A novel, non-invasive and in vivo approach to determine morphometric data in starfish

Sigl, Robert; Imhof, Hannes K.; Settles, Marcus; Laforsch, Christian

doi:10.1016/j.jembe.2013.08.002

Cited by 14 publications

(7 citation statements)

References 42 publications

(44 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A further element of bias, i.e. the process of manual segmentation was compensated for by conducting segmentation independently by two individuals [70].…”

Section: Photogrammetry-based Reconstructions Of the Cephalic Lateralmentioning

confidence: 99%

Form and function of the teleost lateral line revealed using three-dimensional imaging and computational fluid dynamics

Herzog

Klein

Ziegler

2017

J. R. Soc. Interface.

View full text Add to dashboard Cite

Fishes sense weak water motion using the lateral line. Among the thousands of described fish species, this organ may differ in size, shape and distribution of individual mechanoreceptors or lateral line canals. The reasons for this diversity remain unclear, but are very likely related to habitat preferences. To better understand the performance of the organ in natural hydrodynamic surroundings, various three-dimensional imaging datasets of the cephalic lateral line were gathered using Leuciscus idus as representative freshwater teleost. These data are employed to simulate hydrodynamic phenomena around the head and within lateral line canals. The results show that changes in canal dimensions alter the absolute stimulation amplitudes, but have little effect on the relation between bulk water flow and higher frequency signals. By contrast, depressions in the skin known as epidermal pits reduce bulk flow stimulation and increase the ratio between higher-frequency signals and the background flow stimulus.

show abstract

“…A further element of bias, i.e. the process of manual segmentation was compensated for by conducting segmentation independently by two individuals [70].…”

Section: Photogrammetry-based Reconstructions Of the Cephalic Lateralmentioning

confidence: 99%

Form and function of the teleost lateral line revealed using three-dimensional imaging and computational fluid dynamics

Herzog

Klein

Ziegler

2017

J. R. Soc. Interface.

View full text Add to dashboard Cite

show abstract

“…With regard to specimen preparation for MRI, it is important to note that MRI protocols in principle permit scanning specimens fully immersed in ethanol (Sigl et al 2013). This may be advantageous for various reasons, for example if the higher surface tension of water leads to air bubbles being trapped inside a specimen, which usually results in the presence of strong susceptibility artifacts or when museum specimens have to be analyzed as non-invasively as feasible.…”

Section: Preclinical Mrimentioning

confidence: 99%

Digital Three-Dimensional Imaging Techniques Provide New Analytical Pathways for Malacological Research

Ziegler¹,

Bock

Ketten

et al. 2018

American Malacological Bulletin

View full text Add to dashboard Cite

show abstract

“…The methodological approach employed here allows conducting high-throughput analyses of hundreds or even thousands of zoological specimens [ 7 ]. Potential uses of the present dataset include morphometric or volumetric analyses of internal organs [ 11 ] and interactive exploration of sea urchin anatomy using digital 2D and 3D visualization tools [ 12 ]. For example, MRI scans with an isotropic voxel resolution are particularly suitable for 3D modeling [ 13 ].…”

Section: Data Descriptionmentioning

confidence: 99%

A dataset comprising 141 magnetic resonance imaging scans of 98 extant sea urchin species

Ziegler¹,

Faber

Mueller

et al. 2014

GigaSci

View full text Add to dashboard Cite

BackgroundApart from its application in human diagnostics, magnetic resonance imaging (MRI) can also be used to study the internal anatomy of zoological specimens. As a non-invasive imaging technique, MRI has several advantages, such as rapid data acquisition, output of true three-dimensional imagery, and provision of digital data right from the onset of a study. Of particular importance for comparative zoological studies is the capacity of MRI to conduct high-throughput analyses of multiple specimens. In this study, MRI was applied to systematically document the internal anatomy of 98 representative species of sea urchins (Echinodermata: Echinoidea).FindingsThe dataset includes raw and derived image data from 141 MRI scans. Most of the whole sea urchin specimens analyzed were obtained from museum collections. The attained scan resolutions permit differentiation of various internal organs, including the digestive tract, reproductive system, coelomic compartments, and lantern musculature. All data deposited in the GigaDB repository can be accessed using open source software. Potential uses of the dataset include interactive exploration of sea urchin anatomy, morphometric and volumetric analyses of internal organs observed in their natural context, as well as correlation of hard and soft tissue structures.ConclusionsThe dataset covers a broad taxonomical and morphological spectrum of the Echinoidea, focusing on ‘regular’ sea urchin taxa. The deposited files significantly expand the amount of morphological data on echinoids that are electronically available. The approach chosen here can be extended to various other vertebrate and invertebrate taxa. We argue that publicly available digital anatomical and morphological data gathered during experiments involving non-invasive imaging techniques constitute one of the prerequisites for future large-scale genotype—phenotype correlations.

show abstract

A novel, non-invasive and in vivo approach to determine morphometric data in starfish

Cited by 14 publications

References 42 publications

Form and function of the teleost lateral line revealed using three-dimensional imaging and computational fluid dynamics

Form and function of the teleost lateral line revealed using three-dimensional imaging and computational fluid dynamics

Digital Three-Dimensional Imaging Techniques Provide New Analytical Pathways for Malacological Research

A dataset comprising 141 magnetic resonance imaging scans of 98 extant sea urchin species

Contact Info

Product

Resources

About