Neuromuscular Electrical Stimulation Limits Muscle Weakness, Atrophy, Modulates Satellite Cell Function And Reduces Inflammation In Cancer Cachexia

BackgroundCancer cachexia (CC) is characterized by skeletal muscle atrophy and reduced strength, partly linked to dysfunction of muscle stem cells (MuSCs) and alterations in their niche. Although exercise may mitigate muscle loss, its effects in CC remain debated and its feasibility is often limited in advanced patients. Neuromuscular electrical stimulation (NMES) offers a promising alternative, by promoting MuSC proliferation and fusion, increasing muscle size and macrophage content in healthy muscle. This study investigated whether NMES, initiated at tumor onset, could improve MuSC regulation and its niche while limiting muscle atrophy and weakness in a tumor-bearing mouse model. MethodsTen-week-old male BALB/c mice were subcutaneously injected with C26 tumor cells or PBS. Tumor-bearing mice were divided into NMES-treated (C26 NMES) and non-stimulated controls (C26). NMES consisted of six sessions (two series of three consecutive daily sessions separated by one rest day), starting seven days post-inoculation when tumors became visible. Each session was delivered at a submaximal intensity corresponding to 15% of maximal strength. Muscle mass, myofiber size, strength and cellular composition were assessed. ResultsMuscle mass was decreased by 13% in C26 mice as compared to PBS controls, while C26 NMES mice showed a [~]7% improvement over C26 mice. Mean myofiber size decreased similarly in both tumor-bearing groups as compared to PBS controls (-12-14%). However, NMES reduced the proportion of small myofibers (400-600 {micro}m{superscript 2}) as compared to C26 mice. Maximal torque loss was less severe in C26 NMES mice (-28%) than in C26 mice (-34%). As compared with PBS mice, C26 mice exhibited increased MuSC proliferation (+97%) but reduced differentiation (-61%), as indicated by fewer myogenin-positive cells. NMES normalized MuSC proliferation, restored myogenin-positive cell number, and enhanced MuSC fusion, reflected by an increased number of PCM1-positive myonuclei (+8-11%). NMES also modulated inflammation, reducing neutrophils (-42%) and increasing macrophages (+35%), through the proliferation of CD169-positive resident macrophages (+106%). In vitro, macrophages exposed to C26 muscle extracts showed elevated pro-inflammatory markers (COX2 and TNF-; +21% and +16%) as compared to PBS controls. This effect was abolished with extracts from C26 NMES muscles. Additionally, C26 extracts reduced the expression of anti-inflammatory markers by macrophages (CD206 and IL-10; -23%), whereas NMES restored their levels to those of controls. ConclusionNMES-induced mild contractile activity is an effective stimulus for preserving muscle strength and mass, improving MuSC regulation, and modulating muscle inflammation in a mouse model of CC.