, but require further studies to confirm their efficacy.
[Figure omitted. See PDF.]
Increase in proinflammatory cytokines, chemokines, chemokines receptors and NFκB protein with decrease in CCL1 chemokine and motor function are indicated.
[Figure omitted. See PDF.]
Increase in anti-cytokines, CCL1 chemokine and motor function with decrease in proinflammatory cytokines, chemokines, chemokines receptors and NFκB protein are indicated.
In conclusion, our study demonstrates that the USGET technique prevents the increase of pro-inflammatory mediators, such as IL-6 cytokine and CCL3, CCL4 and CCL5 chemokines induced by notexin in the quadriceps muscle. Furthermore, USGET technique also showed a decrease in the CCR5 receptor of the chemokines mentioned above. Moreover, a decrease in CCR8 and NF-ᴋB expression was detected after USGET treatment. On the contrary, an increase in anti-inflammatory mediators (IL-10 and IL-13) after USGET treatment can recover from notexin-induced damage. These results would support the idea that USGET treatment could help muscle recovery after toxic damage justifying its use.
Supporting information
S1 Raw images.
https://doi.org/10.1371/journal.pone.0276634.s001
(PPTX)
Citation: Jorda A, Campos-Campos J, Aldasoro C, Colmena C, Aldasoro M, Alvarez K, et al. (2022) Protective action of ultrasound-guided electrolysis technique on the muscle damage induced by notexin in rats. PLoS ONE 17(11): e0276634. https://doi.org/10.1371/journal.pone.0276634
About the Authors:
Adrian Jorda
Roles: Investigation, Methodology, Validation
Affiliations Department of Physiology, School of Medicine, University of Valencia, Valencia, Spain, Faculty of Nursing and Podiatry, Department of Nursing, University of Valencia, Valencia, Spain
Juan Campos-Campos
Roles: Investigation, Methodology, Software
Affiliations Department of Physiology, School of Medicine, University of Valencia, Valencia, Spain, Faculty of Nursing and Podiatry, Department of Nursing, University of Valencia, Valencia, Spain
Constanza Aldasoro
Roles: Formal analysis, Investigation
Affiliation: Department of Physiology, School of Medicine, University of Valencia, Valencia, Spain
Carlos Colmena
Roles: Investigation
Affiliation: Department of Physiology, School of Medicine, University of Valencia, Valencia, Spain
Martin Aldasoro
Roles: Formal analysis, Investigation, Writing – original draft
Affiliation: Department of Physiology, School of Medicine, University of Valencia, Valencia, Spain
Kenia Alvarez
Roles: Investigation, Methodology
Affiliation: Department of Physiology, School of Medicine, University of Valencia, Valencia, Spain
Soraya L. Valles
Roles: Conceptualization, Project administration, Writing – original draft
E-mail: [email protected]
Affiliation: Department of Physiology, School of Medicine, University of Valencia, Valencia, Spain
https://orcid.org/0000-0001-6093-0013
1. Haddad F, Zaldivar F, Cooper DM, Adams GR. IL-6-induced skeletal muscle atrophy. J Appl Physiol (1985). 2005 Mar;98(3):911–7. pmid:15542570.
2. Chazaud B. Inflammation during skeletal muscle regeneration and tissue remodeling: application to exercise-induced muscle damage management. Immunol Cell Biol. 2016 Feb;94(2):140–5. pmid:26526620.
3. Chazaud B. Inflammation and Skeletal Muscle Regeneration: Leave It to the Macrophages! Trends Immunol. 2020 Jun;41(6):481–492. pmid:32362490.
4. Tidball JG. Regulation of muscle growth and regeneration by the immune system. Nat Rev Immunol. 2017 Mar;17(3):165–178. pmid:28163303.
5. Vannella KM, Wynn TA. Mechanisms of Organ Injury and Repair by Macrophages. Annu Rev Physiol. 2017 Feb 10;79:593–617. pmid:27959618.
6. Pablos A, Ceca D, Jorda A, Rivera P, Colmena C, Elvira L, et al. Protective Effects of Foam Rolling against Inflammation and Notexin Induced Muscle Damage in Rats. Int J Med Sci. 2020 Jan 1;17(1):71–81. pmid:31929740.
7. Lemos DR, Babaeijandaghi F, Low M, Chang CK, Lee ST, Fiore D, et al. Nilotinib reduces muscle fibrosis in chronic muscle injury by promoting TNF-mediated apoptosis of fibro/adipogenic progenitors. Nat Med. 2015 Jul;21(7):786–94. pmid:26053624.
8. Mann CJ, Perdiguero E, Kharraz Y, Aguilar S, Pessina P, Serrano AL, et al. Aberrant repair and fibrosis development in skeletal muscle. Skelet Muscle. 2011 May 4;1(1):21. pmid:21798099.
9. Perandini LA, Chimin P, Lutkemeyer DDS, Câmara NOS. Chronic inflammation in skeletal muscle impairs satellite cells function during regeneration: can physical exercise restore the satellite cell niche? FEBS J. 2018 Jun;285(11):1973–1984. pmid:29473995.
10. Li X, Moody MR, Engel D, Walker S, Clubb FJ Jr, Sivasubramanian N, et al. Cardiac-specific overexpression of tumor necrosis factor-alpha causes oxidative stress and contractile dysfunction in mouse diaphragm. Circulation. 2000 Oct 3;102(14):1690–6. pmid:11015349.
11. Comerford I, McColl SR. Mini-review series: focus on chemokines. Immunol Cell Biol. 2011 Feb;89(2):183–4. pmid:21326315.
12. Ransohoff RM. Chemokines and chemokine receptors: standing at the crossroads of immunobiology and neurobiology. Immunity. 2009 Nov 20;31(5):711–21. pmid:19836265.
13. Peñin-Franch A, García-Vidal JA, Martínez CM, Escolar-Reina P, Martínez-Ojeda RM, Gómez AI, et al. Galvanic current activates the NLRP3 inflammasome to promote Type I collagen production in tendon. Elife. 2022 Feb 24;11:e73675. pmid:35199642.
14. Romero-Morales C, Bravo-Aguilar M, Abuín-Porras V, Almazán-Polo J, Calvo-Lobo C, Martínez-Jiménez EM, et al. Current advances and novel research on minimal invasive techniques for musculoskeletal disorders. Dis Mon. 2021 Oct;67(10):101210. pmid:34099238.
15. Abat F, Diesel WJ, Gelber PE, Polidori F, Monllau JC, Sanchez-Ibañez JM. Effectiveness of the Intratissue Percutaneous Electrolysis (EPI®) technique and isoinertial eccentric exercise in the treatment of patellar tendinopathy at two years follow-up. Muscles Ligaments Tendons J. 2014 Jul 14;4(2):188–93. pmid:25332934.
16. Abat F, Valles SL, Gelber PE, Polidori F, Jorda A, García-Herreros S, et al. An experimental study of muscular injury repair in a mouse model of notexin-induced lesion with EPI® technique. BMC Sports Sci Med Rehabil. 2015 Apr 17;7:7. pmid:25897404.
17. Ghassemi A, Rosenberg P. Effects of snake venom phospholipase A2 toxins (beta-bungarotoxin, notexin) and enzymes (Naja naja atra, Naja nigricollis) on aminophospholipid asymmetry in rat cerebrocortical synaptosomes. Biochem Pharmacol. 1992 Sep 25;44(6):1073–83. pmid:1417932.
18. Zádor E, Mendler L, Ver Heyen M, Dux L, Wuytack F. Changes in mRNA levels of the sarcoplasmic/endoplasmic-reticulum Ca(2+)-ATPase isoforms in the rat soleus muscle regenerating from notexin-induced necrosis. Biochem J. 1996 Nov 15;320 (Pt 1)(Pt 1):107–13. pmid:8947474.
19. Mendler L, Zádor E, Dux L, Wuytack F. mRNA levels of myogenic regulatory factors in rat slow and fast muscles regenerating from notexin-induced necrosis. Neuromuscul Disord. 1998 Dec;8(8):533–41. pmid:10093059.
20. Plant DR, Colarossi FE, Lynch GS. Notexin causes greater myotoxic damage and slower functional repair in mouse skeletal muscles than bupivacaine. Muscle Nerve. 2006 Nov;34(5):577–85. pmid:16881061.
21. Wolf SJ, Heard K, Sloan EP, Jagoda AS; American College of Emergency Physicians. Clinical policy: critical issues in the management of patients presenting to the emergency department with acetaminophen overdose. Ann Emerg Med. 2007 Sep;50(3):292–313. pmid:17709050.
22. Mollier P, Chwetzoff S, Frachon P, Ménez A. Immunological properties of notexin, a potent presynaptic and myotoxic component from venom of the Australian tiger snake Notechis scutatus scutatus. FEBS Lett. 1989 Jul 3;250(2):479–82. pmid:2753144.
23. Plant DR, Colarossi FE, Lynch GS. Notexin causes greater myotoxic damage and slower functional repair in mouse skeletal muscles than bupivacaine. Muscle Nerve. 2006 Nov;34(5):577–85. pmid:16881061.
24. Hunter AJ, Hatcher J, Virley D, Nelson P, Irving E, Hadingham SJ, et al. Functional assessments in mice and rats after focal stroke. Neuropharmacology. 2000 Mar 3;39(5):806–16. pmid:10699446.
25. Peterson GL. A simplification of the protein assay method of Lowry et al. which is more generally applicable. Anal Biochem. 1977 Dec;83(2):346–56. pmid:603028.
26. Jorda A, Aldasoro M, Aldasoro C, Valles SL. Inflammatory Chemokines Expression Variations and Their Receptors in APP/PS1 Mice. J Alzheimers Dis. 2021;83(3):1051–1060. pmid:34397415.
27. Chang JS, Kayani B, Plastow R, Singh S, Magan A, Haddad FS. Management of hamstring injuries: current concepts review. Bone Joint J. 2020 Oct;102-B(10):1281–1288. pmid:32993323.
28. Abat F, Alfredson H, Campos J, Planells G, Torras J, Madruga-Parera M, et al. Ultrasound-guided versus blind interventions in patellar tendon lesions: a cadaveric study. Skeletal Radiol. 2021 May;50(5):967–972. pmid:33063137.
29. Sánchez-Sánchez JL, Calderón-Díez L, Herrero-Turrión J, Méndez-Sánchez R, Arias-Buría JL, Fernández-de-Las-Peñas C. Changes in Gene Expression Associated with Collagen Regeneration and Remodeling of Extracellular Matrix after Percutaneous Electrolysis on Collagenase-Induced Achilles Tendinopathy in an Experimental Animal Model: A Pilot Study. J Clin Med. 2020 Oct 15;9(10):3316. pmid:33076550.
30. Varela-Rodríguez S, Sánchez-González JL, Sánchez-Sánchez JL, Delicado-Miralles M, Velasco E, Fernández-de-Las-Peñas C, et al. Effects of Percutaneous Electrolysis on Endogenous Pain Modulation: A Randomized Controlled Trial Study Protocol. Brain Sci. 2021 Jun 17;11(6):801. pmid:34204415.
31. Margalef R, Bosque M, Monclús P, Flores P, Minaya-Muñoz F, Valera-Garrido F, et al. Percutaneous Application of Galvanic Current in Rodents Reverses Signs of Myofascial Trigger Points. Evid Based Complement Alternat Med. 2020 May 28;2020:4173218. pmid:32565858.
32. Patsalos A, Tzerpos P, Halasz L, Nagy G, Pap A, Giannakis N, et al. The BACH1-HMOX1 Regulatory Axis Is Indispensable for Proper Macrophage Subtype Specification and Skeletal Muscle Regeneration. J Immunol. 2019 Sep 15;203(6):1532–1547. pmid:31405954.
33. Chargé SB, Rudnicki MA. Cellular and molecular regulation of muscle regeneration. Physiol Rev. 2004 Jan;84(1):209–38. pmid:14715915.
34. Porter JD, Khanna S, Kaminski HJ, Rao JS, Merriam AP, Richmonds CR, et al. A chronic inflammatory response dominates the skeletal muscle molecular signature in dystrophin-deficient mdx mice. Hum Mol Genet. 2002 Feb 1;11(3):263–72. pmid:11823445.
35. Mukund K, Subramaniam S. Skeletal muscle: A review of molecular structure and function, in health and disease. Wiley Interdiscip Rev Syst Biol Med. 2020 Jan;12(1):e1462. pmid:31407867.
36. Khunsap S, Khow O, Buranapraditkun S, Suntrarachun S, Puthong S, Boonchang S. Anticancer properties of phospholipase A2 from Daboia siamensis venom on human skin melanoma cells. J Venom Anim Toxins Incl Trop Dis. 2016 Feb 16;22:7. pmid:26884744.
37. Alter J, Rozentzweig D, Bengal E. Inhibition of myoblast differentiation by tumor necrosis factor alpha is mediated by c-Jun N-terminal kinase 1 and leukemia inhibitory factor. J Biol Chem. 2008 Aug 22;283(34):23224–34. pmid:18552402.
38. Webster JM, Kempen LJAP, Hardy RS, Langen RCJ. Inflammation and Skeletal Muscle Wasting During Cachexia. Front Physiol. 2020 Nov 19;11:597675. pmid:33329046.
39. Hunt LC, Upadhyay A, Jazayeri JA, Tudor EM, White JD. An anti-inflammatory role for leukemia inhibitory factor receptor signaling in regenerating skeletal muscle. Histochem Cell Biol. 2013 Jan;139(1):13–34. pmid:22926285.
40. Wang X, Wu H, Zhang Z, Liu S, Yang J, Chen X, et al. Effects of interleukin-6, leukemia inhibitory factor, and ciliary neurotrophic factor on the proliferation and differentiation of adult human myoblasts. Cell Mol Neurobiol. 2008 Jan;28(1):113–24. pmid:18240017.
41. Begue G, Douillard A, Galbes O, Rossano B, Vernus B, Candau R, Py G. Early activation of rat skeletal muscle IL-6/STAT1/STAT3 dependent gene expression in resistance exercise linked to hypertrophy. PLoS One. 2013;8(2):e57141. pmid:23451164.
42. Tidball JG, Villalta SA. Regulatory interactions between muscle and the immune system during muscle regeneration. Am J Physiol Regul Integr Comp Physiol. 2010 May;298(5):R1173–87. pmid:20219869.
43. Deng B, Wehling-Henricks M, Villalta SA, Wang Y, Tidball JG. IL-10 triggers changes in macrophage phenotype that promote muscle growth and regeneration. J Immunol. 2012 Oct 1;189(7):3669–80. pmid:22933625.
44. Locati M, Curtale G, Mantovani A. Diversity, Mechanisms, and Significance of Macrophage Plasticity. Annu Rev Pathol. 2020 Jan 24;15:123–147. pmid:31530089.
45. Villalta SA, Rosenthal W, Martinez L, Kaur A, Sparwasser T, Tidball JG, et al. Regulatory T cells suppress muscle inflammation and injury in muscular dystrophy. Sci Transl Med. 2014 Oct 15;6(258):258ra142. pmid:25320234.
46. Liu X, Wu G, Shi D, Zhu R, Zeng H, Cao B, et al. Effects of nitric oxide on notexin-induced muscle inflammatory responses. Int J Biol Sci. 2015 Jan 5;11(2):156–67. pmid:25561898.
47. Wu G, Hu VJ, McClintick DJ, Gatto JD, Aderibigbe T, Lu L, et al. Lateral to medial fibro-adipogenic degeneration are greater in infraspinatus than supraspinatus following nerve and tendon injury of murine rotator cuff. J Orthop Res. 2021 Jan;39(1):184–195. pmid:32886404.
48. Venuti A, Pastori C, Lopalco L. The Role of Natural Antibodies to CC Chemokine Receptor 5 in HIV Infection. Front Immunol. 2017 Oct 30;8:1358. pmid:29163468.
49. Restrepo C, Gutierrez-Rivas M, Pacheco YM, García M, Blanco J, Medrano LM, et al. CoRIS and the HIV Biobank integrated in the Spanish AIDS Research Network Project RIS/EPICLIN 10_2015. Genetic variation in CCR2 and CXCL12 genes impacts on CD4 restoration in patients initiating cART with advanced immunesupression. PLoS One. 2019 Mar 28;14(3):e0214421. pmid:30921390.
50. Deng H, Liu R, Ellmeier W, Choe S, Unutmaz D, Burkhart M, et al. Identification of a major co-receptor for primary isolates of HIV-1. Nature. 1996 Jun 20;381(6584):661–6. pmid:8649511.
51. Biber K, de Jong EK, van Weering HR, Boddeke HW. Chemokines and their receptors in central nervous system disease. Curr Drug Targets. 2006 Jan;7(1):29–46. pmid:16454698.
52. Jorda A, Cauli O, Santonja JM, Aldasoro M, Aldasoro C, Obrador E, et al. Changes in Chemokines and Chemokine Receptors Expression in a Mouse Model of Alzheimer’s Disease. Int J Biol Sci. 2019 Jan 1;15(2):453–463. pmid:30745834.
53. Ahearn OC, Watson MN, Rawls SM. Chemokines, cytokines and substance use disorders. Drug Alcohol Depend. 2021 Mar 1;220:108511. pmid:33465606.
54. Yahiaoui L, Gvozdic D, Danialou G, Mack M, Petrof BJ. CC family chemokines directly regulate myoblast responses to skeletal muscle injury. J Physiol. 2008 Aug 15;586(16):3991–4004. pmid:18566004.
55. Shireman PK, Contreras-Shannon V, Ochoa O, Karia BP, Michalek JE, McManus LM. MCP-1 deficiency causes altered inflammation with impaired skeletal muscle regeneration. J Leukoc Biol. 2007 Mar;81(3):775–85. pmid:17135576.
56. Liang F, Giordano C, Shang D, Li Q, Petrof BJ. The dual CCR2/CCR5 chemokine receptor antagonist Cenicriviroc reduces macrophage infiltration and disease severity in Duchenne muscular dystrophy (Dmdmdx-4Cv) mice. PLoS One. 2018 Mar 21;13(3):e0194421. pmid:29561896.
57. Zhang C, Qiao Y, Huang L, Li F, Zhang Z, Ping Y, et al. Regulatory T cells were recruited by CCL3 to promote cryo-injured muscle repair. Immunol Lett. 2018 Dec;204:29–37. Erratum in: Immunol Lett. 2022 Apr;244:45–47. pmid:30321562.
58. Miller MD, Hata S, De Waal Malefyt R, Krangel MS. A novel polypeptide secreted by activated human T lymphocytes. J Immunol. 1989 Nov 1;143(9):2907–16. pmid:2809212.
59. Makita S, Takatori H, Nakajima H. Post-Transcriptional Regulation of Immune Responses and Inflammatory Diseases by RNA-Binding ZFP36 Family Proteins. Front Immunol. 2021 Jul 1;12:711633. pmid:34276705.
60. Akimoto N, Honda K, Uta D, Beppu K, Ushijima Y, Matsuzaki Y, et al. CCL-1 in the spinal cord contributes to neuropathic pain induced by nerve injury. Cell Death Dis. 2013 Jun 20;4(6):e679. pmid:23788036.
61. McCully ML, Collins PJ, Hughes TR, Thomas CP, Billen J, O’Donnell VB, et al. Skin Metabolites Define a New Paradigm in the Localization of Skin Tropic Memory T Cells. J Immunol. 2015 Jul 1;195(1):96–104. pmid:26002980.
62. Yazdi S, Naumann M, Stein M. Double phosphorylation-induced structural changes in the signal-receiving domain of IκBα in complex with NF-κB. Proteins. 2017 Jan;85(1):17–29. pmid:27701768.
63. Basak S, Kim H, Kearns JD, Tergaonkar V, O’Dea E, Werner SL, et al. A fourth IkappaB protein within the NF-kappaB signaling module. Cell. 2007 Jan 26;128(2):369–81. pmid:17254973.
64. Thoma A, Lightfoot AP. NF-kB and Inflammatory Cytokine Signalling: Role in Skeletal Muscle Atrophy. Adv Exp Med Biol. 2018;1088:267–279. pmid:30390256.
65. Aguirre-Rueda D, Guerra-Ojeda S, Aldasoro M, Iradi A, Obrador E, Mauricio MD, et al. WIN 55,212–2, agonist of cannabinoid receptors, prevents amyloid β1–42 effects on astrocytes in primary culture. PLoS One. 2015 Apr 13;10(4):e0122843. pmid:25874692.
66. Jorda A, Aldasoro M, Aldasoro C, Guerra-Ojeda S, Iradi A, Vila JM, et al. Action of low doses of Aspirin in Inflammation and Oxidative Stress induced by aβ1–42 on Astrocytes in primary culture. Int J Med Sci. 2020 Mar 13;17(6):834–843. pmid:32218705.
67. Bisciotti GN, Chamari K, Cena E, Garcia GR, Vuckovic Z, Bisciotti A, et al. The conservative treatment of longstanding adductor-related groin pain syndrome: a critical and systematic review. Biol Sport. 2021 Mar;38(1):45–63. pmid:33795914.
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Abstract
It is known that exercise can be one of the causes of muscular damage. In recent times, physiotherapists and medical professionals have been employing USGET techniques to stimulate muscle recovery to improve its performance after the injury. We pretend to analyse if the Ultrasound-guided electrolysis (USGET) technique could reduce muscle damage, inflammation, and pain in the present study. Female Wistar rats were assigned to one of three different groups: control (C), notexin (NOT) and notexin with USGET (electrolysis at 6mA) (NOT+USGET). We used the USGT technique, based on electrical stimulation with a continuous current of 4 pulses at an intensity of 6 mA for 5 seconds, conveyed to the muscle. The response was tested with motor function tests. In these tests, we could observe an increase in time and foot faults when crossing a beam in the NOT group compared to C group rats. On the other hand, a significant decrease in both variables was detected in the NOT+USGET compared to the NOT group. Muscle power was measured with a grip strength test, obtaining far better performances in NOT+USGET rats when compared to NOT rats. Moreover, the USGET technique prevented the increase of pro-inflammatory proteins IL-6 and chemokines CCL3 (Chemokine (C-C motif) ligand 3), CCL4 (Chemokine (C-C motif) ligand 4), and CCL5 (Chemokine (C-C motif) ligand 5) with their receptor CCR5 (C-C chemokine receptor type 5), induced by notexin in the quadriceps. At the same time, the study evidenced a decrease in both CCR8 (C-C chemokine receptor type 5,) and NF-ᴋB (nuclear factor- ᴋB) expressions after USGET treatment. On the other hand, we obtained evidence that demonstrated anti-inflammatory properties of the USGET technique, thus being the increase in IL-10 (Interleukin 10) and IL-13 (Interleukin 13) in the NOT+USGET group compared to the NOT group. Furthermore, when applying NSGET after damage, an increase in anti-inflammatory mediators and reduction of pro-inflammatory mediators, which, overall, promoted muscle regeneration, was observed. These results support the idea that the NSGET technique improves muscle recovery after toxic damages, which would justify its employment.
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