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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Análise da existência de máxima fase estável de lactato nos exercícios resistidos leg press 45º e supino reto / Analysis of the existance of a maximal lactate steady state on resistance exercises leg press 45° and bench press

Rodrigo Ferro Magosso 26 July 2010 (has links)
O objetivo deste estudo foi verificar se existe máxima fase estável de lactato (MFEL) nos exercícios LP e SR e analisar o comportamento de variáveis ventilatórias ventilação (Ve) e consumo de oxigênio (VO2), bem como lactacidemia, freqüência cardíaca (FC) e percepção subjetiva de esforço (PSE) na intensidade da MFEL e comparar as respostas entre os exercícios. Foram avaliados 12 homens jovens (20-33 anos) saudáveis e com experiência mínima de 6 meses em treinamento resistido, que passaram por teste de 1 repetição máxima (1RM), teste crescente para determinação do limiar anaeróbio (AT) e mais três sessões para a determinação da MFEL. Todas as sessões foram realizadas no mesmo horário do dia, separadas por 48 a 72 horas de intervalo. O valor de 1RM no LP foi de 298,0 ± 36,6 kg enquanto que no SR foi 93,7 ± 21,8 kg. A intensidade máxima atingida no teste crescente no LP foi 70,00 ± 12,25% de 1RM e no SR 50,00 ± 8,16% de 1RM, sendo esta diferença estatisticamente significativa (p0,05). A lactacidemia final também foi significativamente maior (p0,05) no LP comparada ao SR (8,36 ± 2,34 vs. 5,43 ± 1,12 mmol/L, respectivamente). O AT, expresso em percentual de 1RM, no LP foi de 27,9 ± 3,7% e no SR de 24,1 ± 4,4% de 1RM, porém esta diferença não foi estatisticamente significante. A lactacidemia no momento do teste crescente em que o AT era atingido também não apresentou diferença significativa, sendo 2,29 ± 0,58 mmol/L no LP e 2,52 ± 0,65 no SR. A intensidade da MFEL, no LP foi de 29,17 ± 7,02% de 1RM, enquanto que no SR a intensidade da MFEL foi de 21,67 ± 4,44% de 1RM, sendo esta diferença estatisticamente significativa (p0,05). No LP não houve diferença significativa entre as intensidades do AT e da MFEL (27,9 ± 3,7% e 29,2 ± 7,0% de 1RM, respectivamente). No SR intensidade do AT foi significativamente maior (p0,05) que a intensidade da MFEL (24,1 ± 3,4% e 21,7 ± 4,4% de 1RM, respectivamente). Durante a realização de exercício na MFEL, a ocorreu aumento de Ve, VO2, FC e PSE seguidos de estabilização, sem diferenças entre os exercícios. Estes resultados demonstram que é possível verificar MFEL nos exercícios LP e SR, e que no LP a intensidade é maior. As diferenças encontradas no teste crescente e na intensidade da MFEL são provavelmente causadas pelas características dos exercícios. / The purpose of the study was to verify if there is a maximal lactate steady state (MLSS) for the Leg Press (LP) and Bench Press (BP) exercises and to analyse ventilatory responses ventilation (Ve) and oxygen uptake (VO2), heart rate (HR), blood lactate concentration (BLC) and ratings of perceived exertion (RPE) to those exercises performed on MLSS intensity and to compare those responses for the exercises. 12 young healthy men with a minimal experience of 6 months of resistance training volunteered for the study. Volunteers underwent a 1 repetition maximum test (1RM), na incremental test to determine anaerobic threshold (AT) and three more sessions to determine MLSS. Session were performed on the same time of Day and separeted by a 48-72h interval. 1RM values for LP and BP were 298,0 ± 36,6kg and 93,7 ± 21,8 kg, respectively. The maximal intensity in the incremental test was 70 ± 12,25% of 1RM for LP and 50,00 ± 8,16% of 1RM for BP, which was a significant difference (p0,05). Post-test blood lactate concentration (BLS) was also significantly higher for LP (8,36 ± 2,34 vs. 5,43 ± 1,12 mmol/L, respectively) (p0,05). AT intensity and was not significantly different for LP and BP (27,9 ± 3,7% vs. 24,1 ± 3,6, respectively). BLC on AT was not significantly different for LP (2,29 ± 0,58 mmol/L) and BP (2,52 ± 0,65). MLSS intensity on LP (29,17 ± 7,02% of 1RM) was significantly higher (p0,05) compared to MFEL on BP (21,67 ± 4,44% of 1RM). When compared to AT, MLSS intensity for LP was not significantly different, but for BP it was significantly lower. During exercise on MLSS, oxygen uptake and ventilation, HR and RPE rose significantly compares to rest and then stabilized. There were no differences between exercises. These results show that it is possible to identify a MLSS on the LP and BP exercises, and that for LP this intensity is higher. The differences found between exercises can be atributted to the intrinsic caractheristics of each exercise.
22

Reliability of the calculated maximal lactate steady state in amateur cyclists

Adam, Jennifer, Oehmichen, Matthias, Oehmichen, Eva, Rother, Janine, Müller, Ulrike Maria, Hauser, Thomas, Schulz, Henry 13 July 2015 (has links)
Abstract provided by Publisher Complex performance diagnostics in sports medicine should contain maximal aerobic and maximal anaerobic performance. The requirements on appropriate stress protocols are high. To validate a test protocol quality criteria like objectivity and reliability are necessary. Therefore, the present study was performed in intention to analyze the reliability of maximal lactate production rate (VLamax) by using a sprint test, maximum oxygen consumption (VO2max) by using a ramp test and, based on these data, resulting power in calculated maximum lactate-steady-state (PMLSS) especially for amateur cyclists. All subjects (n=23, age 26 ± 4 years) were leisure cyclists. At three different days they completed first a sprint test to approximate VLamax. After 60 min of recreation time a ramp test to assess VO2max was performed. The results of VLamax-test and VO2max-test and the body weight were used to calculate PMLSS for all subjects. The intra class correlation (ICC) for VLamax and VO2max was 0.904 and 0.987, respectively, coefficient of variation (CV) was 6.3 % and 2.1 %, respectively. Between the measurements the reliable change index of 0.11 mmol∙l-1∙s-1 for VLamax and 3.3 ml∙kg-1∙min-1 for VO2max achieved significance. The mean of the calculated PMLSS was 237 ± 72 W with an RCI of 9 W and reached with ICC = 0.985 a very high reliability. Both metabolic performance tests and the calculated PMLSS are reliable for leisure cyclists.
23

Comparison of calculated and experimental power in maximal lactate-steady state during cycling

Hauser, Thomas, Adam, Jennifer, Schulz, Henry 11 July 2014 (has links)
Background: The purpose of this study was the comparison of the calculated (MLSSC) and experimental power (MLSSE) in maximal lactate steady-state (MLSS) during cycling. Methods: 13 male subjects (24.2 ± 4.76 years, 72.9 ± 6.9 kg, 178.5 ± 5.9 cm, V_O2max: 60.4 ± 8.6 ml min−1 kg−1, V_ Lamax: 0.9 ± 0.19 mmol l-1 s-1) performed a ramp-test for determining the V_O2max and a 15 s sprint-test for measuring the maximal glycolytic rate (V_ Lamax). All tests were performed on a Lode-Cycle-Ergometer. V_O2max and V_ Lamax were used to calculate MLSSC. For the determination of MLSSE several 30 min constant load tests were performed. MLSSE was defined as the highest workload that can be maintained without an increase of blood-lactate-concentration (BLC) of more than 0.05 mmol l−1 min−1 during the last 20 min. Power in following constant-load test was set higher or lower depending on BLC. Results: MLSSE and MLSSC were measured respectively at 217 ± 51 W and 229 ± 47 W, while mean difference was −12 ± 20 W. Orthogonal regression was calculated with r = 0.92 (p < 0.001). Conclusions: The difference of 12 W can be explained by the biological variability of V_O2max and V_ Lamax. The knowledge of both parameters, as well as their individual influence on MLSS, could be important for establishing training recommendations, which could lead to either an improvement in V_O2max or V_ Lamax by performing high intensity or low intensity exercise training, respectively. Furthermore the validity of V_ Lamax -test should be focused in further studies.

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