Kapi`wara: Um Jogo de Tabuleiro Cooperativo Ecológico-Pedagógico sobre o Rio Pinheiros e suas Capivaras.

A Educação ambiental possui uma perspectiva interdisciplinar, segundo Dias (1992), e perante tantos problemas ambientais, é uma necessidade no ensino fundamental. Os jogos pedagógicos servem de apoio durante o processo de aprendizagem e por terem caráter lúdico, proporcionam atividades educacionais que podem ser mais criativas e motivadoras. O presente trabalho tem por objetivo apresentar a elaboração de um jogo ecológico-pedagógico que envolve design gráfico e de produtos que visa conscientizar seus jogadores sobre o meio ambiente e sensibiliza-los por essas questões. O jogo aborda algumas questões do meio ambiente na cidade de São Paulo, a escassez de recursos naturais, destacando a água, o descarte inadequado de dejetos e a poluição do rio Pinheiros, utilizando as capivaras que habitam as margens deste rio como recurso lúdico para contextualizar o objetivo. Por meio do jogo de tabuleiro cooperativo, propõem-se despertar o interesse e a preocupação nos participantes sobre a condição em que o rio Pinheiros se encontra e sobre a escassez de recursos naturais na cidade de São Paulo. Além do ensino de Ecologia e Educação Ambiental, o projeto visa a integração e a colaboração entre os jogadores, motivando-os de tal modo que possam participar ativamente da melhoria desse quadro

Dynamic effective elasticity of melanoma cells under shear and elongational flow confirms estimation from force spectroscopy

The detection and enrichment of circulating melanoma cells is a challenge, as the cells are very heterogeneous in terms of their biomechanical properties and surface markers. In addition, there is a lack of valid and reliable biomarkers predicting progress and therapeutic response. In this study, we analyze the elasticity of A375 melanoma cells by applying force spectroscopy and a microfluidic method. To identify and eventually separate freely circulating tumor cells, it is crucial to know their physical properties precisely. First, we use standard AFM force spectroscopy, where the elasticity of the cells is calculated from indentation with a pyramidal tip. To extend the limits of the measurements with a tip, we then use cantilevers without a tip to apply force over a larger area of the cells. The resulting Young’s moduli are slightly lower and vary less without the tip, presumably because of the spatial inhomogeneity of the cells. Finally, we implement our microfluidic method: we measure single cell elasticity by analyzing their deformation in high-speed micrographs while passing a stenosis. Combining the force field and the change in shape provides the basis for a stress–strain diagram. The results from the microfluidic deformation analysis were well in accordance with the results from force spectroscopy. The microfluidic method, however, provides advantages over conventional methods, as it is less invasive and less likely to harm the cell during the measurement. The whole cell is measured as one entity without having contact to a stiff substrate, while force spectroscopy is limited to the contact area of the tip, and in some cases dependent of the cell substrate interaction. Consequently, microfluidic deformation analysis allows us to predict the overall elastic behavior of the whole, inhomogeneous cell in three-dimensional force fields. This method may contribute to improve the detection of circulating melanoma cells in the clinical practice

Survival of Plasmodium falciparum infected Red Blood Cell Aggregates in Elongational Shear Flow

Rosetting, the formation of red blood cell aggregates, is a life-threatening condition in malaria tropica and not yet fully understood. We study rosette stability using a set of microfluidic stenotic channels, with varied narrowing angle and erythrocytes of blood groups O and A. We find reduced ability of a rosette to pass a stenosis without disruption, the longer the tapered part of the constriction and the narrower the stenosis is. In general, this ability increases with rosette size and is 5-15% higher in blood group A. The experimental results are substantiated by equivalent experiments using lectin-induced red blood cell aggregates and a simulation of the underlying protein binding kinetics.</p

Aromatic polymers made by reductive polydehalogenation of oligocyclic monomers as conjugated polymers of intrinsic microporosity (C-PIMs)

Reductive dehalogenation polycondensation of a series of penta-or hexacyclic, bisgeminal tetrachlorides with dicobalt octacarbonyl leads to the formation of homopolymers and copolymers with very different optical spectra. While the formation of tetrabenzoheptafulvalene connectors introduces efficient conjugation barriers due to their strongly folded structure, linking of 5-membered ring-based pentacyclic building blocks via bifluorenylidene connectors allows for an extended π-conjugation along the main chain. A comparison of homopolymer P57 and copolymer P55/77 indicates a quite different reactivity for dichloromethylene functions if incorporated into 5-or 7-membered rings. Interestingly, all investigated (co)polymers show an intrinsic microporosity in the solid-state (forming so-called Conjugated Polymers of Intrinsic Microporosity C-PIMs) and have SBET values of up to 760 m2 g-1 for homopolymer P77. This value is one of the highest reported values to date for C-PIMs

Edge photocurrent in bilayer graphene due to inter-Landau-level transitions

We report the observation of the resonant excitation of edge photocurrents in bilayer graphene subjected to terahertz radiation and a magnetic field. The resonantly excited edge photocurrent is observed for both inter-band (at low carrier densities) and intra-band (at high densities) transitions between Landau levels (LL). While the intra-band LL transitions can be traced to the classical cyclotron resonance (CR) and produce strong resonant features, the inter-band-LL resonances have quantum nature and lead to the weaker features in the measured photocurrent spectra. The magnitude and polarization properties of the observed features agree with the semiclassical theory of the intra-band edge photogalvanic effect, including its Shubnikov-de-Haas oscillations at low temperatures.Comment: 11 pages, 11 figure