HEPATIC AND SKELETAL MUSCLE TISSUE IMMUNOMETABOLISM IN TRAINED RATS

Magalhães, Alan José Barbosa; Camargo Filho, José Carlos Silva; Mariolani, José Ricardo Lenzi; Camargo, Regina Celi Trindade; Oikawa, Sergio Minoru; Belangero, William Dias

doi:10.1590/1517-8692202430022023_0219i

ABSTRACT

Introduction:

Physical exercise can be an alternative for preventing and treating the harmful effects of obesity, mainly inflammatory effects on skeletal muscle and liver tissues. However, no consensus exists regarding this purpose's best physical training model.

Objective:

Evaluate morphological, metabolic, and inflammatory alterations in rats’ skeletal and hepatic muscle tissues caused by aerobic and resistance training.

Methods:

24 Wistar rats were divided into sedentary (S), aerobic (AE), and resistance training (R) groups. Blood glucose, total cholesterol, and serum triglycerides were measured periodically. After euthanasia, body mass was measured to calculate the total mass gain during the experiment. High-density lipoprotein (HDL) was measured. Adipose tissue was extracted to calculate its percentage relative to body mass and the liver, soleus, and gastrocnemius muscles for morphological analyses and concentrations of glycogen, lipids, and Tumor Necrosis Factor α (TNF-α). The Kruskall-Wallis test and Dunn's post-test were performed for statistical analysis, adopting p<0.05.

Results:

Both training models reduced the percentage of adipose tissue, body mass gain, and hepatic TNF-α concentration (p<0.05). AE increased serum HDL, gastrocnemius fiber diameter and reduced the fractal dimension in the soleus (p<0.05). R reduced blood glucose and serum and liver lipids, increased liver and soleus glycogen concentrations, increased gastrocnemius fiber diameter, and decreased TNF-α (p<0.05).

Conclusion:

Both training models reduced body mass, relative visceral adipose tissue, serum total cholesterol concentration, and liver inflammation. However, resistance training was more effective in promoting metabolic effects in the liver and skeletal muscle and reducing muscle inflammation in rats. Level of Evidence V; Expert Opinion.

Keywords:
Resistance Training; Liver; Muscle, Skeletal; Tumor Necrosis Factor-alpha

RESUMEN

Introducción:

El ejercicio físico puede ser una alternativa para prevenir y tratar los efectos nocivos de la obesidad, principalmente los efectos inflamatorios sobre los tejidos del músculo esquelético y del hígado. Sin embargo, no existe consenso sobre cuál es el mejor modelo de entrenamiento físico para este fin.

Objetivo:

Evaluar las alteraciones morfológicas, metabólicas e inflamatorias del entrenamiento aeróbico y de resistencia en sobre los tejidos músculo esqueléticos y hepáticos de ratas.

Métodos:

24 ratas Wistar se dividieron en grupos sedentarios (S), aeróbicos (AE) y de entrenamiento de resistencia (R). Se midieron periódicamente glucosa en sangre, colesterol total y triglicéridos. Después de la eutanasia, se midió la masa corporal para calcular la ganancia de masa total durante el experimento. Se midió la lipoproteína de alta densidad (HDL). Se extrajo tejido adiposo para calcular su porcentaje relativo a la masa corporal, así como hígado, músculos sóleo y gastrocnemio para análisis morfológicos y concentraciones de glucógeno, lípidos y Factor de Necrosis Tumoral α (TNF-α). Para el análisis estadístico fueron utilizados Kruskall-Wallis y el post-test de Dunn, adoptando p<0,05.

Resultados:

Ambos entrenamientos redujeron el porcentaje de tejido adiposo, masa corporal y la concentración de TNF-α hepático (p<0,05). AE aumentó el HDL sérico, el diámetro de la fibra del gastrocnemio y redujo la dimensión fractal en el sóleo (p<0,05). R redujo la glucosa en sangre y los lípidos séricos y hepáticos, aumentó las concentraciones de glucógeno hepático y sóleo, aumentó el diámetro de la fibra del gastrocnemio y disminuyó el TNF-α (p<0,05).

Conclusión:

Ambos modelos de entrenamiento redujeron la masa corporal, el tejido adiposo visceral relativo, la concentración sérica de colesterol total y la inflamación hepática. El entrenamiento de resistencia demostró ser más eficaz para promover los efectos metabólicos en el hígado y el músculo esquelético, además de reducir la inflamación muscular en ratas. Nivel de Evidencia V; Opinión del Especialista.

Descriptores:
Entrenamiento de Resistencia; Hígado; Músculo Esquelético; Factor de Necrosis Tumoral alfa

RESUMO

Introdução:

O exercício físico pode se apresentar como uma alternativa para prevenção e tratamento de efeitos deletérios da obesidade, principalmente efeitos inflamatórios sobre os tecidos muscular esquelético e hepático. No entanto, não há consenso quanto ao melhor modelo de treinamento físico para tal finalidade. Objetivos: Avaliar alterações morfológicas, metabólicas e inflamatórias dos treinamentos aeróbico e resistido sobre os tecidos muscular esquelético e hepático de ratos.

Métodos:

24 ratos Wistar foram divididos nos grupos sedentário (S), treinamento aeróbico (AE) e resistido (R). Glicemia, colesterol total e triglicerídeos séricos foram mensurados periodicamente. Após a eutanásia, a massa corporal foi mensurada para calcular o ganho total de massa durante o experimento. A lipoproteína de alta densidade (HDL) foi dosada. O tecido adiposo foi extraído para cálculo de sua porcentagem relativa à massa corporal assim como o fígado e os músculos sóleo e gastrocnêmio para as análises morfológicas e das concentrações de glicogênio, lipídios e Fator de Necrose Tumoral α (TNF-α). Para análise estatística, foram utilizados o teste de Kruskall-Wallis e o pós-teste de Dunn, adotando-se p<0,05.

Resultados:

Ambos os modelos de treinamento reduziram o percentual de tecido adiposo, ganho de massa corporal e concentração hepática de TNF-α (p<0,05). AE aumentou o HDL sérico, o diâmetro das fibras do gastrocnêmio e reduziu a dimensão fractal no sóleo (p<0,05). R reduziu a glicemia e os lipídios séricos e hepáticos, aumentou a concentração de glicogênio hepático e sóleo, aumentou o diâmetro das fibras gastrocnêmicas e diminuiu o TNF-α (p<0,05).

Conclusão:

Ambos os modelos de treinamento reduziram a massa corporal, o tecido adiposo visceral relativo, a concentração sérica de colesterol total e a inflamação hepática. No entanto, o treinamento resistido mostrou-se mais eficaz em promover efeitos metabólicos no fígado e no músculo esquelético, além de reduzir a inflamação muscular em ratos. Nível de Evidência V; Opinião do Especialista.

Descritores:
Treinamento de Resistência; Fígado; Músculo Esquelético; Fator de Necrose Tumoral alfa

INTRODUCTION

Due to its subtle symptoms and long-term effects, sedentary behavior remains a popular topic. A sedentary lifestyle can create a positive feedback loop: reduced physical capacity leads to discomfort during exercise, which can discourage further activity.¹1 Cunningham C, Sullivan RO, Caserotti P, Tully MA. Consequences of physical inactivity in older adults: A systematic review of reviews and meta-analyses. Scand J Med Sci Sports. 2020;30(5):816-27.

As a result, body fat accumulates, caused by an imbalance between calorie intake and energy expenditure. This increase can lead to other pathological conditions, such as metabolic syndrome. In addition, hypertrophied adipocytes suffer hypoxia and secrete Tumor Necrosis Factor α (TNF-α), responsible for the onset of chronic diseases.²2 Patsalos O, Keeler J, Schmidt U, Penninx BWJH, Young AH, Himmerich H. Diet, Obesity, and Depression: A Systematic Review. J Pers Med. 2021;11(3):176.

However, physical training can be an effective non-pharmacological alternative to these harmful effects. Both aerobic and resistance training can reduce the risk of developing chronic diseases,³3 Linden MA, Sheldon RD, Meers GM, Ortinau LC, Morris EM, Booth FW, et al. Aerobic exercise training in the treatment of non-alcoholic fatty liver disease related fibrosis. J Physiol. 2016;594(18):5271-84.,⁴4 Sumi K, Ashida K, Nakazato K. Repeated stretch-shortening contraction of the triceps surae attenuates muscle atrophy and liver dysfunction in a rat model of inflammation. Exp Physiol. 2020;105(7):1111-23. since muscle contraction stimulates the production of Interleukin 10 and reduces the secretion of TNF-α.⁵5 Takegaki J, Ogasawara R, Kotani T, Tamura Y, Takagi R, Nakazato K, et al. Influence of shortened recovery between resistance exercise sessions on muscle-hypertrophic effect in rat skeletal muscle. Physiol Rep. 2019;7(13):e14155.,⁶6 Agostinete RR, Rossi FE, Magalhaes AJ, Rocha AP, Parmezzani SS, Gerosa-Neto J, et al. Immunometabolic Responses after Short and Moderate Rest Intervals to Strength Exercise with and without Similar Total Volume. Front Physiol. 2016;7:444.

However, it is unclear which type of training is best suited to reducing the effects of a sedentary lifestyle and whether the anti-inflammatory effect promoted occurs similarly in skeletal muscle and liver tissues. Therefore, the present study evaluated the morphological, metabolic, and inflammatory changes that aerobic and resistance training promoted in rats’ skeletal muscle and liver tissue.

MATERIALS AND METHODS

Animals

Twenty-four seven-week-old male Wistar rats were obtained from the Animal House II of the Faculty of Science and Technology of the Universidade Estadual Paulista “Júlio de Mesquita Filho” (FCT/UNESP), Presidente Prudente campus. The research was carried out by the rules and ethical principles of animal experimentation of the Ethics Committee for the Use of Animals (CEUA) of FCT/UNESP, under protocol No. 003/2016.

Experimental groups

The animals were divided into sedentary (S), aerobic (AE), and resistance (R) groups and fed SupraLab® brand rodent food from Alisul® (São Leopoldo, Brazil), with a composition of 48g of carbohydrates, 25g of proteins, 3g of lipids and 24g of fibers and minerals per 100 grams, totaling 2.95 kilocalories per gram (Kcal/g). Tap water was offered ad libitum for hydration.

Training protocols

Protocol for the sedentary group

Group S remained in the cage for the entire experimental period without any experimental physical training.

Aerobic training protocol

To familiarize themselves with aerobic training, the animals walked on the Inbramed® treadmill for 30 minutes once a day for six consecutive days, according to the method proposed by Lira et al.⁷7 Lira FS, Koyama CH, Yamashita AS, Rosa JC, Zanchi NE, Batista Jr ML, et al. Chronic exercise decreases cytokine production in healthy rat skeletal muscle. Cell Biochem Funct. 2009;27(7):458-61. After the familiarization period, the prescription of the loads used in aerobic training was defined by the Maximum Speed Test (V_max), using the methods of Faleiros et al.⁸8 Faleiros CM, Francescato H, Papoti M, Chaves L, Silva C, Costa R, et al. Effects of previous physical training on adriamycin nephropathy and its relationship with endothelial lesions and angiogenesis in the renal cortex. Life Sci. 2017;169:43-51.

Then the training period began, in which the animals ran on a treadmill for 60 minutes, once a day, five times a week, for 12 weeks, following the model proposed by Lira et al.⁷7 Lira FS, Koyama CH, Yamashita AS, Rosa JC, Zanchi NE, Batista Jr ML, et al. Chronic exercise decreases cytokine production in healthy rat skeletal muscle. Cell Biochem Funct. 2009;27(7):458-61.

Resistance training protocol

Resistance training was carried out in an aquatic environment. A cylindrical plastic container with 50 cm high and 25 cm in diameter was adapted. The container was filled with water at an average temperature of 30 ± 2 ºC until it reached a depth of 38 cm. The workload was accommodated in the posterior region of the chest using a special vest, allowing vertical jumps to the surface of the container. The familiarization period was carried out as proposed by Teixeira et al.⁹9 Teixeira GR, Fávaro WJ, Pinheiro PFF, Chuffa LGA, Amorim JPA, Mendes LO, et al. Physical exercise on the rat ventral prostate: Steroid hormone receptors, apoptosis and cell proliferation. Scand J Med Sci Sports. 2012;22(5):e86-92.

After the familiarization period, the resistance training protocol began, consisting of four sets of 10 jumps, with a 60-second interval between sets, three times a week, for 12 weeks, following the model used by Teixeira et al.⁹9 Teixeira GR, Fávaro WJ, Pinheiro PFF, Chuffa LGA, Amorim JPA, Mendes LO, et al. Physical exercise on the rat ventral prostate: Steroid hormone receptors, apoptosis and cell proliferation. Scand J Med Sci Sports. 2012;22(5):e86-92.

Periodic evaluation

The animals were periodically assessed for blood glucose and lipid profile during the experimental period, starting one week before the beginning of the pre-training periods, the 8th and 13th weeks of the experimental period.

Analysis of the glycemic response during the experimental period

Blood samples of 25μl were collected from the distal end of the animals’ tails for analysis by photometry using the Accu-Check Active® digital monitor (Roche Diagnosis®, Basel, Switzerland). In the pre-training period, only resting blood glucose was collected from the animals in all groups. On the 13th week, a blood glucose test was carried out on the animals in all groups, as proposed by Oliveira et al.¹⁰10 Oliveira ECD, Gonçalves AC, Silva M, Pedrosa ML, Silva ME. Treino físico promove aumento de peso em ratos desnutridos sem causar stress oxidativo. Motricidade. 2015;11(2):25-35.

Analysis of the lipid profile during the experimental period

The lipid profile was assessed pre-training on the 8th and 13th weeks of training. New blood samples of 25μl were collected from the distal end of the animals’ tails for photometric analysis of total cholesterol and triglycerides using the Accutrend Plus® monitor from Roche Diagnostics® (Basel, Switzerland). This monitor measured triglycerides from 69 mg/dl and total cholesterol from 149 mg/dl. Thus, total cholesterol values were categorized as higher or lower than 149 mg/dl. Triglyceride values were presented in absolute numbers.¹¹11 Uslu S, Alaca N, Kilic KD, Uysal A, Kurtel H. The effects of aerobic exercise frequencies on liver fibrosis, α-fetoprotein and cytokeratin 19 in experimental type 2 diabetes-induced rats: an immunohistochemistry study. Biotech Histochem. 2018;93(8):615-22.

Euthanasia

Body mass was determined using an Ohaus® analytical scale to calculate the animals’ mass gain during the experimental period (Initial Mass - Final Mass = Body Mass Gain). The animals were anesthetized and euthanized according to the methods of Lira et al.⁷7 Lira FS, Koyama CH, Yamashita AS, Rosa JC, Zanchi NE, Batista Jr ML, et al. Chronic exercise decreases cytokine production in healthy rat skeletal muscle. Cell Biochem Funct. 2009;27(7):458-61. 10ml of blood samples were collected to measure High-Density Lipoprotein (HDL) cholesterol. A paramedial incision was made in the abdomen, with the epithelium being folded back to collect the epididymal, mesenteric, and retroperitoneal adipose tissues and the liver. Another incision was made on the lateral side of the tibial region of the lower limb to collect the soleus and gastrocnemius muscles.¹²12 Camargo Filho JCS, Garcia BC, Kodama FY, Bonfim MR, Vanderlei LCM, Ramos EMC. Effects of Aerobic Exercise on the Skeletal Muscle of Rats Exposed to Cigarette Smoke. Rev Bras Med Esp. 2011;17(6):412-5.

Additional variables for the lipid profile

Measurement of relative adipose tissue

The epididymal, mesenteric, and retroperitoneal adipose tissues were weighed on a precision scale, and the percentage relative to the animal's body mass (%) was calculated.¹³13 Barbosa Magalhaes AJ, Trindade Camargo RC, Moreira RJ, Seraphin PM, Oikawa SM, Silva Camargo, JC. Intermittent Training Followed by Detraining Provides the Preservation of Hepatic Tissue and Body Composition of Eutrophic rats in Relation to Obese Rats after the Detraining Period. Int J Morphol. 2018;36(4):1341-9.

HDL cholesterol measurement

The blood samples were used to measure HDL cholesterol using enzymatic methods (CENTERKIT®, São Paulo, Brazil), and colorimetric density was read using a 1600UV® spectrophotometer, brand BUNKER® (Piracicaba, Brazil), with a wavelength of 600nm.⁷7 Lira FS, Koyama CH, Yamashita AS, Rosa JC, Zanchi NE, Batista Jr ML, et al. Chronic exercise decreases cytokine production in healthy rat skeletal muscle. Cell Biochem Funct. 2009;27(7):458-61.

Histological preparation and stereological analysis of liver tissue

Histological preparation of the liver tissue was carried out using the methods of Barbosa Magalhães et al.¹³13 Barbosa Magalhaes AJ, Trindade Camargo RC, Moreira RJ, Seraphin PM, Oikawa SM, Silva Camargo, JC. Intermittent Training Followed by Detraining Provides the Preservation of Hepatic Tissue and Body Composition of Eutrophic rats in Relation to Obese Rats after the Detraining Period. Int J Morphol. 2018;36(4):1341-9. All the images for histological analysis were obtained using a Nikon® 50i optical microscope (New York, United States), coupled with a Nikon® Infinity 1 digital camera (New York, United States).

Ten images per animal were used at 400x magnification for the stereological analysis and stained with Hematoxylin and Eosin (HE). ImageJ® 1.47t for Windows® software (National Institute of Health - Maryland, United States) was used to apply the 144-point multipurpose test recommended by Weibel.¹⁴14 Weibel ER, Kistler GS, Scherle WF. Practical stereological methods for morphometric cytology. J Cell Biol. 1966;30(1):23-38. Using the methods of Catta-Preta et al.,¹⁵15 Catta-Preta M, Mendonca LS, Fraulob-Aquino J, Aguila MB, Mandarim-de-Lacerda CA. A critical analysis of three quantitative methods of assessment of hepatic steatosis in liver biopsies. Virchows Arch. 2011;459(5):477-85. the relative cellular, nuclear, and extracellular matrix portions and the cellular numerical density were obtained.

Histological preparation and morphometric and fractal dimension analysis of skeletal muscle tissue

The soleus and gastrocnemius muscles underwent the histological preparation recommended by Camargo et al.¹²12 Camargo Filho JCS, Garcia BC, Kodama FY, Bonfim MR, Vanderlei LCM, Ramos EMC. Effects of Aerobic Exercise on the Skeletal Muscle of Rats Exposed to Cigarette Smoke. Rev Bras Med Esp. 2011;17(6):412-5. The histological slides of the soleus muscle were stained with HE,¹²12 Camargo Filho JCS, Garcia BC, Kodama FY, Bonfim MR, Vanderlei LCM, Ramos EMC. Effects of Aerobic Exercise on the Skeletal Muscle of Rats Exposed to Cigarette Smoke. Rev Bras Med Esp. 2011;17(6):412-5. PAS¹⁶16 Fiuza-Luces C, Santos-Lozano A, Llavero F, Campo R, Nogales-Gadea G, Díez-Bermejo J, et al. Muscle molecular adaptations to endurance exercise training are conditioned by glycogen availability: a proteomics-based analysis in the McArdle mouse model. J Physiol. 2018;596(6):1035-61. and Sudam III.¹⁶16 Fiuza-Luces C, Santos-Lozano A, Llavero F, Campo R, Nogales-Gadea G, Díez-Bermejo J, et al. Muscle molecular adaptations to endurance exercise training are conditioned by glycogen availability: a proteomics-based analysis in the McArdle mouse model. J Physiol. 2018;596(6):1035-61. Among the histological slides of the gastrocnemius muscle, one sample was stained with HE, and another was immunolocalized with TNF-α antibodies.

Morphological analysis was conducted using NIS-Elements D 3.0 - SP7 - build 547 software, Nikon® for Windows® (New York, United States). In the images of samples stained with HE and magnified at 100x, the smallest diameter of 100 fibers of the soleus and gastrocnemius muscles of each animal was measured.¹²12 Camargo Filho JCS, Garcia BC, Kodama FY, Bonfim MR, Vanderlei LCM, Ramos EMC. Effects of Aerobic Exercise on the Skeletal Muscle of Rats Exposed to Cigarette Smoke. Rev Bras Med Esp. 2011;17(6):412-5.

The Fractal Dimension of the soleus and gastrocnemius muscles was analyzed using ImageJ® 1.47t for Windows® software (National Institute of Health - Maryland, United States), using the systems proposed by Moreira et al.¹⁷17 Moreira RD, Moriel AR, Murta Junior LO, Neves LA, Godoy MF. Dimensão fractal na quantificação do grau de rejeição celular miocárdica pós-transplante cardíaco. Rev Bras Cir Cardiovasc. 2011;26(2):155-63. and Ozaki et al.¹⁸18 Ozaki GAT, Camargo RCT, Koike TE, Garcia TA, Castoldi RC, Camargo Filho JCS. Fractal Analysis of Skeletal Muscle Tissue of Rats Subjected to Stretch Injury. Int J Morphol. 2015;33(3):908-13.

Quantification of concentration of glycogen, lipids, and TNF-α in liver and skeletal muscle tissues

Periodic Acid Schiff (PAS)¹⁶16 Fiuza-Luces C, Santos-Lozano A, Llavero F, Campo R, Nogales-Gadea G, Díez-Bermejo J, et al. Muscle molecular adaptations to endurance exercise training are conditioned by glycogen availability: a proteomics-based analysis in the McArdle mouse model. J Physiol. 2018;596(6):1035-61. was used to assess tissue glycogen concentration, and Sudam III stain¹⁹19 Da Rocha AL, Teixeira GR, Pinto AP, de Morais GP, Oliveira LDC, De Vicente LG, et al. Excessive training induces molecular signs of pathologic cardiac hypertrophy. J Cell Physiol. 2018;233(11):8850-61. was used to assess lipid concentration. In addition, the Tumor Necrosis Factor Alpha (TNF-α) antibody was immunolocalized.

These analyses used images at 20x magnification for skeletal muscle tissue samples and 40x magnification for liver tissue, using ImageJ® 1.47t for Windows® software (National Institute of Health - Maryland, United States), using the method proposed by Da Rocha et al.¹⁹19 Da Rocha AL, Teixeira GR, Pinto AP, de Morais GP, Oliveira LDC, De Vicente LG, et al. Excessive training induces molecular signs of pathologic cardiac hypertrophy. J Cell Physiol. 2018;233(11):8850-61.

Statistical Analysis

Sample sizing was used to calculate the minimum number of animals needed, resulting in eight animals per group; the Randomized Block Design in Factorial Scheme was used to randomize the animals.²⁰20 Montgomery DC. Design and analysis of experiments. 8th ed. Hoboken: Willey; 1991. The Wilcoxon test defined the prevalence of total cholesterol.²⁰20 Montgomery DC. Design and analysis of experiments. 8th ed. Hoboken: Willey; 1991. The Shapiro-Wilk test was used to verify the normality of the data, and the statistical analysis was carried out using the Kruskall-Wallis test and the post-test of Dunn,²⁰20 Montgomery DC. Design and analysis of experiments. 8th ed. Hoboken: Willey; 1991. adopting p<0.05 and using the IBM SPSS 22.0® software.

RESULTS

Table 1 shows no significant difference between the initial (g) and final (g) body mass groups. Still, there was a reduction in body mass in groups AE (p=0.009) and R (p=0.001) compared to S during the experimental period. Serum triglyceride levels in the R group were lower than in the S group at week 13 (p=0.025), with no significant difference in the other periods.

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Table 1
Values referring to body mass (g), serum triglyceride concentration (TG, in mg/dl), mass (g) and percentage (%) of adipose tissue and glycemic test after the experiment.

Figure 1
Use of software: A, B, and C. ImageJ® 1.47t for Windows® for stereological analysis, estimation of glycogen, lipid, IL-6, and TNF-α concentrations and fractal dimension analysis in liver and skeletal muscle tissues; D. NIS-Elements D 3.0 - SP7 - build 547, Nikon® for Windows® for measuring the smallest diameter of muscle fibers.

Figure 2
Photomicrographs of liver tissue: A. PS with a thickness of 5µm and HE staining. Moderate lymphocyte increase in portal spaces (circle) without lymphocyte extravasation, 200X; B. PAE, 5µm thick and HE stained. Discrete lymphocyte increase, without structural alterations or activity (arrow), 200X; C. PR, 5µm thick and HE stained. Moderate lymphocyte increase in portal spaces (circle) with extravasation of lymphocytes and frequent binucleated hepatocytes, some with pyknotic nuclei (arrows). 200X; D. PS with 5µm thickness and PAS staining, 400X; E. PAE; F. PR; G. PS with 5µm thickness and Sudam III staining, 400X; H. PAE; I. PR; J. PS with 5µm thickness and immunolocalized by TNF-α antibody, 400X; K. PAE; L. PR.

Figure 3
Photomicrographs of soleus skeletal muscle tissue: A. PS, 5µm thick and HE stained. Thickening of the perimysium (blue arrow) and endomysium (black arrow) with lymphohistiocytic infiltrate attacking muscle cells (circle), 200X; B. PAE, 5µm thick and HE stained. PAE, 5µm thick and HE stained. Endomysium focally thickened and presence of discreet inflammatory infiltrate (arrows), 200X; C. PR, 5µm thick and HE stained. No significant changes in the tissue, 200X. D. PS, 5µm thick and stained with PAS, 200X; E. PAE; F. PR; G. PS, 5µm thick and stained with Sudam III, 200X; H. PAE; I. PR; J. Photomicrograph of the skeletal muscle tissue of the gastrocnemius of the PS subgroup, with a thickness of 5µm and HE staining. There are no significant histological changes. Isomorphic polygonal skeletal muscle cells with preserved perimysial and endomysial contours, 200X; K. PAE, 5µm thick and HE stained. Focal perimysial thickening with rare lymphocytes (arrow), 200X; L. PR, 5µm thick and HE stained. There are no significant histological changes. Isomorphic polygonal skeletal muscle cells with preserved perimysial and endomysial contours, 200X; M. PS, 5µm thick and immunolocalized by TNF-α antibody, 200X; N. PAE; O. PR.

The adipose tissue mass (g) in group S was higher than in group R (p=0.039). On the other hand, the relative adipose tissue (%) of the S group was higher compared to the AE (p=0.037) and R (p=0.039) groups. Finally, group R had a lower glycemic concentration than group S (p=0.044) at the end of the test (25th minute).

Table 2 shows a higher prevalence of total cholesterol above 149 mg/dl in group S (p=0.034). Serum HDL cholesterol levels (mg/dl) in the AE group were higher than in the S group (p=0.021).

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Table 2
Prevalence (%) of animals with total cholesterol above 149 mg/dl during the experimental period and HDL cholesterol values (mg/dl) after euthanasia.

Liver tissue analysis

Table 3 shows that groups AE and R had a lower numerical density of hepatocytes (p=0.001 and p=0.028), a lower cell volume (p=0.001), and a higher extracellular matrix (p=0.001) compared to S in the sterological analysis, with no significant difference in terms of liver mass.

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Table 3
Stereological analysis values and concentrations (%) of glycogen, lipids, and TNF-α in liver tissue after the experimental period.

The R group had a higher concentration of glycogen (p=0.001) and a lower concentration of lipids (p=0.003) compared to the S. In addition, there was a lower concentration of TNF-α in the AE and R groups (p=0.001) compared to the S, with no significant difference in the concentration of IL-6.

Analysis of skeletal muscle tissue

Table 4 shows no difference in the mass and diameter of the soleus muscle fibers, but AE had a lower fractal dimension than S and R (p=0.001). Group R had a higher muscle glycogen concentration than AE (p=0.001), with no significant difference in lipid concentration.

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Table 4
Values of the smallest diameter of muscle fibers (µm), fractal dimension analysis (UA) and concentrations (%) of glycogen, lipids and TNF-α in the soleus and gastrocnemius muscles after the experimental period.

In the gastrocnemius muscle, there was no difference in muscle mass between the groups, but AE (p=0.001) and R (p=0.003) had larger muscle fiber diameters compared to S. Group R had lower fractal dimension values compared to S and AE (p=0.001). There was no difference in the concentration of IL-6, but R had a lower concentration of TNF-α compared to S and AE (p=0.001).

DISCUSSION

The AE group had lower total cholesterol and HDL concentrations than the S group. According to Rahmati-Ahmadabad et al.,²¹21 Rahmati-Ahmadabad S, Shirvani H, Ghanbari-Niaki A, Rostamkhani F. The effects of high-intensity interval training on reverse cholesterol transport elements: A way of cardiovascular protection against atherosclerosis. Life Sci. 2018;209:377-82. aerobic training increases HDL formation by increasing the hepatic expression of Intracellular Lipid Transporters ATP-binding cassette 1 (ABC1), increasing the transport of total cholesterol and reducing its serum concentration.

In addition, the reduction in visceral adipose tissue and body mass in the AE group compared to the S group may be supported by the transient pro-oxidative state in white adipose tissue after training, favoring increased lipolysis and reduced lipogenesis in adipocytes.²²22 Matta L, Fonseca TS, Faria CC, Lima-Junior NC, De Oliveira DF, Maciel L, et al. The Effect of Acute Aerobic Exercise on Redox Homeostasis and Mitochondrial Function of Rat White Adipose Tissue. Oxid Med Cell Longev. 2021;2021:4593496.

The increase in hepatic and muscular glycogen deposits and lower glycemic concentration presented by R compared to S may have occurred due to the increase in insulin sensitivity, which results in absorption and cellular glycolysis after training.²³23 Cunha TS, Tanno AP, Moura MJCS, Marcondes FK. Influence of high-intensity exercise training and anabolic androgenic steroid treatment on rat tissue glycogen contente. Life Sci. 2005;77(9):1030-43.

At the same time, there was a reduction in body mass, visceral adipose tissue, hepatic lipid concentrations, and serum concentrations of triglycerides and total cholesterol in the R group. Domingos et al.²⁴24 Domingos MM, Rodrigues MF, Stotzer US, Bertucci DR, Souza MV, Marine DA, et al. Resistance training restores the gene expression of molecules related to fat oxidation and lipogenesis in the liver of ovariectomized rats. Eur J Appl Physiol. 2012;112(4):1437-44. observed that resistance training reduces the hepatic expression of SREBP1c and Stearyl-CoA-Desaturase 1 (SDC-1). Thus, post-workout neoglycogenesis occurs from free fatty acids,²³23 Cunha TS, Tanno AP, Moura MJCS, Marcondes FK. Influence of high-intensity exercise training and anabolic androgenic steroid treatment on rat tissue glycogen contente. Life Sci. 2005;77(9):1030-43. which reduces hepatic lipogenesis, increases lipolysis in adipocytes, and reduces serum triglyceride concentrations.²⁴24 Domingos MM, Rodrigues MF, Stotzer US, Bertucci DR, Souza MV, Marine DA, et al. Resistance training restores the gene expression of molecules related to fat oxidation and lipogenesis in the liver of ovariectomized rats. Eur J Appl Physiol. 2012;112(4):1437-44.

The higher concentration of TNF-α and the stereological values of the S group compared to the AE and PR groups suggest an inflammatory process and tissue alterations resulting from a sedentary lifestyle.²³23 Cunha TS, Tanno AP, Moura MJCS, Marcondes FK. Influence of high-intensity exercise training and anabolic androgenic steroid treatment on rat tissue glycogen contente. Life Sci. 2005;77(9):1030-43.–²⁷27 Jarrar BM, Taib NT. Histological and histochemical alterations in the liver induced by lead chronic toxicity. Saudi J Biol Sci. 2012;19(2):203-10. Previous studies³3 Linden MA, Sheldon RD, Meers GM, Ortinau LC, Morris EM, Booth FW, et al. Aerobic exercise training in the treatment of non-alcoholic fatty liver disease related fibrosis. J Physiol. 2016;594(18):5271-84.,⁴4 Sumi K, Ashida K, Nakazato K. Repeated stretch-shortening contraction of the triceps surae attenuates muscle atrophy and liver dysfunction in a rat model of inflammation. Exp Physiol. 2020;105(7):1111-23. have observed a reduction in hepatic IL-1β expression due to aerobic training. Resistance training directly inhibits the transcription of NF-κB and reduces the synthesis of hepatic TNF-α, which may explain the changes in the liver tissue of sedentary animals compared to trained ones.³3 Linden MA, Sheldon RD, Meers GM, Ortinau LC, Morris EM, Booth FW, et al. Aerobic exercise training in the treatment of non-alcoholic fatty liver disease related fibrosis. J Physiol. 2016;594(18):5271-84.,⁴4 Sumi K, Ashida K, Nakazato K. Repeated stretch-shortening contraction of the triceps surae attenuates muscle atrophy and liver dysfunction in a rat model of inflammation. Exp Physiol. 2020;105(7):1111-23.

The AE group showed lower fractal dimension values in the soleus muscle than the others, possibly related to lower muscle tissue inflammation.¹⁸18 Ozaki GAT, Camargo RCT, Koike TE, Garcia TA, Castoldi RC, Camargo Filho JCS. Fractal Analysis of Skeletal Muscle Tissue of Rats Subjected to Stretch Injury. Int J Morphol. 2015;33(3):908-13. Kim et al.,²⁸28 Kim DH, Kim SH, Kim WH, Moon CR. The effects of treadmill exercise on expression of UCP-2 of brown adipose tissue and TNF-α of soleus muscle in obese Zucker rats. J Exerc Nutrition Biochem. 2013;17(4):199-207. observed an increase in the production of Uncoupling Protein 2 (UCP-2) followed by a reduction in the concentration of TNF-α in the soleus muscle after aerobic training. These findings suggest that aerobic training reduces inflammation in the soleus muscle of EA.

Both trained groups had larger gastrocnemius muscle fiber diameters. Resistance training is known to inhibit the Transforming Growth Factor β1 (TGF-β1) signaling pathway,²⁹29 Nikooie R, Jafari-Sardoie S, Sheibani V, Nejadvaziri Chatroudi A. Resistance training-induced muscle hypertrophy is mediated by TGF-β1-Smad signaling pathway in male Wistar rats. J Cell Physiol. 2020;235(7-8):5649-65. while aerobic training activates the Insulin-Linked Growth Factor 1 (IGF-1) and Mammalian Target of Rapamycin (mTOR) signaling pathways.³⁰30 Yin L, Lu L, Lin X, Wang X. Crucial role of androgen receptor in resistance and endurance trainings-induced muscle hypertrophy through IGF-1/IGF-1R- PI3K/Akt- mTOR pathway. Nutr Metab (London). 2020;17:26. Both pathways promote satellite cell activation, post-training protein synthesis for tissue regeneration, and increased muscle trophism in the gastrocnemius.

The lower value in the fractal dimension analysis and the lower concentration of TNF-α in the gastrocnemius of group R compared to the others indicate a reduction in tissue inflammation since resistance training increases the expression of PGC-1α, which activates muscle oxidative capacity and inhibits TNF-α synthesis.⁵5 Takegaki J, Ogasawara R, Kotani T, Tamura Y, Takagi R, Nakazato K, et al. Influence of shortened recovery between resistance exercise sessions on muscle-hypertrophic effect in rat skeletal muscle. Physiol Rep. 2019;7(13):e14155.

However, there was a reduction in muscle inflammation in the soleus of the AE group and the gastrocnemius of the R group. Lira et al.,⁷7 Lira FS, Koyama CH, Yamashita AS, Rosa JC, Zanchi NE, Batista Jr ML, et al. Chronic exercise decreases cytokine production in healthy rat skeletal muscle. Cell Biochem Funct. 2009;27(7):458-61. found that the anti-inflammatory effect in muscles with a predominance of glycolytic metabolism may be related to glycogen content and the physical stress caused by resistance training. In contrast, in muscles with a predominance of aerobic metabolism, the anti-inflammatory effect is related to muscle oxidative capacity during aerobic training. These findings may justify the anti-inflammatory effects on the soleus and gastrocnemius muscles.

CONCLUSION

Both training models reduced body mass, relative visceral adipose tissue, serum total cholesterol concentration, and liver inflammation. However, resistance training promoted better metabolic effects in the liver and skeletal muscle and reduced muscle inflammation in rats compared to aerobic training.

Associate Editor responsible for the review process: André Pedrinelli

ACKNOWLEDGMENTS

We would like to thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for its financial support in the development of this study (process no. 141645/2017-2).

REFERENCES

¹
Cunningham C, Sullivan RO, Caserotti P, Tully MA. Consequences of physical inactivity in older adults: A systematic review of reviews and meta-analyses. Scand J Med Sci Sports. 2020;30(5):816-27.
²
Patsalos O, Keeler J, Schmidt U, Penninx BWJH, Young AH, Himmerich H. Diet, Obesity, and Depression: A Systematic Review. J Pers Med. 2021;11(3):176.
³
Linden MA, Sheldon RD, Meers GM, Ortinau LC, Morris EM, Booth FW, et al. Aerobic exercise training in the treatment of non-alcoholic fatty liver disease related fibrosis. J Physiol. 2016;594(18):5271-84.
⁴
Sumi K, Ashida K, Nakazato K. Repeated stretch-shortening contraction of the triceps surae attenuates muscle atrophy and liver dysfunction in a rat model of inflammation. Exp Physiol. 2020;105(7):1111-23.
⁵
Takegaki J, Ogasawara R, Kotani T, Tamura Y, Takagi R, Nakazato K, et al. Influence of shortened recovery between resistance exercise sessions on muscle-hypertrophic effect in rat skeletal muscle. Physiol Rep. 2019;7(13):e14155.
⁶
Agostinete RR, Rossi FE, Magalhaes AJ, Rocha AP, Parmezzani SS, Gerosa-Neto J, et al. Immunometabolic Responses after Short and Moderate Rest Intervals to Strength Exercise with and without Similar Total Volume. Front Physiol. 2016;7:444.
⁷
Lira FS, Koyama CH, Yamashita AS, Rosa JC, Zanchi NE, Batista Jr ML, et al. Chronic exercise decreases cytokine production in healthy rat skeletal muscle. Cell Biochem Funct. 2009;27(7):458-61.
⁸
Faleiros CM, Francescato H, Papoti M, Chaves L, Silva C, Costa R, et al. Effects of previous physical training on adriamycin nephropathy and its relationship with endothelial lesions and angiogenesis in the renal cortex. Life Sci. 2017;169:43-51.
⁹
Teixeira GR, Fávaro WJ, Pinheiro PFF, Chuffa LGA, Amorim JPA, Mendes LO, et al. Physical exercise on the rat ventral prostate: Steroid hormone receptors, apoptosis and cell proliferation. Scand J Med Sci Sports. 2012;22(5):e86-92.
¹⁰
Oliveira ECD, Gonçalves AC, Silva M, Pedrosa ML, Silva ME. Treino físico promove aumento de peso em ratos desnutridos sem causar stress oxidativo. Motricidade. 2015;11(2):25-35.
¹¹
Uslu S, Alaca N, Kilic KD, Uysal A, Kurtel H. The effects of aerobic exercise frequencies on liver fibrosis, α-fetoprotein and cytokeratin 19 in experimental type 2 diabetes-induced rats: an immunohistochemistry study. Biotech Histochem. 2018;93(8):615-22.
¹²
Camargo Filho JCS, Garcia BC, Kodama FY, Bonfim MR, Vanderlei LCM, Ramos EMC. Effects of Aerobic Exercise on the Skeletal Muscle of Rats Exposed to Cigarette Smoke. Rev Bras Med Esp. 2011;17(6):412-5.
¹³
Barbosa Magalhaes AJ, Trindade Camargo RC, Moreira RJ, Seraphin PM, Oikawa SM, Silva Camargo, JC. Intermittent Training Followed by Detraining Provides the Preservation of Hepatic Tissue and Body Composition of Eutrophic rats in Relation to Obese Rats after the Detraining Period. Int J Morphol. 2018;36(4):1341-9.
¹⁴
Weibel ER, Kistler GS, Scherle WF. Practical stereological methods for morphometric cytology. J Cell Biol. 1966;30(1):23-38.
¹⁵
Catta-Preta M, Mendonca LS, Fraulob-Aquino J, Aguila MB, Mandarim-de-Lacerda CA. A critical analysis of three quantitative methods of assessment of hepatic steatosis in liver biopsies. Virchows Arch. 2011;459(5):477-85.
¹⁶
Fiuza-Luces C, Santos-Lozano A, Llavero F, Campo R, Nogales-Gadea G, Díez-Bermejo J, et al. Muscle molecular adaptations to endurance exercise training are conditioned by glycogen availability: a proteomics-based analysis in the McArdle mouse model. J Physiol. 2018;596(6):1035-61.
¹⁷
Moreira RD, Moriel AR, Murta Junior LO, Neves LA, Godoy MF. Dimensão fractal na quantificação do grau de rejeição celular miocárdica pós-transplante cardíaco. Rev Bras Cir Cardiovasc. 2011;26(2):155-63.
¹⁸
Ozaki GAT, Camargo RCT, Koike TE, Garcia TA, Castoldi RC, Camargo Filho JCS. Fractal Analysis of Skeletal Muscle Tissue of Rats Subjected to Stretch Injury. Int J Morphol. 2015;33(3):908-13.
¹⁹
Da Rocha AL, Teixeira GR, Pinto AP, de Morais GP, Oliveira LDC, De Vicente LG, et al. Excessive training induces molecular signs of pathologic cardiac hypertrophy. J Cell Physiol. 2018;233(11):8850-61.
²⁰
Montgomery DC. Design and analysis of experiments. 8th ed. Hoboken: Willey; 1991.
²¹
Rahmati-Ahmadabad S, Shirvani H, Ghanbari-Niaki A, Rostamkhani F. The effects of high-intensity interval training on reverse cholesterol transport elements: A way of cardiovascular protection against atherosclerosis. Life Sci. 2018;209:377-82.
²²
Matta L, Fonseca TS, Faria CC, Lima-Junior NC, De Oliveira DF, Maciel L, et al. The Effect of Acute Aerobic Exercise on Redox Homeostasis and Mitochondrial Function of Rat White Adipose Tissue. Oxid Med Cell Longev. 2021;2021:4593496.
²³
Cunha TS, Tanno AP, Moura MJCS, Marcondes FK. Influence of high-intensity exercise training and anabolic androgenic steroid treatment on rat tissue glycogen contente. Life Sci. 2005;77(9):1030-43.
²⁴
Domingos MM, Rodrigues MF, Stotzer US, Bertucci DR, Souza MV, Marine DA, et al. Resistance training restores the gene expression of molecules related to fat oxidation and lipogenesis in the liver of ovariectomized rats. Eur J Appl Physiol. 2012;112(4):1437-44.
²⁵
Kowalski GM, Bruce CR. The regulation of glucose metabolism: implications and considerations for the assessment of glucose homeostasis in rodents. Am J Physiol Endocrinol Metab. 2014;307(10):E859-71.
²⁶
Accioly MF, Souza DRS, Padulla SAT, Camargo Filho JCS, do Carmo EM, Martins AT, et al. Effect of statins and aerobic physical exercise on liver function in dyslipidemic rats - Morphometric study. Int J Morphol. 2013;31(4):1309-16.
²⁷
Jarrar BM, Taib NT. Histological and histochemical alterations in the liver induced by lead chronic toxicity. Saudi J Biol Sci. 2012;19(2):203-10.
²⁸
Kim DH, Kim SH, Kim WH, Moon CR. The effects of treadmill exercise on expression of UCP-2 of brown adipose tissue and TNF-α of soleus muscle in obese Zucker rats. J Exerc Nutrition Biochem. 2013;17(4):199-207.
²⁹
Nikooie R, Jafari-Sardoie S, Sheibani V, Nejadvaziri Chatroudi A. Resistance training-induced muscle hypertrophy is mediated by TGF-β1-Smad signaling pathway in male Wistar rats. J Cell Physiol. 2020;235(7-8):5649-65.
³⁰
Yin L, Lu L, Lin X, Wang X. Crucial role of androgen receptor in resistance and endurance trainings-induced muscle hypertrophy through IGF-1/IGF-1R- PI3K/Akt- mTOR pathway. Nutr Metab (London). 2020;17:26.

Publication Dates

Publication in this collection
11 Dec 2023
Date of issue
2024

History

Received
28 Mar 2023
Accepted
08 Aug 2023

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Associate Editor responsible for the review process: André Pedrinelli

Variables (Med (IQ))	PS (n=8)	AE (n=7)	R (n=6)
Initial body mass (g)	336.5 (29.37)	343.5 (28.00)	352.5 (66.12)
Final body mass (g)	474.2 (62.00)	463.5 (46.50)	434.0 (91.25)
Body mass gain (g)	156.5 (34.25)	124.0 (43.00) ^* * p < 0.05 compared to PS.	100.5 (65.50) ^* * p < 0.05 compared to PS.
Pre-training TG (mg/dl)	101.5 (27.25)	108.0 (41.00)	136.0 (31.50)
TG 8th week (mg/dl)	127.5 (23.50)	118.0 (60.50)	114.0 (32.50)
TG 13th week (mg/dl)	132.5 (26.50)	125.0 (69.50)	114.0 (32.50) ^* * p < 0.05 compared to PS.
Mass of adipose tissue (g)	15.52 (5.08)	12.29 (4.55)	9.38 (6.51) ^* * p < 0.05 compared to PS.
Relative adipose tissue (%)	3.54 (0.81)	3.05 (0.83) ^* * p < 0.05 compared to PS.	2.48 (1.21) ^* * p < 0.05 compared to PS.
Resting blood glucose (mg/dl)	89.00 (10.00)	116.00 (10.00)	132.00 (30.00)
Blood glucose 5th min test (mg/dl)	91.00 (4.00)	103.00 (24.00)	136.00 (48.00)
Blood glucose 25th min test (mg/dl)	90.00 (16.00)	102.00 (26.50)	108.00 (31.75) ^* * p < 0.05 compared to PS.

	Total cholesterol (%)			HDL (Med (IQ))
	Pre-training	Week 8	Week 13	Post-euthanasia
PS	50.0%	37.5%	87.5%^* * p<0.05 compared to PS.	35.36 (8.10)
PAE	42.9%	85.7%	14.3%	42.71 (8.09) ^* * p<0.05 compared to PS.
PR	67.7%	33.3%	50.0%	42.97 (18.72)

Variables (Med (IQ))	S (n=8)	AE (n=7)	R (n=6)
Liver mass (g)	11.69 (1.38)	12.70 (2.71)	10.46 (1.42)
Numerical density (nº/µm³)	1.03 (0.05)	0.84 (0.26) ^* * p<0.05 compared to S.	0.87 (0.23) ^* * p<0.05 compared to S.
Cell volume (%)	84.72 (2.43)	79.16 (7.63) ^* * p<0.05 compared to S.	56.25 (10.06) ^* * p<0.05 compared to S.
Nuclear volume (%)	14.58 (5.20)	26.38 (12.84)	21.52 (9.37)
Volume of extracellular matrix (%)	15.27 (2.43)	20.83 (7.63) ^* * p<0.05 compared to S.	43.75 (10.06) ^* * p<0.05 compared to S.
Glycogen (%)	27.70 (16.46)	38.49 (22.55)	47.53 (16.49) ^* * p<0.05 compared to S.
Lipids (%)	54.62 (14.41)	51.74 (17.57)	38.55 (25.58) ^* * p<0.05 compared to S.
TNF-α (%)	40.53 (6.76)	22.44 (7.79) ^* * p<0.05 compared to S.	21.29 (16.11) ^* * p<0.05 compared to S.

Variables (Med (IQ))	S (n=8)	AE (n=7)	R (n=6)
SL mass (g)	0.103 (0.02)	0.099 (0.01)	0.097 (0.01)
GT mass (g)	0.610 (0.07)	0.568 (0.24)	0.655 (0.10)
Smallest SL diameter (µm)	71.34 (9.89)	64.52 (6.56)	64.44 (9.88)
Smallest GT diameter (µm)	55.06 (7.03)	70.05 (5.70) ^* * p<0.05 compared to S.	70.38 (11.66) ^* * p<0.05 compared to S.
DF SL (UA)	1.586 (0.06)	1.510 (0.11) ^* * p<0.05 compared to S. ^† † R.	1.558 (0.07)
DF GT (UA)	1.664 (0.04)	1.532 (0.08)	1.565 (0.12) ^* * p<0.05 compared to S. ^ AE.
Glycogen SL (%)	47.55 (13.88)	34.08 (18.40)	57.57 (36.11) ^ AE.
Lipids SL (%)	68.30 (17.48)	64.23 (11.87)	75.19 (18.51)
TNF-α GT (%)	22.72 (13.95)	24.25 (9.76)	14.50 (10.33) ^* * p<0.05 compared to S. ^ AE.

Brasil

Brasil

HEPATIC AND SKELETAL MUSCLE TISSUE IMMUNOMETABOLISM IN TRAINED RATS

INMUNOMETABOLISMO DEL TEJIDO HEPÁTICO Y MUSCULAR ESQUELÉTICO DE RATAS ENTRENADAS

ABSTRACT

Introduction:

Objective:

Methods:

Results:

Conclusion:

RESUMEN

Introducción:

Objetivo:

Métodos:

Resultados:

Conclusión:

RESUMO

Introdução:

Métodos:

Resultados:

Conclusão:

INTRODUCTION

MATERIALS AND METHODS

Animals

Experimental groups

Training protocols

Protocol for the sedentary group

Aerobic training protocol

Resistance training protocol

Periodic evaluation

Analysis of the glycemic response during the experimental period

Analysis of the lipid profile during the experimental period

Euthanasia

Additional variables for the lipid profile

Measurement of relative adipose tissue

HDL cholesterol measurement

Histological preparation and stereological analysis of liver tissue

Histological preparation and morphometric and fractal dimension analysis of skeletal muscle tissue

Quantification of concentration of glycogen, lipids, and TNF-α in liver and skeletal muscle tissues

Statistical Analysis

RESULTS

Liver tissue analysis

Analysis of skeletal muscle tissue

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History