Your search keyword '"Dorst, N"' showing total 7 results

1. Pitfall Flower Development and Organ Identity of Ceropegia sandersonii (Apocynaceae-Asclepiadoideae)

Author

Heiduk, A., Pramanik, D., Spaans, M., Gast, L., Dorst, N., Heuven, B.J., Gravendeel, B., Heiduk, A., Pramanik, D., Spaans, M., Gast, L., Dorst, N., Heuven, B.J., and Gravendeel, B.

Abstract

Contains fulltext : 229042.pdf (publisher's version ) (Open Access)

Published

2020

2. De visie van kinderen en jongeren op de aanpak van kindermishandeling: Outcome- en procesevaluatie van de methode ‘Child-Voice groepen’.

Author

Dorst, N., Londen-Barentsen, W.M. van (Thesis Advisor), Baerveldt, C., Dorst, N., Londen-Barentsen, W.M. van (Thesis Advisor), and Baerveldt, C.

Abstract

Up to now, children in the Netherlands have hardly been involved in the addressing of child abuse. The International Convention on the Rights of the Child, however, states that children should be involved in matters that affect them. This research introduces the Child-Voice-group method, a method by which the vision of children and young people in addressing child abuse is investigated. A total of 26 children and adolescents living in residential settings participated in the study, some of whom have experienced child abuse. Using the Child-Voice-group method, children and adolescents give their views on the addressing of child abuse through creative methods. This results in tangible products: a comic, a drama film, an animation film, and dioramas. In addition, this study evaluates the Child-Voice-group method through interviews and focus groups with facilitators of the Child-Voice groups. The results of this study provide practical tools for addressing child abuse. They give instructions for signaling, talking about child abuse and the desired form of treatment. The Child-Voice-group method connects the children’s right to participate with their right to be protected, by making it possible for them to express their views in a safe way.

Published

2013

3. Expansion and differentiation of human primary osteoblasts in two- and three-dimensional culture

Author

Metzger, W, primary, Schimmelpfennig, L, additional, Schwab, B, additional, Sossong, D, additional, Dorst, N, additional, Bubel, M, additional, Görg, A, additional, Pütz, N, additional, Wennemuth, G, additional, Pohlemann, T, additional, and Oberringer, M, additional

Published

2012

4. Expansion and differentiation of human primary osteoblasts in two- and three-dimensional culture.

Author

Metzger, W, Schimmelpfennig, L, Schwab, B, Sossong, D, Dorst, N, Bubel, M, Görg, A, Pütz, N, Wennemuth, G, Pohlemann, T, and Oberringer, M

Subjects

TISSUE differentiation, OSTEOBLASTS, BIOMINERALIZATION, OSTEOCALCIN, SPHEROIDAL state

Abstract

Despite the regenerative capability of bone, treatment of large defects often requires bone grafts. The challenge for bone grafting is to establish rapid and sufficient vascularization. Three-dimensional (3D) multicellular spheroids consisting of the relevant cell types can be used as 'mini tissues' to study the complexity of angiogenesis. We investigated two-dimensional (2D) expansion, differentiation and characterization of primary osteoblasts as steps toward the establishment of 3D multicellular spheroids. Supplementation of cell culture medium with vitamin D3 induces the osteocalcin expression of osteoblasts. An increased osteocalcin concentration of 10.8 ± 0.58 ng/ml could be measured after 19 days in supplemented medium. Vitamin D3 has no influence on the expression of alkaline phosphatase or the deposition of calcium. Expression of these additional osteogenic markers requires addition of a cocktail of osteogenic factors that, conversely, have no influence on the expression of osteocalcin. Supplementation of the cell culture medium with both vitamin D3 and a cocktail of osteogenic factors is recommended to produce an osteoblast phenotype that secretes osteocalcin, expresses alkaline phosphatase and deposits calcium. In such a supplemented medium, a mean osteocalcin concentration of 11.63 ± 4.85 ng/ml was secreted by the osteoblasts. Distinguishing osteoblasts and fibroblasts remains a challenge. Neither differentiated nor undifferentiated osteoblasts can be distinguished from fibroblasts by the expression of CD90, ED-A-fibronectin or α-smooth muscle actin; however, these cell types exhibit clear differences in their growth characteristics. Osteoblasts can be arranged as 3D spheroids by coating the bottom of the cell culture device with agarose. The cellular composition of 3D multicellular spheroids can be evaluated quantitatively using vital fluorescence labeling techniques. Spheroids are a promising tool for studying angiogenic and osteogenic phenomena in vivo and in vitro. [ABSTRACT FROM AUTHOR]

Published

2013

5. Pitfall Flower Development and Organ Identity of Ceropegia sandersonii (Apocynaceae-Asclepiadoideae).

Author

Heiduk A, Pramanik D, Spaans M, Gast L, Dorst N, van Heuven BJ, and Gravendeel B

Abstract

Deceptive Ceropegia pitfall flowers are an outstanding example of synorganized morphological complexity. Floral organs functionally synergise to trap fly-pollinators inside the fused corolla. Successful pollination requires precise positioning of flies headfirst into cavities at the gynostegium. These cavities are formed by the corona, a specialized organ of corolline and/or staminal origin. The interplay of floral organs to achieve pollination is well studied but their evolutionary origin is still unclear. We aimed to obtain more insight in the homology of the corona and therefore investigated floral anatomy, ontogeny, vascularization, and differential MADS-box gene expression in Ceropegia sandersonii using X-ray microtomography, Light and Scanning Electronic Microscopy, and RT-PCR. During 10 defined developmental phases, the corona appears in phase 7 at the base of the stamens and was not found to be vascularized. A floral reference transcriptome was generated and 14 MADS-box gene homologs, representing all major MADS-box gene classes, were identified. B- and C-class gene expression was found in mature coronas. Our results indicate staminal origin of the corona, and we propose a first ABCDE-model for floral organ identity in Ceropegia to lay the foundation for a better understanding of the molecular background of pitfall flower evolution in Apocynaceae.

Published

2020

6. Evolution and development of three highly specialized floral structures of bee-pollinated Phalaenopsis species.

Author

Pramanik D, Dorst N, Meesters N, Spaans M, Smets E, Welten M, and Gravendeel B

Abstract

Background: Variation in shape and size of many floral organs is related to pollinators. Evolution of such organs is driven by duplication and modification of MADS-box and MYB transcription factors. We applied a combination of micro-morphological (SEM and micro 3D-CT scanning) and molecular techniques (transcriptome and RT-PCR analysis) to understand the evolution and development of the callus, stelidia and mentum, three highly specialized floral structures of orchids involved in pollination. Early stage and mature tissues were collected from flowers of the bee-pollinated Phalaenopsis equestris and Phalaenopsis pulcherrima , two species that differ in floral morphology: P. equestris has a large callus but short stelidia and no mentum, whereas P. pulcherrima has a small callus, but long stelidia and a pronounced mentum., Results: Our results show the stelidia develop from early primordial stages, whereas the callus and mentum develop later. In combination, the micro 3D-CT scan analysis and gene expression analyses show that the callus is of mixed petaloid-staminodial origin, the stelidia of staminodial origin, and the mentum of mixed sepaloid-petaloid-staminodial origin. SEP clade 1 copies are expressed in the larger callus of P. equestris , whereas AP3 clade 1 and AGL6 clade 1 copies are expressed in the pronounced mentum and long stelidia of P. pulcherrima. AP3 clade 4, PI -, AGL6 clade 2 and PCF clade 1 copies might have a balancing role in callus and gynostemium development. There appears to be a trade-off between DIV clade 2 expression with SEP clade 1 expression in the callus, on the one hand, and with AP3 clade 1 and AGL6 clade 1 expression in the stelidia and mentum on the other., Conclusions: We detected differential growth and expression of MADS box AP3/PI -like, AGL 6-like and SEP -like, and MYB DIV -like gene copies in the callus, stelidia and mentum of two species of Phalaenopsis, of which these floral structures are very differently shaped and sized. Our study provides a first glimpse of the evolutionary developmental mechanisms driving adaptation of Phalaenopsis flowers to different pollinators by providing combined micro-morphological and molecular evidence for a possible sepaloid-petaloid-staminodial origin of the orchid mentum., Competing Interests: Competing interestsThe authors declare that they have no competing interests., (© The Author(s) 2020.)

Published

2020

7. Analysis of cellular composition of co-culture spheroids.

Author

Dorst N, Oberringer M, Grässer U, Pohlemann T, and Metzger W

Subjects

Capillaries cytology, Cells, Cultured, Coculture Techniques, Endothelium, Vascular cytology, Fibroblasts ultrastructure, Fluorescent Dyes, Humans, Microscopy, Electron, Scanning, Osteoblasts ultrastructure, Spheroids, Cellular chemistry, Spheroids, Cellular ultrastructure

Abstract

3D spheroids and in particular co-culture spheroids reflect the natural organization of cells in tissues much better than 2D cell cultures as indicated by differences in cellular phyisology. However, most methods to analyze cells were established for 2D cultures and cannot easily be applied to spheroids. This study has aimed to demonstrate the possibility of quantification of the cellular composition of co-culture spheroids without previous dissociation into single cells. Prior to the generation of the spheroids, human endothelial cells, osteoblasts and fibroblasts were stained with fluoresent dyes for living cells. Co-culture spheroids of defined stoichiometric compositions were generated by the liquid overlay technique, cultivated for one, three or six days, respectively, and afterwards snap-frozen in liquid nitrogen. Cryo-sections of co-culture spheroids were analyzed by fluorescence microscopy and a newly established semi-automatic measuring routine. In order to compare the results, spheroids of one group were dissociated and the cellular composition was quantified by FACS-analysis. Staining efficiencies were higher than 95% as quantified in preliminary experiments with 2D cultures. Depending on the staining procedure, variations from uniform to punctate signals were detected. The size of all co-culture spheroids decreased over time and snap-freezing did not lead to shrinkage of the spheroids. We were able to detect organizational patterns of different cell types within the spheroids. It was possible to determine the cellular composition by quantitative microscopic analyses of cryo-sections as it could be confirmed by flow cytometric analyses. Depending on the experimental requirements, a combination of both methods might lead to valuable synergy., (Copyright © 2014 Elsevier GmbH. All rights reserved.)

Published

2014