ABSTRACT
The effect of a short-term creatine supplementation on hindlimb suspension (HS)-induced muscle atrophy was investigated. Creatine monohydrate (5 g/kg b.w. per day) or placebo, divided in 2 daily doses, was given by oral gavage for 5 days. Rats were maintained in HS with dietary supplementation concomitantly for 5 days. Body weight, soleus and EDL muscle masses, and cross-sectional areas (CSA) of the muscle fibers were measured. Signaling pathways associated with skeletal muscle mass regulation (FST, MSTN, FAK, IGF-1, MGF, Akt, mTOR, atrogin-1, and MuRF1 expressions, and Akt, S6, GSK3B, and 4EBP1 proteins) were evaluated in the muscles. Soleus muscle exhibited more atrophy than the EDL muscle due to HS. Creatine supplementation attenuated the decrease of wet weight and increased p-4EBP1 protein in the EDL muscle of HS rats. Also, creatine increased mTOR and atrogin-1 expressions in the same muscle and condition. In the absence of HS, creatine supplementation increased FAK and decreased MGF expressions in the EDL muscle. Creatine attenuated the increase in FST expression due to HS in the soleus muscle. MuRF1 expression increased in the soleus muscle due to creatine supplementation in HS animals whereas atrogin-1 expression increased still further in this group compared with untreated HS rats. In conclusion, short-term creatine supplementation changed protein metabolism signaling in soleus and EDL muscles. However, creatine supplementation only slightly attenuated the mass loss of both muscles and did not prevent the CSA reduction and muscle strength decrease induced by HS for 5 days.
Subject(s)
Animals , Male , Rats , Muscular Atrophy/diet therapy , Hindlimb Suspension/adverse effects , Dietary Supplements , Creatine/administration & dosage , Muscular Atrophy/etiology , Signal Transduction/drug effects , Rats, Wistar , Muscle, Skeletal/drug effects , Disease Models, AnimalABSTRACT
High-impact exercise has been considered an important method for treating bone loss in osteopenic experimental models. In this study, we investigated the effects of osteopenia caused by inactivity in femora and tibiae of rats subjected to jump training using the rat tail suspension model. Eight-week-old female Wistar rats were divided into five groups (n=10 each group): jump training for 2 weeks before suspension and training during 3 weeks of suspension; jump training for 2 weeks before suspension; jump training only during suspension; suspension without any training; and a control group. The exercise protocol consisted of 20 jumps/day, 5 days/week, with a jump height of 40 cm. The bone mineral density of the femora and tibiae was measured by double energy X-ray absorptiometry and the same bones were evaluated by mechanical tests. Bone microarchitecture was evaluated by scanning electron microscopy. One-way ANOVA was used to compare groups. Significance was determined as P<0.05. Regarding bone mineral density, mechanical properties and bone microarchitecture, the beneficial effects were greater in the bones of animals subjected to pre-suspension training and subsequently to training during suspension, compared with the bones of animals subjected to pre-suspension training or to training during suspension. Our results indicate that a period of high impact exercise prior to tail suspension in rats can prevent the installation of osteopenia if there is also training during the tail suspension.
Subject(s)
Animals , Female , Bone Diseases, Metabolic/prevention & control , Hindlimb Suspension/physiology , Physical Conditioning, Animal/physiology , Biomechanical Phenomena/physiology , Bone Density/physiology , Cancellous Bone/pathology , Femur/pathology , Femur/physiology , Hindlimb Suspension/adverse effects , Models, Animal , Rats, Wistar , Tibia/pathology , Tibia/physiologyABSTRACT
Osteoporosis has become a serious global public health issue. Hence, osteoporotic fracture healing has been investigated in several previous studies because there is still controversy over the effect osteoporosis has on the healing process. The current study aimed to analyze two different periods of bone healing in normal and osteopenic rats. Sixty, 7-week-old female Wistar rats were randomly divided into four groups: unrestricted and immobilized for 2 weeks after osteotomy (OU2), suspended and immobilized for 2 weeks after osteotomy (OS2), unrestricted and immobilized for 6 weeks after osteotomy (OU6), and suspended and immobilized for 6 weeks after osteotomy (OS6). Osteotomy was performed in the middle third of the right tibia 21 days after tail suspension, when the osteopenic condition was already set. The fractured limb was then immobilized by orthosis. Tibias were collected 2 and 6 weeks after osteotomy, and were analyzed by bone densitometry, mechanical testing, and histomorphometry. Bone mineral density values from bony calluses were significantly lower in the 2-week post-osteotomy groups compared with the 6-week post-osteotomy groups (multivariate general linear model analysis, P<0.000). Similarly, the mechanical properties showed that animals had stronger bones 6 weeks after osteotomy compared with 2 weeks after osteotomy (multivariate general linear model analysis, P<0.000). Histomorphometry indicated gradual bone healing. Results showed that osteopenia did not influence the bone healing process, and that time was an independent determinant factor regardless of whether the fracture was osteopenic. This suggests that the body is able to compensate for the negative effects of suspension.
Subject(s)
Animals , Female , Bone Diseases, Metabolic/physiopathology , Fracture Healing/physiology , Tibial Fractures/physiopathology , Bone Density/physiology , Bony Callus/physiopathology , Collagen/analysis , Hindlimb Suspension/adverse effects , Hindlimb Suspension/physiology , Models, Animal , Osteotomy/adverse effects , Random Allocation , Rats, Wistar , Time Factors , Torsion, MechanicalABSTRACT
To explore whether an environment of weightlessness will cause damage to the reproductive system of animals, we used the tail-suspension model to simulate microgravity, and investigated the effect of microgravity on the tissue structure and function of the testis in sexually mature male rats. Forty-eight male Wistar rats weighing 200-250 g were randomly assigned to three groups (N = 16 each): control, tail traction, and tail suspension. After the rats were suspended for 7 or 14 days, morphological changes of testis were evaluated by histological and electron microscopic methods. The expression of HSP70, bax/bcl-2 and AR (androgen receptor) in testis was measured by immunohistochemistry. Obvious pathological lesions were present in the testis after the rats were suspended for 7 or 14 days. We detected overexpression of HSP70 and an increase of apoptotic cells, which may have contributed to the injury to the testis. The expression of AR, as an effector molecule in the testis, was significantly decreased in the suspended groups compared to control (P < 0.01). We also observed that, with a longer time of suspension, the aforementioned pathological damage became more serious and some pathological injury to the testis was irreversible. The results demonstrated that a short- or medium-term microgravity environment could lead to severe irreversible damage to the structure of rat testis.
Subject(s)
Animals , Humans , Male , Rats , Testis/ultrastructure , Weightlessness Simulation/adverse effects , /analysis , Hindlimb Suspension/adverse effects , Immunohistochemistry , Microscopy, Electron, Transmission , Random Allocation , Rats, Wistar , Receptors, Androgen/analysis , Testis/metabolism , Testis/pathology , /analysisABSTRACT
Longos períodos de imobilização conduzem à perda óssea e de propriedades do osso, e sua recuperação depende de vários fatores; além disso, a imobilização pode causar ulcerações no tecido cartilaginoso articular devido a alterações como perda de proteoglicanas, de massa e volume totais da cartilagem. O objetivo deste estudo foi verificar alterações histológicas, do tecido ósseo periarticular e da cartilagem articular, provocadas pela imobilização e remobilização de membros posteriores de ratos Wistar. Foram utilizados 12 ratos Wistar, divididos em dois grupos: GI - (n = 6): 15 dias com o membro posterior esquerdo imobilizado em plantiflexão, sendo o membro direito o controle; GR - (n = 6): período de 15 dias de remobilização livre na gaiola, associado a três séries diárias de alongamento do músculo sóleo esquerdo por 30 segundos. Foram avaliados no tecido ósseo as medidas de espessura do osso cortical, diâmetro do canal medular e número de osteócitos; no tecido cartilaginoso, foram mensurados a espessura média da cartilagem e o número de condrócitos. Como resultado, observou-se que para GI não houve alterações significativas na espessura do osso (p = 0,1156) nem no diâmetro do canal medular (p = 0,5698), mas diminuição significativa dos osteócitos em relação ao contralateral (p = 0,0005); em GR também houve decréscimo no número de osteócitos (p = 0,0001), mas as diferenças na espessura (p = 0,1343) e diâmetro do canal medular (p = 0,6456) mantiveram-se não significantes. Para os dados de cartilagem articular não houve diferenças significativas para as amostras, tanto na espessura da cartilagem para GI (p = 0,6640) e GR (p = 0,1633), quanto no número de condrócitos em GI (p = 0,9429) e GR (p = 0,1634). Conclui-se que duas semanas de imobilização e remobilização produziram apenas diminuição significativa no número de osteócitos nos ratos imobilizados; esse número continuou a diminuir mesmo nos animais remobilizados.
Long immobilization periods lead to bone and properties loss, and its recovery depends on many factors. Besides that, immobilization can cause ulcerations in the articular cartilage tissue due to alterations, such as loss of proteoglycans and total cartilage mass and volume. The aim of this study was to verify histological alterations of the periarticular bone tissue and articular cartilage caused by immobilization as well as remobilization of hinder limbs of Wistar rats. Twelve Wistar rats were divided in two groups: GI - (n=6): 15 days with the left hinder limb immobilized at plantiflexion, with the right limb being the control; GR - (n=6): used a 15 day-period of free remobilization in the cage, associated with 3 daily stretching bouts of the left soleus muscle for 30 seconds. The measures of the cortical bone thickness, diameter of the medular channel and number of condrocites were evaluated; in the cartilage tissue, the cartilage mean thickness and the number of condrocites were measured. The results showed that for GI there were no significant alterations in the bone thickness (p=0.1156), nor in the medular channel diameter (p=0.5698), but there was significant decrease of the osteocytes compared with the counter-lateral side (p=0.0005); in GR decrease in the number of osteocytes (p=0.0001) was also observed, but the differences in thickness (p=0.1343) and medular channel diameter (p=0.6456) remained non-significant. There were no significant differences for the articular cartilage data for the samples, neither in the cartilage thickness for GI (p=0.6640) and GR (p=0.1633); concerning the number of condrocites in GI (p=0.9429) and GR (p=0.1634). It is concluded hence that two weeks of immobilization and remobilization produced only significant decrease in the number of osteocytes in the immobilized rats and continued to decrease even in the remobilized animals.
Subject(s)
Animals , Male , Rats , Bone Density/physiology , Hindlimb Suspension/adverse effects , Hindlimb Suspension/methods , Immobilization/adverse effects , Muscle Stretching Exercises , Bone and Bones/metabolism , Osteoporosis/metabolism , Rats, WistarABSTRACT
Trinta e quatro ratos foram alocados em quatro grupos experimentais: sem imobilização (G1), com imobilização do joelho direito por 45 dias (G2), com imobilização e remobilização com atividade livre por cinco semanas (G3), imobilização e remobilização com atividade livre e natação por cinco semanas (G4). A imobilização interferiu negativamente na marcha e amplitude articular e o G4 apresentou melhor evolução na marcha nos cinco primeiros dias, em relação ao G3. Após esse período, a evolução foi similar. Os componentes do G2 apresentaram rigidez articular, não observada em G3 e G4. Histologicamente, a imobilização promoveu aumento da espessura da cápsula articular, evidenciada pela presença do tecido conjuntivo fibroso que substituiu o tecido adiposo no G2, mas em menor proporção em G3 e G4. A imobilização determinou perda de proteoglicanos da matriz cartilaginosa, aumento do número de condrócitos, dispostos de forma irregular, aumento da espessura da cartilagem calcificada, irregularidade da superfície articular, proliferação de tecido conjuntivo no espaço intra-articular e aumento da espessura do osso subcondral. O G3 apresentou maior número de alterações na cartilagem e osso subcondral, quando comparado com G4. A imobilização degenerou as células sinoviais, indicando diminuição da produção de fluido sinovial e do suprimento nutricional à cartilagem. Tanto a atividade livre quanto sua associação com a natação favoreceram o retorno das condições biomecânicas e da cápsula articular, anteriores à imobilização.
Thirty-four rats were randomly allocated into one of four experimental groups: without immobilization (G1), immobilization of the right knee joint for 45 days (G2), immobilization and remobilization with free activity for 5 weeks (G3), and immobilization and remobilization with free activity and swimming program for 5 weeks (G4). The immobilization was prejudicial to march and flexibility articular. Animals from G4 showed a better march evolution on the first five days as compared to those from G3. After that periods, march evolution were similar in both G3 and G4. Animals from G2 showed rigid joint while in those from G3 and G4 the articular movement was close to normal. The histological analysis pointed out that immobilization led to increase in articular capsule thickness evidenced by the presence of fibrous connective tissue replacing adipose tissue in G2, but proportionally less in G3 and G4. It was observed that immobilization determined loss of proteoglycans from the cartilaginous matrix, increase in the number of regularly arranged condrocytes, increase in calcified cartilage thickness, irregularity in the articular surface, proliferation of connective tissue in the intra-articular space and increase in subchondral bone thickness. The animals from G3 showed a greater number of alterations in both articular cartilage and subchondral bone, as compared to those from G4. Immobilization degenerated synovial cells indicating decreased synovial fluid production and reduced nutritional supplying to the cartilage. The free cage activity and its association with swimming influenced positively the return of biomechanics and articular capsule morphologic conditions to those before immobilization.