Desenvolvimento de um fantoma cerebral para ressonância magnética

O controlo da qualidade em ressonância magnética (RM) passa pela realização de diversos testes ao equipamento e calibrações diárias, onde os fantomas desempenham um papel fundamental. Este trabalho teve como objetivo principal o desenvolvimento de um fantoma cerebral para um sistema de RM de intensidade 3.0 Tesla. Com base na literatura existente, escolheram-se como reagentes o cloreto de gadolínio (III) (GdCl3), a agarose, e o gelificante carragena, tendo sido ainda acrescentado o conservante químico azida de sódio (NaN3) de forma a inibir a degradação da solução. Realizaram-se vários testes com diferentes concentrações dos materiais selecionados até obter as misturas adequadas a suscetibilidade magnética das substâncias branca e cinzenta cerebrais. Os tempos de relaxação T1 das diversas substâncias desenvolvidas foram medidos, apresentando o fantoma final uns tempos de T1 de 702±10 ms, quando a concentração de GdCl3 foi de 100 µmol (substância branca) e 1179±23 ms quando a concentração foi de 15 µmol (substância cinzenta). Os valores de T1 do fantoma foram comparados estatisticamente com os tempos de relaxação conseguidos a partir de um cérebro humano, obtendo-se uma correlação de 0.867 com significância estatística. No intuito de demonstrar a aplicabilidade do fantoma, este foi sujeito a um protocolo de RM, do qual constaram as sequências habitualmente usadas no estudo cerebral. Como principais resultados constatou-se que, nas sequências ponderadas em T1, o fantoma apresenta uma forte associação positiva (rs > 0.700 p = 0.072) com o cérebro de referência, ainda que não sejam estatisticamente significativos. As sequências ponderadas em T2 demonstraram uma correlação positiva moderada e fraca, sendo a ponderação densidade protónica a única a apresentar uma associação negativa. Desta forma, o fantoma revelou-se um ótimo substituto do cérebro humano. Este trabalho culminou na criação de um modelo cerebral tridimensional onde foram individualizadas as regiões das substâncias branca e cinzenta, de forma a posteriormente serem preenchidas pelas correspondentes substâncias desenvolvidas, obtendo-se um fantoma cerebral antropomórfico.

Modeling of the lung impedance using a fractional order ladder network with constant phase elements

The self similar branching arrangement of the airways makes the respiratory system an ideal candidate for the application of fractional calculus theory. The fractal geometry is typically characterized by a recurrent structure. This study investigates the identification of a model for the respiratory tree by means of its electrical equivalent based on intrinsic morphology. Measurements were obtained from seven volunteers, in terms of their respiratory impedance by means of its complex representation for frequencies below 5 Hz. A parametric modeling is then applied to the complex valued data points. Since at low-frequency range the inertance is negligible, each airway branch is modeled by using gamma cell resistance and capacitance, the latter having a fractional-order constant phase element (CPE), which is identified from measurements. In addition, the complex impedance is also approximated by means of a model consisting of a lumped series resistance and a lumped fractional-order capacitance. The results reveal that both models characterize the data well, whereas the averaged CPE values are supraunitary and subunitary for the ladder network and the lumped model, respectively.

Characterisation of adventitious lung sounds in people with dementia

Introduction: Lower Respiratory Tract Infections (LRTIs) are highly prevalent in institutionalised people with dementia, constituting an important cause of morbidity and mortality. Computerised auscultation of Adventitious Lung Sounds (ALS) has shown to be objective and reliable to assess and monitor respiratory diseases, however its application in people with dementia is unknown. Aim: This study characterised ALS (crackles and wheezes) in institutionalised people with dementia. Methods: An exploratory descriptive study, including 6 long-term care institutions was conducted. The sample included a dementia group (DG) of 30 people with dementia and a match healthy group (HG) of 30 elderly people. Socio-demographic and anthropometric data, cognition, type and severity of dementia, cardio-respiratory parameters, balance, mobility and activities and participation were collected. Lung sounds were recorded with a digital stethoscope following Computerised Respiratory Sound Analysis (CORSA) guidelines. Crackles’ location, number (N), frequency (F), two-cycle duration (2CD), initial deflection width (IDW) and largest deflection width (LDW) and wheezes’ number (N), ratio (R) and frequency (F) were analysed per breathing phase. Statistical analyses were performed using PASW Statistics(v.19). Results: There were no significant differences between the two groups in relation to the mean N of crackles during inspiration and expiration in both trachea and thorax. DG trachea crackles had significant higher F during inspiration and lower IDW, 2CD and LDW during expiration when compared with HG. At the thorax, the LDW during inspiration was also significantly lower in the DG. A significant higher N of inspiratory wheezes was found in the HG. Both groups had a low ratio of high frequency wheezes. Conclusion: Computerised analyses of ALS informed on the respiratory system and function of people with dementia and elderly people. Hence, this could be the step towards prevention, early diagnosis and continuous monitoring of respiratory diseases in people with cognitive impairment.

Towards Human-like Bimanual Movements in Anthropomorphic Robots: A Nonlinear Optimization Approach

Previously we have presented a model for generating human-like arm and hand movements on an unimanual anthropomorphic robot involved in human-robot collaboration tasks. The present paper aims to extend our model in order to address the generation of human-like bimanual movement sequences which are challenged by scenarios cluttered with obstacles. Movement planning involves large scale nonlinear constrained optimization problems which are solved using the IPOPT solver. Simulation studies show that the model generates feasible and realistic hand trajectories for action sequences involving the two hands. The computational costs involved in the planning allow for real-time human robot-interaction. A qualitative analysis reveals that the movements of the robot exhibit basic characteristics of human movements.