Hydrodynamic flow patterns and synchronization of beating cilia

We calculate the hydrodynamic flow field generated far from a cilium which is attached to a surface and beats periodically. In the case of two beating cilia, hydrodynamic interactions can lead to synchronization of the cilia, which are nonlinear oscillators. We present a state diagram where synchronized states occur as a function of distance of cilia and the relative orientation of their beat. Synchronized states occur with different relative phases. In addition, asynchronous solutions exist. Our work could be relevant for the synchronized motion of cilia generating hydrodynamic flows on the surface of cells.Comment: 5 pages, 4 figures, v2: minor correction

Somersault of Paramecium in extremely confined environments

We investigate various swimming modes of Paramecium in geometric confinements and a non-swimming self-bending behavior like a somersault, which is quite different from the previously reported behaviors. We observe that Paramecia execute directional sinusoidal trajectories in thick fluid films, whereas Paramecia meander around a localized region and execute frequent turns due to collisions with adjacent walls in thin fluid films. When Paramecia are further constrained in rectangular channels narrower than the length of the cell body, a fraction of meandering Paramecia buckle their body by pushing on the channel walls. The bucking (self-bending) of the cell body allows the Paramecium to reorient its anterior end and explore a completely new direction in extremely confined spaces. Using force deflection method, we quantify the Young’s modulus of the cell and estimate the swimming and bending powers exerted by Paramecium. The analysis shows that Paramecia can utilize a fraction of its swimming power to execute the self-bending maneuver within the confined channel and no extra power may be required for this new kind of self-bending behavior. This investigation sheds light on how micro-organisms can use the flexibility of the body to actively navigate within confined spaces

A Low Percent Ethanol Method for Immobilizing Planarians

Planarians have recently become a popular model system for the study of adult stem cells, regeneration and polarity. The system is attractive for both undergraduate and graduate research labs, since planarian colonies are low cost and easy to maintain. Also in situ hybridization, immunofluorescence and RNA-interference (RNAi) gene knockdown techniques have been developed for planarian studies. However, imaging of live worms (particularly at high magnifications) is difficult because animals are strongly photophobic; they quickly move away from light sources and out of frame. The current methods available to inhibit movement in planarians include RNAi injection and exposure to cold temperatures. The former is labor and time intensive, while the latter precludes the use of many fluorescent reporter dyes. Here, we report a simple, inexpensive and reversible method to immobilize planarians for live imaging. Our data show that a short 1 hour treatment with 3% ethanol (EtOH) is sufficient to inhibit both the fine and gross movements of Schmidtea mediterranea planarians, of the typical size used (4–6 mm), with full recovery of movement within 3–4 hours. Importantly, EtOH treatment did not interfere with regeneration, even after repeated exposure, nor lyse epithelial cells (as assayed by H&E staining). We demonstrate that a short exposure to a low concentration of EtOH is a quick and effective method of immobilizing planarians, one that is easily adaptable to planarians of all sizes and will increase the accessibility of live imaging assays to planarian researchers

Tratamento da esquistossomose mansônica hepatesplênica com praziquantel

Noventa e quatro pacientes, 22 do sexo masculino e 72 do feminino, com idades variando de 11 a 71 anos, média de 25, apresentando a forma hepatesplênica da esquistossomose mansônica, foram tratados com uma nova droga antiesquistossomótica — praziquantel — objetivando-se investigar sua eficácia e tolerância. Duas doses orais — 1 x 30 e 2 x 25 mg/kg — foram comparadas. Efeitos colaterais foram verificados durante os primeiros dois dias seguintes à administração da droga, mas usualmente de média intensidade e curta duração. Os mais freqüentes e, por vezes, mais severos foram: dor ou desconforto abdominal, diarréia, tontura, cefaléia e náusea. Febre esteve presente em 19,2% dos casos e urticaria e prurido em dois pacientes. A investigação laboratorial mostrou, em alguns casos, ligeiras alterações enzimáticas (AST, ALT, γ-GT) 24 horas após a medicação. Nenhuma modificação da urinálise, da glicose sangüínea e dos dados hematológicos foi detectada, exceto o aumento comumente observado dos eosinófilos nos 7." e 30.° dias, relacionado à morte dos parasitas dentro do organismo. Da mesma forma, nenhuma anormalidade foi verificada no estudo eletroencefalográfico. Na eletrocardiografia, observou-se, em duas pacientes, uma ligeira e transitória alteração na repolarização ventricular. No que diz respeito à cura parasitológica, constatou-se, em 62 pacientes que concluíram seis meses de controle, um porcentual global de cura de 80,6%, sendo de 76,7% com a dose de 30 mg/lkg e de 84,4% com a de 2 x 25 mg/kg. Os pacientes não curados tiveram, por outro lado, uma acentuada redução no número de ovos do S. mansoni eliminados nas fezes. Além disso, cinco pacientes não curados, foram retratados seis ou mais meses depois, com a mesma dose inicial, obtendo-se 100°/o de negatividade nos exames de fezes. Os Autores acreditam que com a administração de doses um pouco mais altas como, por exemplo, 60 mg/kg, se possa obter um maior porcentual de cura, sem prejuízo da boa tolerância. A melhora clínica e laboratorial a longo prazo, isto é, seis ou mais meses após a medicação, foi marcante em todos os parâmetros estudados

An Outer Arm Dynein Conformational Switch Is Required for Metachronal Synchrony of Motile Cilia in Planaria

Here we use the motile ventral cilia of the planarian S. mediterranea to examine the role of outer arm dynein in the generation and maintenance of metachronal synchrony. We demonstrate that a single dynein light chain plays a mechanosensory role necessary to entrain and maintain the metachronal synchrony of motile cilia