Your search keyword '"Praet T"' showing total 10 results

1. Validation of an ultra-high-performance liquid chromatography-mass spectrometry method for the quantification of cysteinylated aldehydes and application to malt and beer samples

Author

Bustillo Trueba, P., Jaskula-Goiris, B., De Clippeleer, J., Goiris, K., Praet, T., Sharma, U.K., Van der Eycken, E., Sanders, M.G., Vincken, J.-P., De Brabanter, J., De Rouck, G., Aerts, G., and De Cooman, L.

Published

2019

2. Looking Inside Marine Organisms with MRI and X-ray Tomography

Author

Reynaud, EG, Zanette, I, Daghfous, G, Weitkamp, T, Gillet, B, Adriaens, D, Langer, M, Cloetens, P, Helfen, L, Bravin, A, Peyrin, F, Baumbach, T, Dischler, J, Praet, T, Poirer-Quinot, M, Boistel, R, Zanette I, Daghfous G, Weitkamp T, Gillet B, Adriaens D, Langer M, Cloetens P, Helfen L, Bravin A, Peyrin F, Baumbach T, Dischler J-M, Praet T, Poirer-Quinot M, Boistel R, Reynaud, EG, Zanette, I, Daghfous, G, Weitkamp, T, Gillet, B, Adriaens, D, Langer, M, Cloetens, P, Helfen, L, Bravin, A, Peyrin, F, Baumbach, T, Dischler, J, Praet, T, Poirer-Quinot, M, Boistel, R, Zanette I, Daghfous G, Weitkamp T, Gillet B, Adriaens D, Langer M, Cloetens P, Helfen L, Bravin A, Peyrin F, Baumbach T, Dischler J-M, Praet T, Poirer-Quinot M, and Boistel R

Abstract

In this chapter we describe computer-based tomographic methods using magnetic resonance imaging (MRI) and X-ray absorption as well as Xray phase-contrast imaging techniques. The latter are based on refraction and near-field diffraction of X-rays and are gaining increased attention due to the increase in sensitivity they offer over conventional, attenuationbased X-ray techniques. The increased sensitivity is of particular interest in marine biology imaging, especially for soft tissue visualization and analysis. The basic principles of the imaging techniques are described, starting with an analysis of the image formation process, followed by a review of several tomography methods, such as MRI or X-ray imaging, and practical guidelines for parameter selection. Finally, two relevant examples of imaging are presented: imaging in marine biology (segmentation and visualization) and small animal (sea horse) imaging. These examples illustrate imaging under different conditions and using different reconstruction options.

Published

2014

3. Looking Inside Marine Organisms with MRI and X-ray Tomography

Author

Zanette I, Daghfous G, Weitkamp T, Gillet B, Adriaens D, Langer M, Cloetens P, Helfen L, Bravin A, Peyrin F, Baumbach T, Dischler J-M, Praet T, Poirer-Quinot M, Boistel R, Reynaud, EG, Zanette, I, Daghfous, G, Weitkamp, T, Gillet, B, Adriaens, D, Langer, M, Cloetens, P, Helfen, L, Bravin, A, Peyrin, F, Baumbach, T, Dischler, J, Praet, T, Poirer-Quinot, M, and Boistel, R

Subjects

Diffusion tensor imaging, Phase contrast, X-ray imaging, Absorption contrast, MEMRI, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), Phase tomography, Magnetic resonance imaging (MRI), Laminography, Grating interferometry, Functional MRI, Phase retrieval

Abstract

In this chapter we describe computer-based tomographic methods using magnetic resonance imaging (MRI) and X-ray absorption as well as Xray phase-contrast imaging techniques. The latter are based on refraction and near-field diffraction of X-rays and are gaining increased attention due to the increase in sensitivity they offer over conventional, attenuationbased X-ray techniques. The increased sensitivity is of particular interest in marine biology imaging, especially for soft tissue visualization and analysis. The basic principles of the imaging techniques are described, starting with an analysis of the image formation process, followed by a review of several tomography methods, such as MRI or X-ray imaging, and practical guidelines for parameter selection. Finally, two relevant examples of imaging are presented: imaging in marine biology (segmentation and visualization) and small animal (sea horse) imaging. These examples illustrate imaging under different conditions and using different reconstruction options.

Published

2014

4. Understanding the mechanics of tail grasping in seahorses using a parametrized computer model

Author

Praet, T., Adriaens, D., Neutens, C., Maia, A., De Beule, E., and Verhegghe, B.

Abstract

Seahorses are intriguing fishes for several reasons, one being their prehensile tail. Syngnathid fishes, to which seahorses, pipefish, seadragons and pipehorses belong, are characterised by a body armour of bony plates. They form a serially articulated system that encloses the vertebral column and its musculature. In the ancestral condition, as in pipefish, the tail is straight with limited flexibility, and mainly used for steering (pectorals and dorsal used for swimming). During evolution, the tail became modified into a grasping apparatus multiple times independently within the syngnathid family. Less known than the seahorse prehensile capabilities, pipehorses also show different morphologies related to grasping performance. To better understand the structural basis of tail grasping mechanics, a parameterized model of the seahorse tail was developed. By combining multibody dynamics analysis with finite element analysis, we analysed the implication of partial contribution of epaxial and hypaxial muscles, versus ventral median muscle, as well as that of the bony plate geometry. Natural bending postures, as observed in living seahorses, can be obtained up to some degree. The analyses showed particular relations between morphology and bending kinematics. Using this seahorse model, functional implications of evolutionary changes in in syngnathid tails can be further analysed, as well as to develop biomimetic designs of serially articulated systems that meet particular application demands.

Published

2014

5. Computer modelling and biomimetics for understanding the evolution of tail grasping in seahorses

Author

Adriaens, Dominique, primary, Praet, T., additional, Neutens, C, additional, Porter, M., additional, De Beule, M., additional, McKittrick, J., additional, and Verhegghe, B, additional

Published

2015

6. Local strain in a 5-harness satin weave composite under static tension: Part II – Meso-FE analysis

Author

Daggumati, S., primary, Van Paepegem, W., additional, Degrieck, J., additional, Praet, T., additional, Verhegghe, B., additional, Xu, J., additional, Lomov, S.V., additional, and Verpoest, I., additional

Published

2011

7. Influence of the internal yarn nesting (Shifting) on the local structural response of a satin weave composite-an experimental and numerical overview

Author

Daggumati, S., Voet, E., Wim VAN PAEPEGEM, Degrieck, J., Praet, T., Verhegghe, B., Xu, J., Lomov, S. V., Verpoest, I., Binetruy, C, and Boussu, F

Subjects

Technology and Engineering, TEXTILE COMPOSITES

Abstract

The current paper emphasizes on the effect of internal yarn nesting (shifting) on the local structural response, such as, local stress - strain and the local damage of a satin weave composite. Detailed study of the variation of the local stress – strain behavior in the plies of a satin weave composite leads to the following conclusions: 1) local longitudinal strain in the plies of a satin weave composite is not influenced by the internal yarn nesting of the adjacent plies (position of the ply in the laminate); 2) local transverse stress as well as the weft yarn transverse damage is sensitive to the position of the ply in the laminate.

8. Changes in the hop-derived volatile profile upon lab scale boiling.

Author

Praet T, Van Opstaele F, Steenackers B, De Brabanter J, De Vos D, Aerts G, and De Cooman L

Abstract

Hop terpenes might be oxidized during kettle boiling into more water soluble compounds that could contribute to 'hoppy' aroma of kettle hopped lager beers. Our current research proves that the boiling process induces significant changes in the hop oil volatile profile. The discrimination between volatile profiles of unboiled and boiled hop essential oil was evaluated via principal component and cluster analysis (PCA and CA). HS-SPME-GC-MS analysis revealed quantitative changes (e.g. increases in the levels of oxygenated α-humulene and β-caryophyllene derivatives) as well as qualitative changes (i.e. detection of compounds, not found in unboiled hop essential oil) in the hop oil volatile profile upon boiling. Many of these compounds were previously found in lager beer and may therefore contribute to beer flavor. Interestingly, the analytical difference between unboiled and boiled hop essential oil proved to be more pronounced as the initial hop essential oil concentration used for boiling was increased. In addition, lager beers spiked with boiled hop oil were described as 'hoppy/spicy' during sensory evaluations. Therefore, the newly formed products and hop oil constituents that are characterized by an increased recovery after boiling, are candidate compounds for 'hoppy' aroma in real brewing practice., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

9. Characterization of novel single-variety oxygenated sesquiterpenoid hop oil fractions via headspace solid-phase microextraction and gas chromatography-mass spectrometry/olfactometry.

Author

Van Opstaele F, Praet T, Aerts G, and De Cooman L

Subjects

Gas Chromatography-Mass Spectrometry methods, Molecular Structure, Olfactometry, Solid Phase Microextraction methods, Humulus chemistry, Plant Oils chemistry, Terpenes chemistry, Terpenes isolation & purification

Abstract

The volatile composition of novel varietal oxygenated sesquiterpenoid hop oil fractions ("spicy essences") was characterized by headspace solid-phase microextraction in combination with gas chromatography-mass spectrometry. Oxygenated sesquiterpenes represent the major chemical compound class, accounting for at least 65% of the total volatile fraction. In addition to oxygenated sesquiterpenes, spicy hop essences consist of several ketones, sesquiterpene and monoterpene hydrocarbons, and a relatively high number of unidentified compounds. On the basis of their relative composition, spicy hop essences can be fully differentiated according to their varietal origin. Multidimensional gas chromatography in combination with time-of-flight mass spectrometry on spicy hop essence cv. Spalter Select further demonstrated the enormous complexity of this particular hop oil fraction. The aromagram obtained via gas chromatography-olfactometry comprised nine odor-active regions described in terms of "citrus", "green", "haylike", "earthy", "woody", and "spicy". 2-Undecanone, 2-tridecanone, γ-cadinene, α-calacorene, calarene, humuladienone, caryolan-1-ol, caryophyllene oxide enantiomers, and humulene epoxide II are tentatively identified in the odor-active zones.

Published

2013

10. Inspiration from nature: dynamic modelling of the musculoskeletal structure of the seahorse tail.

Author

Praet T, Adriaens D, Van Cauter S, Masschaele B, De Beule M, and Verhegghe B

Subjects

Animals, Biomechanical Phenomena, Biomedical Engineering, Computer Simulation, Imaging, Three-Dimensional, Joints anatomy & histology, Joints physiology, Models, Anatomic, Muscle Contraction physiology, Musculoskeletal Physiological Phenomena, Musculoskeletal System anatomy & histology, Tail anatomy & histology, Tail diagnostic imaging, Tail physiology, X-Ray Microtomography, Models, Biological, Smegmamorpha anatomy & histology, Smegmamorpha physiology

Abstract

Technological advances are often inspired by nature, considering that engineering is frequently faced by the same challenges as organisms in nature. One such interesting challenge is creating a structure that is at the same time stiff in a certain direction, yet flexible in another. The seahorse tail combines both radial stiffness and bending flexibility in a particularly elegant way: even though the tail is covered in a protective armour, it still shows sufficient flexibility to fully function as a prehensile organ. We therefore study the complex mechanics and dynamics of the musculoskeletal system of the seahorse tail from an engineering point of view. The seahorse tail derives its combination of flexibility and resilience from a chain of articulating skeletal segments. A versatile dynamic model of those segments was constructed, on the basis of automatic recognition of joint positions and muscle attachments. Both muscle structures that are thought to be responsible for ventral and ventral-lateral tail bending, namely the median ventral muscles and the hypaxial myomere muscles, were included in the model. Simulations on the model consist mainly of dynamic multi-body simulations. The results show that the sequential structure of uniformly shaped bony segments can remain flexible because of gliding joints that connect the corners of the segments. Radial stiffness on the other hand is obtained through the support that the central vertebra provides to the tail plating. Such insights could help in designing biomedical instruments that specifically require both high bending flexibility and radial stiffness (e.g. flexible stents and steerable catheters)., (Copyright © 2012 John Wiley & Sons, Ltd.)

Published

2012