Your search keyword '"Konglerd P"' showing total 4 results

1. From Molecules to Morphologies, a Multiscale Modeling Approach to Unravel the Complex System of Coral Calcification

Author

Deutekom, E.S., Konglerd, P., Ramos-Silva, P., Kaandorp, J.A., Goffredo, S., Dubinsky, Z., and Computational Science Lab (IVI, FNWI)

Subjects

0106 biological sciences, 0301 basic medicine, Computational model, Process (engineering), Complex system, Nanotechnology, Mineral deposition, Computational biology, Biology, medicine.disease, 010603 evolutionary biology, 01 natural sciences, Multiscale modeling, Organic molecules, 03 medical and health sciences, Multiple data, 030104 developmental biology, medicine, Calcification

Abstract

Calcification can be viewed as an emergent behavior resulting from a complex system in which several sub-processes on very different temporal and spatial scales (ranging from nanometer and nanoseconds to meters and years) are connected in a multiscale system. Sub-processes like gene regulation, organic molecules influencing the mineral deposition process, cellular and physiological processes and environment are all linked. Although different calcification mechanisms and pathways have been proposed, there is still no conclusive and comprehensive model of the process. In recent years, many efforts have been made to individually elucidate the regulatory subprocesses. It is important to integrate this knowledge into a multiscale model and analysis that will increase fundamental understanding, guide coral preservation efforts and find potentially important applications in material sciences. Computational models can effectively aid in this integration, by providing structure and serving as a tool for inferring and interpreting interactions and hypotheses. The multiple data that have been collected and the computational models that have been and could be developed will be reviewed, starting with the coral transcriptome, followed by the skeletal proteome, tissue physiology, and skeletal micro- and macromorphology.

Published

2016

2. Quantitative morphological analysis of 2D images of complex-shaped branching biological growth forms: the example of branching thalli of liverworts

Author

Konglerd, P. (Pirom), Reeb, C. (Catherine), Jansson, F.R. (Fredrik), Kaandorp, J.A. (Jaap), Konglerd, P. (Pirom), Reeb, C. (Catherine), Jansson, F.R. (Fredrik), and Kaandorp, J.A. (Jaap)

Abstract

Background - Many organisms such as plants can be characterized as complex-shaped branching forms. The morphological quantification of the forms is a support for a number of areas such as the effects of environmental factors and species discrimination. To date, there is no software package suitable for our dataset representing the forms. We therefore formulate methods for extracting morphological measurements from images of the forms.Results - As a case study we analyze two-dimensional images of samples from four groups belonging to three species of thalloid liverworts, genus Riccardia. The images are pre-processed and converted into binary images, then skeletonized to obtain a skeleton image, in which features such as junctions and terminals are detected. Morphological measurements known to characterize and discriminate the species in the samples such as junction thickness, branch thickness, terminal thickness, branch length, branch angle, and terminal spacing are then quantified. The measurements are used to distinguish among the four groups of Riccardia and also between the two groups of Riccardia amazonica collected in different locations, Africa and South America. Canonical discriminant analysis results show that those measurements are able to discriminate among the four groups. Additionally, it is able to discriminate R. amazonica collected in Africa from those collected in South America.Conclusions - This paper presents general automated methods implemented in our software for quantifying two-dimensional images of complex branching forms. The methods are used to compute a series of morphological measurements. We found significant results to distinguish Riccardia species by using the measurements. The methods are also applicable for analyzing other branching organisms. Our software is freely available under the GNU GPL.

Published

2017

3. Gains and losses of coral skeletal porosity changes with ocean acidification acclimation

Author

Fantazzini, Paola, Mengoli, Stefano, Pasquini, Luca, Bortolotti, Villiam, Brizi, Leonardo, Mariani, Manuel, Di Giosia, Matteo, Fermani, Simona, Capaccioni, Bruno, Caroselli, Erik, Prada, Fiorella, Zaccanti, Francesco, Levy, Oren, Dubinsky, Zvy, Kaandorp, Jaap A., Konglerd, Pirom, Hammel, Jörg U., Dauphin, Yannicke, Cuif, Jean-Pierre, Fabricius, Katharina E., Wagermaier, Wolfgang, Fratzl, Peter, Falini, Giuseppe, Goffredo, Stefano, and Weaver, James

Abstract

Ocean acidification is predicted to impact ecosystems reliant on calcifying organisms, potentially reducing the socioeconomic benefits these habitats provide. Here we investigate the acclimation potential of stony corals living along a pH gradient caused by a Mediterranean CO2 vent that serves as a natural long-term experimental setting. We show that in response to reduced skeletal mineralization at lower pH, corals increase their skeletal macroporosity (features >10 μm) in order to maintain constant linear extension rate, an important criterion for reproductive output. At the nanoscale, the coral skeleton's structural features are not altered. However, higher skeletal porosity, and reduced bulk density and stiffness may contribute to reduce population density and increase damage susceptibility under low pH conditions. Based on these observations, the almost universally employed measure of coral biomineralization, the rate of linear extension, might not be a reliable metric for assessing coral health and resilience in a warming and acidifying ocean., Version of Record

Published

2015

4. Quantitative morphological analysis of 2D images of complex-shaped branching biological growth forms: the example of branching thalli of liverworts.

Author

Konglerd P, Reeb C, Jansson F, and Kaandorp JA

Subjects

Africa, South America, Hepatophyta anatomy & histology, Image Processing, Computer-Assisted methods, Plant Physiological Phenomena

Abstract

Background: Many organisms such as plants can be characterized as complex-shaped branching forms. The morphological quantification of the forms is a support for a number of areas such as the effects of environmental factors and species discrimination. To date, there is no software package suitable for our dataset representing the forms. We therefore formulate methods for extracting morphological measurements from images of the forms., Results: As a case study we analyze two-dimensional images of samples from four groups belonging to three species of thalloid liverworts, genus Riccardia. The images are pre-processed and converted into binary images, then skeletonized to obtain a skeleton image, in which features such as junctions and terminals are detected. Morphological measurements known to characterize and discriminate the species in the samples such as junction thickness, branch thickness, terminal thickness, branch length, branch angle, and terminal spacing are then quantified. The measurements are used to distinguish among the four groups of Riccardia and also between the two groups of Riccardia amazonica collected in different locations, Africa and South America. Canonical discriminant analysis results show that those measurements are able to discriminate among the four groups. Additionally, it is able to discriminate R. amazonica collected in Africa from those collected in South America., Conclusions: This paper presents general automated methods implemented in our software for quantifying two-dimensional images of complex branching forms. The methods are used to compute a series of morphological measurements. We found significant results to distinguish Riccardia species by using the measurements. The methods are also applicable for analyzing other branching organisms. Our software is freely available under the GNU GPL.

Published

2017