Efeito da ligadura funcional na prevenção da recorrência da entorse do tornozelo numa equipa de basquetebol feminino

Introdução: O basquetebol é considerado um desporto de alto risco para a ocorrência de lesões, nomeadamente das entorses do tornozelo. Como a história de lesão anterior é um fator de risco para a ocorrência de entroses têm-se desenvolvido estratégias de prevenção para evitar as recidivas, um dos métodos possíveis é o recurso a ligaduras funcionais em “tape”. Objetivo: Neste trabalho vai-se verificar se as ligaduras funcionais em “tape” previnem a recorrência de entorse do tornozelo, numa equipa feminina de basquetebol sub-16. Métodos: A amostra é composta por 9 atletas de basquetebol sub-16 com história de entorse no tornozelo na época precedente, vão-se utilizar ligaduras funcionais no tornozelo. Resultados: A entorse teve 9 registos na época anterior. Não houve registo de qualquer lesão da tibiotársica nos treinos ou jogos, durante a aplicação das ligaduras. Conclusão: A utilização das ligaduras funcionais no grupo estudado, como método de prevenção foi eficaz, não se registando qualquer entorse no decorrer das atividades desportivas (treinos/jogos).

Macrophages as biomarkers in BCG treatment response in bladder cancer

Bladder cancer is a common urologic cancer and the majority has origin in the urothelium. Patients with intermediate and high risk of recurrence/progression bladder cancer are treated with intravesical instillation with Bacillus Calmette-Guérin, however, approximately 30% of patients do not respond to treatment. At the moment, there are no accepted biomarkers do predict treatment outcome and an early identification of patients better served by alternative therapeutics. The treatment initiates a cascade of cytokines responsible by recruiting macrophages to the tumor site that have been shown to influence treatment outcome. Effective BCG therapy needs precise activation of the Th1 immune pathway associated with M1 polarized macrophages. However, tumor-associated macrophages (TAMs) often assume an immunoregulatory M2 phenotype, either immunosuppressive or angiogenic, that interfere in different ways with the BCG induced antitumor immune response. The M2 macrophage is influenced by different microenvironments in the stroma and the tumor. In particular, the degree of hypoxia in the tumors is responsible by the recruitment and differentiation of macrophages into the M2 angiogenic phenotype, suggested to be associated with the response to treatment. Nevertheless, neither the macrophage phenotypes present nor the influence of localization and hypoxia have been addressed in previous studies. Therefore, this work devoted to study the influence of TAMs, in particular of the M2 phenotype taking into account their localization (stroma or tumor) and the degree of hypoxia in the tumor (low or high) in BCG treatment outcome. The study included 99 bladder cancer patients treated with BCG. Tumors resected prior to treatment were evaluated using immunohistochemistry for CD68 and CD163 antigens, which identify a lineage macrophage marker and a M2-polarized specific cell surface receptor, respectively. Tumor hypoxia was evaluated based on HIF-1α expression. As a main finding it was observed that a high predominance of CD163+ macrophage counts in the stroma of tumors under low hypoxia was associated with BCG immunotherapy failure, possibly due to its immunosuppressive phenotype. This study further reinforces the importance the tumor microenvironment in the modulation of BCG responses.

A theoretical study on modelling the respiratory tract with ladder networks by means of intrinsic fractal geometry

Fractional order modeling of biological systems has received significant interest in the research community. Since the fractal geometry is characterized by a recurrent structure, the self-similar branching arrangement of the airways makes the respiratory system an ideal candidate for the application of fractional calculus theory. To demonstrate the link between the recurrence of the respiratory tree and the appearance of a fractional-order model, we develop an anatomically consistent representation of the respiratory system. This model is capable of simulating the mechanical properties of the lungs and we compare the model output with in vivo measurements of the respiratory input impedance collected in 20 healthy subjects. This paper provides further proof of the underlying fractal geometry of the human lungs, and the consequent appearance of constant-phase behavior in the total respiratory impedance.