Avaliação da força muscular inspiratória (PImáx) durante o desmame da ventilação mecânica em pacientes neurológicos internados na unidade de terapia intensiva

A ventilação mecânica, freqüentemente necessária em pacientes em estado crítico, pode ser associada à perda de força muscular respiratória por diversos mecanismos. Nosso objetivo foi avaliar a progressão da força da musculatura respiratória durante o processo de desmame, por mensuração seriada da PImáx até a independência completa da ventilação mecânica em pacientes neurológicos. A PImáx foi avaliada evolutivamente, uma vez ao dia, durante todo o período de desmame, com auxílio de manovacuômetro e válvula unidirecional. Foram incluídos no estudo 31 pacientes neurológicos (pós acidente vascular ou trauma crânio-encefálico) em desmame ventilatório e os valores obtidos foram comparados aos previstos, segundo Black e Hyatt. A média de PImáx inicial (primeiro dia do desmame) foi - 40,0±20,0 cmH2O (39% do previsto) (pMechanical ventilation, often needed in critically ill patients, may be associated to loss of respiratory muscular force due to several mechanisms. The objective was to assess the progression of respiratory muscular force during weaning from mechanical ventilation by using serial measurement of maximum inspiratory pressure until complete discontinuation in neurological patients. The PImax was progressively assessed by using manovacuometer and unidirectional valve once a day during the whole period of mechanical ventilation weaning. Thirty-one neurological patients (after stroke or craniocerebral trauma) undergoing weaning from mechanical ventilation were included for study, and the values obtained were compared to those established by Black and Hyatt. The initial mean PImax (first day of weaning) was - 40.0±20.0 cmH2O (39% of the expected value) (p < 0.05), reaching 50% at day 5 and 60% at day 10. It was observed an increase of 21% (p < 0.05) between the first and tenth days. On the 13th day, mechanical ventilation had been completely discontinued in all patients. Therefore a progressive evaluation of the inspiratory muscular force in patients undergoing prolonged mechanical ventilation shows that the complete discontinuation is possible in neurological patients with 72% of the established values

Predicting Spatial Patterns of Plant Recruitment Using Animal-Displacement Kernels

For plants dispersed by frugivores, spatial patterns of recruitment are primarily influenced by the spatial arrangement and characteristics of parent plants, the digestive characteristics, feeding behaviour and movement patterns of animal dispersers, and the structure of the habitat matrix. We used an individual-based, spatially-explicit framework to characterize seed dispersal and seedling fate in an endangered, insular plant-disperser system: the endemic shrub Daphne rodriguezii and its exclusive disperser, the endemic lizard Podarcis lilfordi. Plant recruitment kernels were chiefly determined by the disperser's patterns of space utilization (i.e. the lizard's displacement kernels), the position of the various plant individuals in relation to them, and habitat structure (vegetation cover vs. bare soil). In contrast to our expectations, seed gut-passage rate and its effects on germination, and lizard speed-of-movement, habitat choice and activity rhythm were of minor importance. Predicted plant recruitment kernels were strongly anisotropic and fine-grained, preventing their description using one-dimensional, frequency-distance curves. We found a general trade-off between recruitment probability and dispersal distance; however, optimal recruitment sites were not necessarily associated to sites of maximal adult-plant density. Conservation efforts aimed at enhancing the regeneration of endangered plant-disperser systems may gain in efficacy by manipulating the spatial distribution of dispersers (e.g. through the creation of refuges and feeding sites) to create areas favourable to plant recruitment

The Advantage of Standing Up to Fight and the Evolution of Habitual Bipedalism in Hominins

BACKGROUND: Many quadrupedal species stand bipedally on their hindlimbs to fight. This posture may provide a performance advantage by allowing the forelimbs to strike an opponent with the range of motion that is intrinsic to high-speed running, jumping, rapid braking and turning; the range of motion over which peak force and power can be produced. METHODOLOGY/PRINCIPAL FINDINGS: To test the hypothesis that bipedal (i.e., orthograde) posture provides a performance advantage when striking with the forelimbs, I measured the force and energy produced when human subjects struck from "quadrupedal" (i.e., pronograde) and bipedal postures. Downward and upward directed striking energy was measured with a custom designed pendulum transducer. Side and forward strikes were measured with a punching bag instrumented with an accelerometer. When subjects struck downward from a bipedal posture the work was 43.70±12.59% (mean ± S.E.) greater than when they struck from a quadrupedal posture. Similarly, 47.49±17.95% more work was produced when subjects struck upward from a bipedal stance compared to a quadrupedal stance. Importantly, subjects did 229.69±44.19% more work in downward than upward directed strikes. During side and forward strikes the force impulses were 30.12±3.68 and 43.04±9.00% greater from a bipedal posture than a quadrupedal posture, respectively. CONCLUSIONS/SIGNIFICANCE: These results indicate that bipedal posture does provide a performance advantage for striking with the forelimbs. The mating systems of great apes are characterized by intense male-male competition in which conflict is resolved through force or the threat of force. Great apes often fight from bipedal posture, striking with both the fore- and hindlimbs. These observations, plus the findings of this study, suggest that sexual selection contributed to the evolution of habitual bipedalism in hominins