The transport of liquids in softwood: timber as a model porous medium.

Timber is the only widely used construction material we can grow. The wood from which it comes has evolved to provide structural support for the tree and to act as a conduit for fluid flow. These flow paths are crucial for engineers to exploit the full potential of timber, by allowing impregnation with liquids that modify the properties or resilience of this natural material. Accurately predicting the transport of these liquids enables more efficient industrial timber treatment processes to be developed, thereby extending the scope to use this sustainable construction material; moreover, it is of fundamental scientific value - as a fluid flow within a natural porous medium. Both structural and transport properties of wood depend on its micro-structure but, while a substantial body of research relates the structural performance of wood to its detailed architecture, no such knowledge exists for the transport properties. We present a model, based on increasingly refined geometric parameters, that accurately predicts the time-dependent ingress of liquids within softwood timber, thereby addressing this long-standing scientific challenge. Moreover, we show that for the minimalistic parameterisation the model predicts ingress with a square-root-of-time behaviour. However, experimental data show a potentially significant departure from this [Formula: see text] behaviour - a departure which is successfully predicted by our more advanced parametrisation. Our parameterisation of the timber microstructure was informed by computed tomographic measurements; model predictions were validated by comparison with experimental data. We show that accurate predictions require statistical representation of the variability in the timber pore space. The collapse of our dimensionless experimental data demonstrates clear potential for our results to be up-scaled to industrial treatment processes.

Cell geometry across the ring structure of Sitka spruce.

For wood to be used to its full potential as an engineering material, it is necessary to quantify links between its cell geometry and the properties it exhibits at bulk scale. Doing so will make it possible to predict timber properties crucial to engineering, such as mechanical strength and stiffness, and the resistance to fluid flow, and to inform strategies to improve those properties as required, as well as to measure the effects of interventions such as genetic manipulation and chemical modification. Strength, stiffness and permeability of timber all derive from the geometry of its cells, and yet current practice is to predict them based on properties, such as bulk density, that do not directly describe the cell structure. This work explores links between micro-computed tomography data for structural-size pieces of wood, which show the variation of porosity across the wood's ring structure, and high-resolution tomography showing the geometry of the cells, from which we measure cell length, lumen area, porosity, cell wall thickness and the number density of cells. High-resolution scans, while informative, are time-consuming and expensive to run on a large number of samples at the scale of building components. By scanning the same volume of timber at both low and high resolutions (high-resolution scans over a near-continuous volume of timber of approx. 20 mm3 at 15 µm3 per voxel), we are able to demonstrate correlations between the measurements at the two different resolutions, reveal the physical basis for these correlations, and demonstrate that the data from the low-resolution scan can be used to estimate the variation in (small-scale) cell geometry throughout a structural-size piece of wood.

Recurrent temporary paralysis reported after human rabies post-exposure prophylaxis.

Adverse events can occur after rabies post-exposure prophylaxis (PEP), and linkage to causality is often difficult to determine. We report a case of recurrent temporary paralysis that began immediately after the initiation of rabies PEP in a man exposed to a bat. The recurrent temporary paralysis first occurred in the patient after his initial dose and then again after day 3 of his rabies PEP. The PEP was terminated prior to a serologic response. The patient continued to experience numerous discrete episodes of temporary paralysis for over two years.

Expression of transforming growth factor-beta type I and type II receptors is altered in rat lungs undergoing bleomycin-induced pulmonary fibrosis.

Transforming growth factor-beta (TGF-beta) is a family of autocrine/paracrine/endocrine cytokines involved in controlling cell growth and extracellular matrix metabolism. TGF-beta exerts its biological effects via binding to type I (TbetaRI) and type II (TbetaRII) receptors. To gain insight into the possible role of TGF-beta receptors in the pathogenesis of pulmonary fibrosis, we investigated the expression of TGF-beta receptors and their ligands in a bleomycin-induced model of pulmonary fibrosis. We found that the expression of both TbetaRI and TbetaRII was altered in rat lungs during pulmonary fibrosis induced by bleomycin. The increase in TbetaRI mRNA level was evident after 3 days of bleomycin administration, and TbetaRI mRNA continually increased for over 12 days after bleomycin instillation, whereas TbetaRII mRNA declined at day 3 post bleomycin instillation and then increased during the reparative phase of lung injury (days 8 and 12). The immunoreactivity for both TbetaRI and TbetaRII was detected in the cells of the interstitium, the epithelium, and the blood vessels of normal rat lungs. In bleomycin-induced pulmonary fibrosis, an extensive immunostaining for TbetaRI and TbetaRII was present in the cells at the sites of injury and active fibrosis. These results demonstrate that the expression of TGF-beta type I and type II receptors was altered during pulmonary fibrosis, suggesting that the TGF-beta signal transduction pathway may be involved in the pathogenesis of lung fibrosis.