The problem of handedness reversal during the spiral growth of Phycomyces

One may easily conclude that the mechanism of cell wall growth of the sporangiophore of Phycomyces is an extremely complex one since the sporangiophore not only grows vertically (stretches) but also rotates (twists) about its longitudinal axis during growth. The result is spiral growth. The spiraling changes direction during the sporangiophore's development going from an initial left-handed spiral to a right-handed one and finally returning to the left-handed form. We believe that these observations can be explained in the following way. The cell's turgor pressure causes both longitudinal and radial deformation in the soft, thin, plastic region of the growing cell wall thus causing the wall to stretch. The cell wall microfibrils, which are initially oriented in a near transverse direction in the upper region of the growing zone, are displaced toward the longitudinal axis as a result of vertical stretch. This fibril displacement, from a transverse to a longitudinal direction, causes a horizontal displacement of the cell wall. This horizontal displacement is coupled with the vertical stretch to generate a spiral effect, i.e. spiral growth. We are further proposing that interfibril slippage occurs as the cell wall softens between stages IVa and IVb and it is this slippage that accounts for the change in the direction of spiraling when the sporangiophore goes from the left-handed form to the right-handed one.     

Coupled oxygen transport analysis in the avascular wall of a post-angioplasty coronary artery stenosis

The coupled oxygen transport in the avascular wall of a coronary artery stenosis is studied by numerically solving the convection-diffusion equations. Geometry, replicating residual stenosis after percutaneous transluminal coronary angioplasty (PTCA), is used for the analysis. Important physiological aspects, such as oxygen consumption in the wall, oxygen carried by the hemoglobin, non-Newtonian viscosity of the blood, and supply of oxygen from the vasa vasorum are included. Mean blood flow rate in the lumen is varied from basal to hyperemic conditions. The results show that the P(O2) in the medial region of the arterial wall is approximately 10 mmHg. The oxygen flux to the wall increases in the flow acceleration region, whereas it decreases at the flow reattachment zone. Near the location of flow separation there is a small rise and a sharp fall in the oxygen flux. The minimum P(O2) in the avascular wall, P(O2, min ), at the point of flow reattachment reduces to approximately 6 mmHg for a 300 micron wall thickness. For a thinner wall of 200 micron, the P(O2, min ) at the location of flow reattachment increases to 6 times that of a 300 micron wall. The P(O2, min ) in the wall decreases by 60% when volumetric oxygen consumption is increased by 30% for the same avascular wall thickness.     

Wall extensibility: its nature, measurement and relationship to plant cell growth

Expansive growth of plant cells is controlled principally by processes that loosen the wall and enable it to expand irreversibly. The central role of wall relaxation for cell expansion is reviewed. The most common methods for assessing the extension properties of plant cell walls ( wall extensibility') are described, categorized and assessed critically. What emerges are three fundamentally different approaches which test growing cells for their ability (a) to enlarge at different values of turgor, (b) to induce wall relaxation, and (c) to deform elastically or plastically in response to an applied tensile force. Analogous methods with isolated walls are similarly reviewed. The results of these different assays are related to the nature of plant cell growth and pertinent biophysical theory. I argue that the extensibilities' measured by these assays are fundamentally different from one another and that some are more pertinent to growth than others.     

Differential histone modification and protein expression associated with cell wall removal and regeneration in rice (Oryza sativa)

The cell wall is a critical extracellular structure that provides protection and structural support in plant cells. To study the biological function of the cell wall and the regulation of cell wall resynthesis, we examined cellular responses to enzymatic removal of the cell wall in rice (Oryza sativa) suspension cells using proteomic approaches. We find that removal of cell wall stimulates cell wall synthesis from multiple sites in protoplasts instead of from a single site as in cytokinesis. Nucleus DAPI stain and MNase digestion further show that removal of the cell wall is concomitant with substantial chromatin reorganization. Histone post-translational modification studies using both Western blots and isotope labeling assisted quantitative mass spectrometry analyses reveal that substantial histone modification changes, particularly H3K18(AC) and H3K23(AC), are associated with the removal and regeneration of the cell wall. Label-free quantitative proteome analyses further reveal that chromatin associated proteins undergo dramatic changes upon removal of the cell wall, along with cytoskeleton, cell wall metabolism, and stress-response proteins. This study demonstrates that cell wall removal is associated with substantial chromatin change and may lead to stimulation of cell wall synthesis using a novel mechanism.     

The formation of the cyst wall of the metacercaria of Fasciola hepatica L.

Summary The several concentric layers of the cyst wall of Fasciola hepatica are formed from precursors synthesised in the cystogenic cells of the cercaria during its development in the redia. A cinematographic analysis shows that the separate components are released in succession during encystment.The outer portion of the wall consists of two layers: a tanned protein and a carbohydrate-protein complex. The granular precursors of these are formed in separate groups of cells and migrate from these cells into the superficial epithelium (embryonic epithelium) during development. They are released to form the outer wall by the bursting of the embryonic epithelium at the beginning of encystment. This process is rapid and is completed in a few minutes.A pause follows the separation of the outer wall during which a further polysaccharide layer is released and the cells, which contain the rod-like scrolls of sheets of the laminated component of the inner wall, migrate from within the cercaria through gaps in the superficial musculature on to the cercarial surface to form a new epithelium replacing that previously shed.The cercaria now begins a series of complex oscillatory movements within the enveloping outer cyst wall during which the scrolls are secreted into the space underneath the outer wall, unroll and are compacted by the animal's movements into the lamellar inner wall.The rodlets are enclosed in vacuoles and their secretion is effected by the fusion of the vacuolar membrane with the plasma membrane without destroying the integrity of the cells, which remain to constitute the epithelium of the juvenile fluke when this emerges later.     

Study of Pole Assembly in Bacillus subtilis by Computer Reconstruction of Septal Growth Zones Seen in Central, Longitudinal Thin Sections of Cells

The septal growth of Bacillus subtilis 168/s has been studied by making a number of observations from thin sections of cells from exponentially growing cultures. The process was initiated by the formation of a new cross wall under a preexisting layer of cylindrical wall. An annular notch appeared to cut through the overlying wall and presumably allowed the cross wall to split into two layers of peripheral wall. During this initial notching process, two raised bands of wall material were produced which resembled those previously observed in morphological studies of Streptococcus faecalis. Through an improved fixation technique, it was possible to preserve the bands seen in B. subtilis to the extent that they were used as markers to study the subsequent stages of septal growth. These stages included (i) the continued displacement of the two bands from the cross wall (as the two nascent polar surfaces enlarged and as the diameter of the cross wall decreased), (ii) the closure of the cross wall, and (iii) the final severance of the common cross wall connection between two completed poles. To study this process in a more quantitative manner, three-dimensional reconstructions of the envelope observed between pairs of the raised bands were made from axial thin sections of cells. The process of reconstruction was based on a technique by which x, y coordinates were taken from thin sections and were rotated around the cell's central axis. These reconstructions were used to estimate the surface area or volume of the reconstructed zones or their parts. A round of septal growth was then simulated by arranging 118 reconstructions in order of increasing surface area or volume. The topology of the process was studied by noting how various measurements of septal thickness, length, surface area, and volume varied as a function of increasing septal zone size. This analysis was based on several assumptions, of which three of the most important are: (i) the bands produced by the initial notching process are markers which separate septal from cylindrical wall growth; (ii) a septal zone observed between pairs of bands is made up of two nascent poles and a single cross wall; and (iii) as septal zones develop in terms of relative age they increase in size (volume or surface area) or amount of wall. The data suggested that the S. faecalis model of surface growth (in which polar growth occurs through a regulated constrictive separation and expansion of a cross wall) also seems applicable to the pattern of septal growth observed here for B. subtilis. This was indicated from measurements which showed that increases in the size of nascent polar surfaces were correlated with decreases in cross wall diameter. An explanation of these observations may be that decreases in cross wall diameter were due to a progressive splitting of the cross wall that removed surface from the outer circumference of the cross wall and converted it into new polar surface. Calculations further suggested that if the poles of B. subtilis were made by this model a sizeable and variable increase in surface area of the cross wall would also be required to convert these separating cross wall layers into two curved polar structures. Measurements of wall thickness taken from various locations within septal zones indicated that while the thickness of the polar wall of B. subtilis was constant over its surface, the width of the cross wall varied considerably during a round of synthesis. Again, one of the simplest explanations compatible with these observations and those previously made in S. faecalis is that the B. subtilis cross wall is brought to a constant thickness (possibly by remodeling or precursor addition) before or during separation. Although most observations made from the reconstruction of the septal zones of B. subtilis may fit the S. faecalis model of surface growth, differences in the pattern of septal growth were seen when the two organisms were compared. These have been discussed in terms of differences in the regulation of their respective septal growth sites and basic mechanisms of wall assembly and modification.     

Reciprocal influence of ethylene and gibberellins on response-gene expression in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

A cortical band of fiber cells originate de novo in tendrils of redvine [Brunnichia ovata (Walt.) Shiners] when these convert from straight, supple young filaments to stiffened coiled structures in response to touch stimulation. We have analyzed the cell walls of these fibers by in situ localization techniques to determine their composition and possible role(s) in the coiling process. The fiber cell wall consists of a primary cell wall and two lignified secondary wall layers (S₁ and S₂) and a less lignified gelatinous (G) layer proximal to the plasmalemma. Compositionally, the fibers are sharply distinct from surrounding parenchyma as determined by antibody and affinity probes. The fiber cell walls are highly enriched in cellulose, callose and xylan but contain no homogalacturonan, either esterified or de-esterified. Rhamnogalacturonan-I (RG-I) epitopes are not detected in the S layers, although they are in both the gelatinous layer and primary wall, indicating a further restriction of RG-I in the fiber cells. Lignin is concentrated in the secondary wall layers of the fiber and the compound middle lamellae/primary cell wall but is absent from the gelatinous layer. Our observations indicate that these fibers play a central role in tendril function, not only in stabilizing its final shape after coiling but also generating the tensile strength responsible for the coiling. This theory is further substantiated by the absence of gelatinous layers in the fibers of the rare tendrils that fail to coil. These data indicate that gelatinous-type fibers are responsible for the coiling of redvine tendrils and a number of other tendrils and vines.     

Stabilization of cell wall proteins in Bacillus subtilis: a proteomic approach

Even though cell wall proteins of Bacillus subtilis are characterized by specific cell wall retention signals, some of these are also components of the extracellular proteome. In contrast to the majority of extracellular proteins, wall binding proteins disappeared from the extracellular proteome during the stationary phase and are subjected to proteolysis. Thus, the extracellular proteome of the multiple protease-deficient strain WB700 was analyzed which showed an increased stability of secreted WapA processing products during the stationary phase. In addition, stabilization of the WapA processing products was observed also in a sigD mutant strain which is impaired in motility and cell wall turnover. Next, we analyzed if proteins that can be extracted from B. subtilis cell walls are stabilized in the WB700 strain as well as in the sigD mutant. Thus, the cell wall proteome of B. subtilis wild type was defined showing most abundantly cell wall binding proteins (CWBPs) resulting from the WapA and WprA precursor processing. The inactivation of extracellular proteases as well as SigmaD caused an increase of CWBP105 and a decrease of CWBP62 in the cell wall proteome. We conclude that WapA processing products are substrates for the extracellular proteases which are stabilized in the absence of sigD due to an impaired cell wall turnover.     

Geometry of varicose veins segments

The geometry of varicose vein segments, chosen from macroscopically normal as well as unmistakable dilated (bulbous) sites of the vessels, were studied in specimens obtained from stripping operations. Geometrical aspects (valves, dilatations) were studied on the vein slit open in axial direction and geometrical parameters (mean diameter, wall thickness) were measured on 3 sets of strips cut in circumferential direction with special reference to their location to the valves. In normal segments the vein is enlarged immediately proximal to the valves. In contrast to this, the bulbous and assymetric protrusions found in the diseased segments lie just below the valves, that is upstream. Values of diameters, wall thickness and wall thickness to diameter ratios are plotted as mean +/- SD in bar graphs. Results indicate that 1. the diameter has a maximum value at the valvular site both in the normal and the diseased segments; the normal diameters are smaller than the corresponding diseased ones. 2. The wall thickness increases from the distal to the proximal site in the normal segments, whereas it displays a minimum value at the valvular site of the bulbous segments. 3. The wall thickness to diameter ratios of both the normal and the pathological segments have a minimum at valvular site, but the normal values are larger than the corresponding pathological values, a behavior which is more apparent in the bulbous enlargements and even evident in the hypertrophied side of the wall opposite to the protrusions.     

Estimating wall guidance and attraction in mouse free locomotor behavior

In this study, we estimate the influence exerted by the wall of the Open Field on the trajectory of the mouse. The wall exerts two types of influence on the mouse's path: one of guidance and one of attraction. The guiding influence is expressed by the tendency of mice to progress in parallel to the wall. This tendency wanes with increasing distance from the wall but is observed at large distances from it. The more parallel the mouse is to the wall the higher is its speed, even when distant from the wall. This association between heading direction and speed shows that the mouse controls its heading in reference to the wall. It is also observed in some blind strains, revealing that wall-guidance is not based exclusively on vision. The attraction influence is reflected by movement along the wall and by the asymmetry between speed during movement toward, and during movement away from the wall: sighted mice move faster toward the wall, whereas blind mice use similar speeds in both directions. Measures characterizing these influences are presented for five inbred strains, revealing heritable components that are replicable across laboratories. The revealed structure can lead to the identification of distinct groups of genes that mediate the distinct influences of guidance and attraction exerted by the wall. It can also serve as a framework for the decoding of electrophysiological data recorded in free moving rodents in the Open Field.     

Constructing and deconstructing the bacterial cell wall

The history of modern medicine cannot be written apart from the history of the antibiotics. Antibiotics are cytotoxic secondary metabolites that are isolated from Nature. The antibacterial antibiotics disproportionately target bacterial protein structure that is distinct from eukaryotic protein structure, notably within the ribosome and within the pathways for bacterial cell‐wall biosynthesis (for which there is not a eukaryotic counterpart). This review focuses on a pre‐eminent class of antibiotics—the β‐lactams, exemplified by the penicillins and cephalosporins—from the perspective of the evolving mechanisms for bacterial resistance. The mechanism of action of the β‐lactams is bacterial cell‐wall destruction. In the monoderm (single membrane, Gram‐positive staining) pathogen Staphylococcus aureus the dominant resistance mechanism is expression of a β‐lactam‐unreactive transpeptidase enzyme that functions in cell‐wall construction. In the diderm (dual membrane, Gram‐negative staining) pathogen Pseudomonas aeruginosa a dominant resistance mechanism (among several) is expression of a hydrolytic enzyme that destroys the critical β‐lactam ring of the antibiotic. The key sensing mechanism used by P. aeruginosa is monitoring the molecular difference between cell‐wall construction and cell‐wall deconstruction. In both bacteria, the resistance pathways are manifested only when the bacteria detect the presence of β‐lactams. This review summarizes how the β‐lactams are sensed and how the resistance mechanisms are manifested, with the expectation that preventing these processes will be critical to future chemotherapeutic control of multidrug resistant bacteria.     

Ultrastructure of soybean nodules. I: release of rhizobia from the infection thread

Root nodules on soybeans (var. Clark 63) were examined by transmission electron microscopy 10-12 days after seed inoculation and planting. The cell infection process appeared identical in both effective nodules, induced by Rhizobium japonicum strain 138 (USDA) and in ineffective nodules, induced by strain 8-0 (Iowa). Electron micrographs are presented which suggest that rhizobia are freed from the infection thread by disintegration of the thread wall and compartmentalization of the distintegrated wall material in membrane-bound vesicles derived from the membrane surrounding the thread. As the thread wall is removed in this manner, the bacteria are released into the host cytoplasm by a process which encloses each in an envelope also dervide from the thread membrane. Any thread wall material remaining around a bacterium after it has dissociated from the thread is removed from the envelope space by vesiculation of the membrane envelope. thus, it appears that endocytosis of both the bacteria and the material composing the infection thread wall occurs during release of rhizobia into the host cell.     

The role of the heat shock protein Hsp12p in the dynamic response of Saccharomyces cerevisiae to the addition of Congo red

In this study, we investigate the electrohydrodynamic and nanomechanical characteristics of two Saccharomyces cerevisiae yeast strains, a wild-type (WT) strain and a strain overexpressing (OE) Hsp12p, in the presence and absence of hydrophobic Congo red compound. By combining these two advanced biophysical methods, we demonstrate that Hsp12p proteins are mostly located within a thin layer ( c . 10 nm thick) positioned at the external side of the cell wall. However, this Hsp12p-enriched layer does not prevent Congo red from entering the cell wall and from interacting with the chitin therein. The entrance of Congo red within the cell wall is reflected in an increase of the turgor pressure for the OE strain and a decrease of that for the WT strain. It is shown that these opposite trends are consistent with significant modulations of the water content within the cell wall from/to the cytoplasm. These are the result of changes in the hydrophobicity/hydrophilicity balance, as governed by the intertwined local concentration variations of Congo red and Hsp12p across the cell wall. In particular, the decrease of the turgor pressure in the case of WT strain upon addition of Congo red is shown to be consistent with an upregulation of Hsp12p in the close vicinity of the plasma membrane.     

Pulse wave velocity as a diagnostic index: the pitfalls of tethering versus stiffening of the arterial wall

Pulse wave velocity (PWV) is often used as a clinical index of aging, vascular disease, or age related hypertension. This practice is based on the assumption that a higher wave speed indicates vascular stiffening. This assumption is well grounded in the physics of pulsatile flow of an incompressible fluid where it is fully established that a pulse wave travels faster in a tube of stiffer wall, the wave speed becoming infinite in the mathematical limit of a rigid wall. However, in this paper we point out that the physical principal of higher pulse wave velocity in a stiffer tube is strictly valid only when the wall is free from outside constraints, which in the physiological setting is present in the form of tethering of the vessel wall. The use of PWV as an index of arterial stiffening may thus lose its validity if tethering is involved. A solution of the problem of vessel wall mechanics as they arise from the physiological pulsatile flow problem is presented for the purpose of resolving this issue. The vessel wall is considered to have finite thickness with or without tethering and with a range of mechanical properties ranging from viscoelastic to stiff. The results show that, indeed, while the wave speed becomes infinite in the mathematical limit of a rigid free wall, the opposite actually happens if the vessel wall is tethered. Here the wave speed actually diminishes as the degree of tethering increases. This dichotomy in the effects of tethering versus stiffening of the arterial wall may clearly lead to error in the interpretation of PWV as an index of vessel wall stiffness. In particular, a normal value of PWV may lead to the conclusion that vessel wall stiffening is absent while this value may in fact have been lowered by tethering. In other words, the diagnostic test may lead to a false negative diagnosis. Our results indicate that the reason for which PWV is lower in a tethered wall compared with that in a free wall of the same stiffness is that the radial movements of the wall are greatly reduced by tethering. More precisely, the results show that PWV depends strongly on the ratio of radial to axial displacements and that this ratio is much lower in a tethered wall than it is in a free wall of the same stiffness.     

Growth,cell wall formation and differentiation in the protonema of the moss,Funaria hygrometrica: Effects of plasmolysis on the developmental program and its expression

Summary Cultivation ofFunaria protonemata under plasmolytic or slightly subplasmolytic conditions initially causes a cessation of growth which is accompanied by a transient disappearance (or strong reduction in frequency, respectively) of putative cellulose synthesizing particle rosettes in the plasma membrane. Simultaneously, the formation and exocytosis of cell wall materialsecreting Golgi vesicles is slowed down. The latter process does not become apparent for several hours, though the reduction in activity can be proved indirectly. As a consequence of the imbalance between exocytosis, cell wall material accumulates in the plasmolytic space, generally at the cell tip. This indicates that the pattern of local, polar deposition of cell wall formation and cell elongation, membrane debris as well as wall material is maintained for some time. Later, however, the whole protoplast may become covered by new wall layers. Potentially growing filament tips and the distal region of nontip cells increase in diameter after longer cultivation in subplasmolytic conditions. It is suggested that normal wall growth results from a softening of the existing wall, its stretching and simultaneous stabilization by the apposition of new wall layers. We believe that the swelling is caused by a change in the equilibrium between the obviously less affected softening process and the imperfect stabilization by new wall layers because the wall layers which are formed at reduced turgor pressure are looser than normal and may have a changed composition.Kinetin-induced buds do not develop under plasmolytic conditions. Instead, spiral filaments are formed which readily give rise to buds when the osmotic value of the (kinetin-containing) medium is normalized. The results show that plasmolysis affects the expression of the developmental program rather than its initiation or maintenance.     

Ultrastructural specialization at the host-pathogen interface in rust-infected flax

Summary Ultrastructure of the association between the rust fungus, Melampsora lini, and a compatible variety of flax, Linum usitatissimum, was studied to clarify the structural relationships and interactions at the site of host penetration and at the host-parasite interface. Results of freeze-etching as well as a special section-staining procedure consisting of periodate-chromate-phosphotungstate (PACP) are shown with a host-parasite combination for the first time. The host plasma membrane is invaginated by the fungus and forms a continuous boundary around the fungal haustoria which penetrate the host cells. No morphological continuities are observed linking the protoplasts of host and fungus. With both freeze-etching and the PACP stain, the invaginated portion of the host plasma membrane at the host-parasite interface shows distinctive features that are not characteristic of the non-invaginated portion of the membrane. This localized specialization of host plasma membrane in response to the fungus appears as a significant and consistent feature of the host-parasite interaction. The host plasma membrane is separated from the haustorial wall by an amorphous layer of sheath material which covers the body but not the neck of the haustorium. This sheath provides the environment in which the haustorium exists and functions during the course of the host-parasite association. Occasionally, a collar of wall-like material derived from the host cell forms around the haustorial neck. The collar is continuous with the host wall and is distinct and discontinuous from the haustorial sheath. In fewer than 5% of the infected cells this wall material encases entire haustoria. The fungal wall is structurally specialized around the site of host penetration, and it becomes intimately associated with the host wall where the fungus penetrates into the lumen of the host cell. During penetration, the host and fungal walls appear to be fused so that the interface between them is not clearly delineated. The haustorial wall is continuous, via the haustorial neck, with the wall of the haustorial mother cell which lies outside the host cell. Different staining properties reveal this wall continuum to consist of several well-defined regions having different structure or composition. A ring of fungal wall material midway along the haustorial neck stains densely with lead citrate, but is preferentially etched away by periodic acid. The neck ring denotes a transition in the staining reaction of the fungal wall, from that present in the region of host penetration to that of the wall surrounding the haustorium. The findings demonstrate specialization of the fungal wall in the area of host penetration as well as specialization of the host plasma membrane at the host-parasite interface to a degree not previously realized from ultrastructural information.     

Teichoic acid is an essential polymer in Bacillus subtilis that is functionally distinct from teichuronic acid

Wall teichoic acids are anionic, phosphate-rich polymers linked to the peptidoglycan of gram-positive bacteria. In Bacillus subtilis, the predominant wall teichoic acid types are poly(glycerol phosphate) in strain 168 and poly(ribitol phosphate) in strain W23, and they are synthesized by the tag and tar gene products, respectively. Growing evidence suggests that wall teichoic acids are essential in B. subtilis; however, it is widely believed that teichoic acids are dispensable under phosphate-limiting conditions. In the work reported here, we carefully studied the dispensability of teichoic acid under phosphate-limiting conditions by constructing three new mutants. These strains, having precise deletions in tagB, tagF, and tarD, were dependent on xylose-inducible complementation from a distal locus (amyE) for growth. The tarD deletion interrupted poly(ribitol phosphate) synthesis in B. subtilis and represents a unique deletion of a tar gene. When teichoic acid biosynthetic proteins were depleted, the mutants showed a coccoid morphology and cell wall thickening. The new wall teichoic acid biogenesis mutants generated in this work and a previously reported tagD mutant were not viable under phosphate-limiting conditions in the absence of complementation. Cell wall analysis of B. subtilis grown under phosphate-limited conditions showed that teichoic acid contributed approximately one-third of the wall anionic content. These data suggest that wall teichoic acid has an essential function in B. subtilis that cannot be replaced by teichuronic acid.     

ULTRASTRUCTURE AND TAXONOMIC POSITION OF THE RARE VOLVOCALEAN ALGA,CHLORCORONA BOHEMICA1

Chlorcorona bohemica (Fott) Fott was previously of uncertain taxonomic affinities. The cell to cell connections, which are one of the chief features of the colony, are composed of wall extensions from adjacent cells. The outgrowths are connected by a fine fibrous component extending from wall to wall. The structure of the wall itself and the cell to cell connections, are similar to those of Pyrobotrys, although the connections in the latter are not as elongated. In addition, the flagellar apparatus of Chlorocorona is very similar to the flagellar apparatus of Pyrobotrys, and unlike that in other Chlorophyceae examined. These features suggest that Chlorcorona is closely related to Pyrobotrys and should be referred to the family Spondylomoraceae.     

Wall stress and flow dynamics in abdominal aortic aneurysms: finite element analysis vs. fluid-structure interaction

Abdominal aortic aneurysm (AAA) rupture is the clinical manifestation of an induced force exceeding the resistance provided by the strength of the arterial wall. This force is most frequently assumed to be the product of a uniform luminal pressure acting along the diseased wall. However fluid dynamics is a known contributor to the pathogenesis of AAAs, and the dynamic interaction of blood flow and the arterial wall represents the in vivo environment at the macro-scale. The primary objective of this investigation is to assess the significance of assuming an arbitrary estimated peak fluid pressure inside the aneurysm sac for the evaluation of AAA wall mechanics, as compared with the non-uniform pressure resulting from a coupled fluid-structure interaction (FSI) analysis. In addition, a finite element approach is utilised to estimate the effects of asymmetry and wall thickness on the wall stress and fluid dynamics of ten idealised AAA models and one non-aneurysmal control. Five degrees of asymmetry with uniform and variable wall thickness are used. Each was modelled under a static pressure-deformation analysis, as well as a transient FSI. The results show that the inclusion of fluid flow yields a maximum AAA wall stress up to 20% higher compared to that obtained with a static wall stress analysis with an assumed peak luminal pressure of 117 mmHg. The variable wall models have a maximum wall stress nearly four times that of a uniform wall thickness, and also increasing with asymmetry in both instances. The inclusion of an axial stretch and external pressure to the computational domain decreases the wall stress by 17%.     

Wall stress and flow dynamics in abdominal aortic aneurysms: finite element analysis vs. fluid–structure interaction

Abdominal aortic aneurysm (AAA) rupture is the clinical manifestation of an induced force exceeding the resistance provided by the strength of the arterial wall. This force is most frequently assumed to be the product of a uniform luminal pressure acting along the diseased wall. However fluid dynamics is a known contributor to the pathogenesis of AAAs, and the dynamic interaction of blood flow and the arterial wall represents the in vivo environment at the macro-scale. The primary objective of this investigation is to assess the significance of assuming an arbitrary estimated peak fluid pressure inside the aneurysm sac for the evaluation of AAA wall mechanics, as compared with the non-uniform pressure resulting from a coupled fluid–structure interaction (FSI) analysis. In addition, a finite element approach is utilised to estimate the effects of asymmetry and wall thickness on the wall stress and fluid dynamics of ten idealised AAA models and one non-aneurysmal control. Five degrees of asymmetry with uniform and variable wall thickness are used. Each was modelled under a static pressure-deformation analysis, as well as a transient FSI. The results show that the inclusion of fluid flow yields a maximum AAA wall stress up to 20% higher compared to that obtained with a static wall stress analysis with an assumed peak luminal pressure of 117 mmHg. The variable wall models have a maximum wall stress nearly four times that of a uniform wall thickness, and also increasing with asymmetry in both instances. The inclusion of an axial stretch and external pressure to the computational domain decreases the wall stress by 17%.