A subsequent movement alters lower extremity muscle activity and kinetics in drop jumps vs. drop landings

Drop landings and drop jumps are common training exercises and injury research model tasks. Drop landings have a single landing, whereas drop jumps include a subsequent jump after initial landing. With the expected ground impact, instant and landing surface suggested to modulate landing neuromechanics, muscle activity, and kinetics should be the same in both tasks when landing from the same height onto the same surface. Although previous researchers have noted some differences between these tasks across separate studies, little research has compared these tasks in the same study. Thus, we examined whether a subsequent movement after initial landing alters muscle activity and kinetics between drop landings and jumps. Fifteen women performed 10 drop landings and drop jumps each from 45 cm. Muscle onsets and integrated muscle activation amplitudes 150 milliseconds before (preactivity) and after landing (postactivity) in the medial and lateral quadriceps, hamstrings, and lateral gastrocnemius and peak and time-to-peak vertical ground reaction forces were examined across tasks (p ≤ 0.05). When performing drop jumps, subjects demonstrated later (p = 0.02) gastrocnemius and lesser lateral gastrocnemius (p = 0.002) and medial quadriceps (p = 0.02) preactivity followed by increased postactivity in all muscles (p = 0.006), with higher peak vertical ground reaction forces (p = 0.04) but no differences in times to these peaks (p = 0.60) than drop landings. The later gastrocnemius activation, higher gastrocnemius and quadriceps postlanding amplitudes, and higher ground reaction forces in drop jumps may allow subjects to propel the body vertically after the initial landing vs. simply absorbing impact in drop landings. Our results indicate that in addition to landing surface and height, anticipation of a subsequent task changes landing neuromechanics. Generalizations of results from landing-only studies should not be made with landing followed-by-subsequent-activity studies. Landing exercises should be incorporated based on sport-specific demands.     

Enhanced Detection of Surface-Associated Bacteria in Indoor Environments by Quantitative PCR

Methods for detecting microorganisms on surfaces are needed to locate biocontamination sources and to relate surface and airborne concentrations. Research was conducted in an experimental room to evaluate surface sampling methods and quantitative PCR (QPCR) for enhanced detection of a target biocontaminant present on flooring materials. QPCR and culture analyses were used to quantitate Bacillus subtilis (Bacillus globigii) endospores on vinyl tile, commercial carpet, and new and soiled residential carpet with samples obtained by four surface sampling methods: a swab kit, a sponge swipe, a cotton swab, and a bulk method. The initial data showed that greater overall sensitivity was obtained with the QPCR than with culture analysis; however, the QPCR results for bulk samples from residential carpet were negative. The swab kit and the sponge swipe methods were then tested with two levels of background biological contamination consisting of Penicillium chrysogenum spores. The B. subtilis values obtained by the QPCR method were greater than those obtained by culture analysis. The differences between the QPCR and culture data were significant for the samples obtained with the swab kit for all flooring materials except soiled residential carpet and with the sponge swipe for commercial carpet. The QPCR data showed that there were no significant differences between the swab kit and sponge swipe sampling methods for any of the flooring materials. Inhibition of QPCR due solely to biological contamination of flooring materials was not evident. However, some degree of inhibition was observed with the soiled residential carpet, which may have been caused by the presence of abiotic contaminants, alone or in combination with biological contaminants. The results of this research demonstrate the ability of QPCR to enhance detection and enumeration of biocontaminants on surface materials and provide information concerning the comparability of currently available surface sampling methods.     

Enhanced detection of surface-associated bacteria in indoor environments by quantitative PCR

Methods for detecting microorganisms on surfaces are needed to locate biocontamination sources and to relate surface and airborne concentrations. Research was conducted in an experimental room to evaluate surface sampling methods and quantitative PCR (QPCR) for enhanced detection of a target biocontaminant present on flooring materials. QPCR and culture analyses were used to quantitate Bacillus subtilis (Bacillus globigii) endospores on vinyl tile, commercial carpet, and new and soiled residential carpet with samples obtained by four surface sampling methods: a swab kit, a sponge swipe, a cotton swab, and a bulk method. The initial data showed that greater overall sensitivity was obtained with the QPCR than with culture analysis; however, the QPCR results for bulk samples from residential carpet were negative. The swab kit and the sponge swipe methods were then tested with two levels of background biological contamination consisting of Penicillium chrysogenum spores. The B. subtilis values obtained by the QPCR method were greater than those obtained by culture analysis. The differences between the QPCR and culture data were significant for the samples obtained with the swab kit for all flooring materials except soiled residential carpet and with the sponge swipe for commercial carpet. The QPCR data showed that there were no significant differences between the swab kit and sponge swipe sampling methods for any of the flooring materials. Inhibition of QPCR due solely to biological contamination of flooring materials was not evident. However, some degree of inhibition was observed with the soiled residential carpet, which may have been caused by the presence of abiotic contaminants, alone or in combination with biological contaminants. The results of this research demonstrate the ability of QPCR to enhance detection and enumeration of biocontaminants on surface materials and provide information concerning the comparability of currently available surface sampling methods.     

A novel first aid stretcher for immobilization and transportation of spine injured patients

Effective immobilization and transportation are vital to the life-saving acute medical care needed when treating critically injured people. However, the most common types of stretchers used today are wrought with problems that can lead to further medical complications, difficulty in employment and rescue, and ineffective transitions to hospital treatment. Here we report a novel first aid stretcher called the "emergency carpet", which solves these problems with a unique design for spine injured patients. Polyurethane composite material, obtained by a novel process of manually mixing isocyanate and additives, can be poured into a specially designed fabric bag and allowed to harden to form a rigid human-shaped stretcher. The effectiveness of the emergency carpet was examined in the pre-hospital management of victims with spinal fractures. Additionally, it was tested on flat ground and complex terrain as well as in the sea and air. We demonstrated that the emergency carpet can be assembled and solidified on the scene in 5 minutes, providing effective immobilization to the entire injured body. With the protection of the emergency carpet, none of the 20 patients, who were finally confirmed to have spinal column fracture or dislocation, had any neurological deterioration during transportation. Furthermore, the carpet can be handled and transported by multiple means under differing conditions, without compromising immobilization. Finally, the emergency carpet allows the critically injured patient to receive multiple examinations such as X-ray, CT, and MRI without being removed from the carpet. Our results demonstrate that the emergency carpet has ideal capabilities for immobilization, extrication, and transportation of the spine injured patients. Compared with other stretchers, it allows for better mobility, effective immobilization, remarkable conformity to the body, and various means for transportation. The emergency carpet is promising for its intrinsic advantages in the pre-hospital management of accident victims.     

Interaction between epithelial basement membrane and migrating mesoblast cells in the avian blastoderm

We investigated the remodeling of glucosamine-containing basement-membrane components in chimaeric avian embryos during gastrulation. Epiblast grafts metabolically labelled with tritiated glucosamine were excised from gastrulating quail embryos and implanted orthotopically into chicken embryos at the same developmental stage. The chimaerae were allowed to develop in culture for 5-7 h before autoradiographic processing. The resulting autoradiographs not only showed the presence of silver grains in the grafted quail tissue and at the level of its basement membrane, but also revealed labelling in the basement-membrane region of the chicken tissue lateral to the graft, i.e. between the mesoblast and epiblast. This last labelling extended as far as at the edge of the area pellucida, i.e. in a region of chicken tissue situated more laterally than the initial position of the graft. No labelling was observed medial, anterior, or posterior to the graft. This observation argues against the interpretation that our results were due to diffusion of labelled compounds within the basement membrane. We also provide evidence to exclude the possibility that quail epiblast cells migrated on their own underlying basement membrane, leaving behind a carpet of labelled material. Taking into account, firstly, the morphogenetic movements that occur during gastrulation, i.e. the movement of epiblast cells towards the primitive streak where they ingress, and the migration of mesoblast cells along the basement membrane towards the periphery of the area pellucida, and secondly, the medial movement of the basement membrane, it is suggested that mesoblast cells picked up labelled compounds in the basement membrane of the graft and left these behind during their lateral migration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pupation site selection of cat fleas (Siphonaptera: Pulicidae) in various carpet types and its influence on insecticide efficacy

Pupation sites of cat flea, Ctenocephalides felis (Bouché), larvae were determined in three styles of nylon and one style of wool carpet. Nylon saxony carpet had 59.3% of pupae at the top of the pile and 40% at the base of the pile. In nylon contract carpet, 55.2% of pupae were found at the top, 42.6% in the middle, and only 2.2% at the base of the pile. Nylon loop carpet contained 59.2% of pupae at the base, 25.5% in the middle, and 15.3% in the top of the pile. Wool loop carpet had 92.4% at the base and 3.8% both in the middle and top of the pile. Bioassays comparing the control of pupae manually placed at the base of carpets to that in carpets with natural pupation showed that control of pupae in the latter was 39-68% higher. Pupal control after natural pupation was greatest in nylon saxony and nylon contract carpets and lowest in nylon loop and wool loop carpets. Additional studies demonstrated that vacuuming provided the same level of pupal control on nylon saxony carpet as a spray application of permethrin to the carpet surface. Therefore, pupae that survived chemical and mechanical control treatments in nylon saxony carpet probably pupated away from the surface of the pile. Application of permethrin to the base of nylon saxony carpet did not significantly increase control. Future bioassays with cat flea pupae in carpet should be performed after natural pupation and consider carpet make and style.     

Early axonal contacts during development of an identified dendrite in the brain of the zebrafish

We have identified the initial synaptic contacts made onto the Mauthner (M) cell, an identified neuron that arises during early development of the zebrafish hindbrain. The contacts are made by a small bundle of pioneering trigeminal sensory axons onto the M cell soma before it forms dendrites. The sensory bundle is then partially enveloped by the M cell. The lateral dendrite appears at about the site of the contact, and eventually the trigeminal inputs are shifted to its trunk. As the dendrite elongates, other sensory contacts are made on its distal regions, sequentially from the acoustico-vestibular nerve and the lateral line nerves. To learn whether the earliest inputs induce the initial outgrowth of the M cell dendrite, we ablated the trigeminal neurons by laser irradiation before they contacted the M cell. Morphogenesis of the M cell, including its dendrite, appeared normal.     

Lipopolysaccharide O antigen chains mask IcsA (VirG) in Shigella flexneri

Shigella flexneri 2a strain 2457T lipopolysaccharide (LPS) has O antigen (Oag) chains with two modal lengths (S-type and VL-type), and has IcsA apparently located at one pole on its cell surface. Treatment of Y serotype derivatives of 2457T and RMA696 (2457T wzz(SF)) with Sf6 tailspike protein (TSP) resulted in hydrolysis of Oag chains, and an increase in detection of IcsA by indirect immunofluorescence staining on both the lateral and polar regions of the cell surface. Newly synthesised IcsA expressed from a pBAD promoter in a S. flexneri Y strain was also detected on both the lateral and polar regions of the cell when incubated with TSP prior to immunofluorescence staining. We conclude that IcsA is actually located on both lateral and polar regions of the S. flexneri cell surface, and that LPS Oag chains mask the presence of IcsA by hindering its detection with antibodies. These results have implications for the mechanism of IcsA export. They suggest that while IcsA export is predominantly targeted to the old cell pole, it can also occur on the lateral regions of the cell surface.     

A model of drop size distribution for a system with evaporation

Abstract. The size and shape of drops on leaf surfaces strongly affect their persistence. The relationship between volume and exposed surface area of drops on wheat leaves and the log-normal drop size distribution in a wheat canopy after rain are used to derive equations to describe how the total volume and drop number change with evaporation. Firstly, the behaviour of a single drop as it evaporates is considered and then equations describing the change in a population of drops with an initial log-normal distribution are derived. The time taken for all the drops to reach complete dryness is about thirty times that for the same volume of water spread uniformly over the surface with the same potential evaporation rate.     

Modeling Superhydrophobic Contact Angles and Wetting Transition

It is well known that surface roughness has a very important effect on superhydrophobicity.The Wenzel and Cassie-Baxtermodels,which correspond to the homogeneous and heterogeneous wetting respectively,are currently primary instructions fordesigning superhydrophobic surfaces.However,the particular drop shape that a drop exhibits might depend on how it is formed.A water drop can occupy multiple equilibrium states,which relate to different local minimal energy.In some cases,both equilibriumstates can even co-exist on a same substrate.Thus the apparent contact angles may vary and have different values.Wediscuss how the Wenzel and Cassie-Baxter equations determine the homogeneous and heterogeneous wetting theoretically.Contact angle analysis on hierarchical surface structure and contact angle hysteresis has been put specific attention.In particular,we study the energy barrier of transition from Cassie-Baxter state to Wenzel state,based on existing achievement by previousresearchers,to determine the possibility of the transition and how it can be interpreted.It has been demonstrated that surfaceroughness and geometry will influence the energy required for a drop to get into equilibrium,no matter it is homogeneous orheterogeneous wetting.     

Comparison of collagen and glycosaminoglycan synthesis in attaching control and diabetic human skin fibroblasts

Summary Cultured fibroblasts derived from normal subjects and juvenile diabetics attach in the absence of serum to plastic culture dishes and secrete macromolecules, including collagenous components, hyaluronic acid, and proteoglycans into the medium and onto the plastic surface where they form a microexudate carpet. Most diabetic fibroblasts examined did not spread as well as normal cells during a 4-hr interval after the initial attachment. There were no significant differences between normal and diabetic cells with respect to proline and lysine incorporation and lysine hydroxylation. The percentage glycosylation of hydroxylysine was marginally higher in the media proteins of diabetic cells, but glycosylation in both normal and diabetic cells was elevated over that typically observed in human skin collagen. Collagenous components were estimated to constitute approximately 15–20% of the microexudate carpet fraction in both normal and diabetic cell strains. Diabetic fibroblasts exhibited a marginally lower ratio of heparan sulfate to chondroitin sulfate in the cell surface to matrix microexudate carpet fraction (trypsinate) than did normal fibroblasts. The hyaluronate and chondroitin sulfate contents of this fraction of diabetic cells were not significantly different from those of normal cells. This work was supported by Grants AM 11821 and AM 19606 from the National Institutes of Health, United States Public Health Service, by a grant from the American Diabetes Association (Leon W. Cunningham, Principal Investigator) and by the Vanderbilt Diabetes Endocrinology Center grant, AM 17026. R. E. Branson was the recipient of a research fellowship of the Juvenile Diabetes Foundation and of a National Institutes of Health Postdoctoral Fellowship AM 05636.     

Enamel extension rate patterns in modern human teeth: Two approaches designed to establish an integrated comparative context for fossil primates

Enamel extension rates (EERs), the rates at which ameloblasts differentiate, determine how fast tooth crowns grow in height. Studies of fossil primate (including hominin) enamel microstructure usually focus on species differences in enamel formation time, but they have also begun to address species-level variation in enamel extension rates. To improve our ability to compare EERs among primate species, a better understanding how EERs vary within species is necessary. Using a large and diverse modern human histological sample, we find that initial EERs and patterns of EER change along the enamel-dentine junction (EDJ) vary in relation to EDJ length. We also find that enamel formation time varies in relation to EDJ length, but that it does so independently of initial EERs. These results suggest that EDJ length variation within a species sample can affect interspecific comparisons not only of EERs but also of enamel formation times. Additionally, these results lend within-species support to the hypothesis, based on comparisons among hominin species, that EERs and crown formation times can vary independently (Dean, 2009). In a second approach, we analyzed EER changes specifically in the lateral enamel of two modern human population samples as these changes relate to the distribution of perikymata. As surface manifestations of internal enamel growth increments, perikymata provide a valuable source of information about enamel growth in fossils. We find that EER declines in the lateral enamel are associated with an increase in perikymata density from first to last-formed lateral enamel. Moreover, variation in the extent of EER decline among individuals is associated with variation in the distribution of perikymata along their enamel surfaces. These latter findings suggest that the distribution of perikymata on the enamel surface provides information about rates of EER decline in lateral enamel, at least in modern humans.     

Contribution of lateral gene transfer to the gene repertoire of a gut-adapted methanogen

Methanobrevibacter smithii is the most abundant archaeon in the human colon. As most of its neighbors are bacterial species, it is expected that lateral gene acquisition from bacteria might have contributed to the evolution and adaptation of this archaeon. We performed a tree-based genome-wide survey of putative lateral gene transfer products in M. smithii, using a phylogenetic pipeline. Over 15% of the coding genes of M. smithii are inferred to be bacterial in origin, based on this analysis. Laterally acquired genes have had the largest contribution to surface functions, and encode glycosyl-transferases and adhesin-like proteins. In addition, several important ABC transporters, especially metal transporters are of bacterial origin. Thus, bacterial genes contributed to the host-adaptation by allowing a larger variety of surface structures and increasing the efficiency of metal ion uptake in the competitive gut niche.     

Fluorescence Recovery after Merging a Droplet to Measure the Two-dimensional Diffusion of a Phospholipid Monolayer

We introduce a new method to measure the lateral diffusivity of a surfactant monolayer at the fluid-fluid interface, called fluorescence recovery after merging (FRAM). FRAM adopts the same principles as the fluorescence recovery after photobleaching (FRAP) technique, especially for measuring fluorescence recovery after bleaching a specific area, but FRAM uses a drop coalescence instead of photobleaching dye molecules to induce a chemical potential gradient of dye molecules. Our technique has several advantages over FRAP: it only requires a fluorescence microscope rather than a confocal microscope equipped with high power lasers; it is essentially free from the selection of fluorescence dyes; and it has far more freedom to define the measured diffusion area. Furthermore, FRAM potentially provides a route for studying the mixing or inter-diffusion of two different surfactants, when the monolayers at a surface of droplet and at a flat air/water interface are prepared with different species, independently.     

Minireview: Differential Targeting and Retention of G Protein-Coupled Receptors in Polarized Epithelial Cells

Abstract

Localization of receptors in discrete cellular microdomains undoubtedly contributes to their interaction with particular effectors and receptor targets. For G protein-coupled receptors, virtually nothing is known about the mechanisms and structural features responsible for their targeting to and retention in varying surface domains. We have shown that the G_j/G_o-coupled α_2A-adrenergic receptor (α_2AAR) is directly targeted to the lateral subdomain of MDCK II cells. Mutational analysis has revealed that regions in or near the bilayer are likely critical for α_2AAR targeting, whereas endofacial domains contribute to α_2AAR retention on the lateral surface. Although the α_2BAR also is enriched on the lateral subdomain at steady-state, its polarization occurs after initial random delivery to both apical and basolateral surfaces followed by a selective accumulation on the lateral subdomain. The α_2CAR also is expressed on the lateral subdomain and achieves its localization via direct delivery to the basolateral surface; however, the α_2CAR also exists in an as yet not fully characterized intracellular compartment. Interestingly, another G_j/G_o-coupled receptor, the A₁ adenosine receptor, is enriched on the apical surface of MDCK II calls and achieves this localization by direct apical delivery. These findings indicate that receptor delivery to polarized surfaces is not determined by receptor coupling to a specific subpopulation of G proteins.     

The cells shed by the root cap of Zea: their origin and some structural and physiological properties

Abstract Two populations of living detached cap cells are found within the drop of mucilage at the root tip of a 3-d-old corn seedling. Axial cells, which pass through the length of the columella, are shed at the apex of the cap and lateral cells, which have spent less time or no time within the columella, are detached from the cap flanks. The two types of cells differ in shape, size and internal structure. Whereas the axial cells are more or less spherical and have a projected surface area of 1300μm², the lateral cells are elongated and possess a projected surface area of 2000μm². The axial cells are further distinguished by the association with a polyhedric net thought to be remnants of undigested middle lamellar material from the columellar tissue. Both populations of cells arc metabolically active and can be plasmolysed, but no evidence was found that they secrete mucilage after detachment. The lateral cells have been cultured on solid nutrient media and on nutrient-free agar. In both cases, they did not divide; however, they enlarged by one-third in their projected surface area over 15 d.     

Adsorption kinetics and rheological interfacial properties of plant proteins at the oil-water interface

Adsorption and rheological properties of plant proteins were determined by means of the dynamic pendant drop technique. The plant protein properties were compared with the interfacial properties of gelatin, which is well-known for its surface-active properties and is commonly used in food and health products. The results showed that alpha gliadins (wheat proteins) and pea globulins have the highest surface active properties at the oil-water interface, even higher than gelatin at the same concentration (weight/volume). After a short time of adsorption, alpha gliadin interfacial behavior is characterized by a pronounced viscoelasticity, which was confirmed with time whereas pea protein interfacial behavior became elastic after a long initial adsorption period. Finally, the behavior of gelatin is very close to the alpha gliadin behavior for the short initial adsorption period, whereas it looks like the behavior of legume seed proteins for longer times of the adsorption kinetics. This study emphasizes the importance of the choice of the proteins and the emulsification time in the encapsulation process, according to the interfacial behavior.     

Comparison of lower limb kinetics,kinematics and muscle activation during drop jumping under shod and barefoot conditions

This study was to investigate the acute effects of wearing shoes on lower limb kinetics, kinematics and muscle activation during a drop jump. Eighteen healthy men performed a drop jump under barefoot and shod conditions. Vertical ground reaction force (GRF) was measured on a force plate during the contact phase of a drop jump, and GRF valuables were calculated for each condition. The angles of the knee and ankle joints, and the foot strike angle (the angle between the plantar surface of the foot and the ground during ground contact) as well as the electromyography of 7 muscles were measured. The shod condition showed a significant larger first peak GRF, longer time to first peak GRF from the initial ground contact and lower initial loading rate than the barefoot condition. The shod condition showed a significant larger ankle joint angle at initial ground contact, smaller knee joint angle between the second peak GRF and take-off as well as smaller foot strike angle at both initial ground contact and take-off than the barefoot condition. There were significant correlations between relative differences in ankle joint at the initial ground contact and relative differences in the initial loading rate. The muscle activity of all muscles during foot ground contact did not differ between two conditions; however, in the shod condition, muscle activation of 150 ms before foot ground contact was significantly higher in the rectus femoris, whereas it was lower in the biceps femoris and tibialis anterior muscles than the barefoot condition. These results indicate that wearing shoes alternates the GRF variables at initial ground contact, joint kinematics at the ground contact and muscle activation before foot ground contact during a drop jump, suggesting that the effects of wearing shoes on drop jump training differ from being barefoot.     

Recycling Postconsumer Nylon Carpet

Each year 34 billion pounds of nylon carpet are discarded into landfills in the United States. As a case study we examine the technical and economic feasibility of recycling a portion of this source of discarded plastic. The carpet could be (I) shredded for use as daily cover at landfills or as a strengthening component of concrete, (2) sheared or chemically processed for reuse as recycled nylon or as pure nylon feedstock, or (3) made into a new type of plastic. We estimate the costs of a recycling facility to handle 450,000 Ib of discarded nylon carpet each month in Pittsburgh, Pennsylvania. We found that with current technology, regulations, and markets, only the recycling of carpet from commercial settings using shearing or chemical processing is economical and only under very narrow circumstances. We learned four lessons from this study, First, collection costs are high and can dominate the economics of recycling. Second, given time and incentives, collection costs can be reduced. Third, trying to recycle products not designed to be recycled leads to many problems. Carpet could be redesigned to make recycling easier by making the carpet out of a single material and using an adhesive that can be removed easily. Fourth, recycling processes should be designed to produce an existing material if at all possible, because new materials present marketing problems.     

Numerical analysis of the deformation of an adherent drop under shear flow

The adhesion of leukocytes to substrates is an important biomedical problem and has drawn extensive research. In this study, employing both single and compound drop models, we investigate how hydrodynamics interacts with an adherent liquid drop in a shear flow. These liquid drop models have recently been used to describe the rheological behavior of leukocytes. Numerical simulation confirms that the drop becomes more elongated when either capillary number or initial contact angle increases. Our results show that there exists a thin region between the drop and the wall as the drop undergoes large stretching, which allows high pressure to build up and provides a lift force. In the literature, existing models regard the leukocyte as a rigid body to calculate the force and torque acting on the drop in order to characterize the binding between cell receptors and endothelial ligands. The present study indicates that such a rigid body model is inadequate and the force magnitude obtained from it is less than half of that obtained using the deformable drop models. Furthermore, because of its much higher viscosity, the cell nucleus introduces a hydrodynamic time scale orders of magnitude slower than the cytoplasm. Hence the single and compound drops experience different dynamics during stretching, but exhibit very comparable steady-state shapes. The present work offers a framework to facilitate the development of a comprehensive dynamic model for blood cells.