TY  - GEN
A1  - Zimmermann, Marc
A1  - Stomps, Benjamin René Harald
A1  - Schulte-Osseili, Christine
A1  - Grigoriev, Dmitry
A1  - Ewen, Dirk
A1  - Morgan, Andrew
A1  - Böker, Alexander
T1  - Organic dye anchor peptide conjugates as an advanced coloring agent for polypropylene yarn
T2  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - Polypropylene as one of the world's top commodity polymers is also widely used in the textile industry. However, its non-polar nature and partially crystalline structure significantly complicate the process of industrial coloring of polypropylene. Currently, textiles made of polypropylene or with a significant proportion of polypropylene are dyed under quite harsh conditions, including the use of high pressures and temperatures, which makes this process energy intensive. This research presents a three-step synthesis of coloring agents, capable of adhering onto synthetic polypropylene yarns without harsh energy-consuming conditions. This is possible by encapsulation of organic pigments using trimethoxyphenylsilane, introduction of surface double bonds via modification of the silica shell with trimethoxysilylpropylmethacrylate and final attachment of highly adhesive anchor peptides using thiol-ene chemistry. We demonstrate the applicability of this approach by dyeing polypropylene yarns in a simple process under ambient conditions after giving a step-by-step guide for the synthesis of these new dyeing agents. Finally, the successful dyeing of the yarns is visualized, and its practicability is discussed.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1380 
KW  - anchor peptides
KW  - organic dye pigments
KW  - coloring agents
KW  - polypropylene yarns
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-548913
SN  - 1866-8372
IS  - 1-2
ER  - 
TY  - JOUR
A1  - Zimmermann, Marc
A1  - Stomps, Benjamin René Harald
A1  - Schulte-Osseili, Christine
A1  - Grigoriev, Dmitry
A1  - Ewen, Dirk
A1  - Morgan, Andrew
A1  - Böker, Alexander
T1  - Organic dye anchor peptide conjugates as an advanced coloring agent for polypropylene yarn
JF  - Textile Research Journal
N2  - Polypropylene as one of the world's top commodity polymers is also widely used in the textile industry. However, its non-polar nature and partially crystalline structure significantly complicate the process of industrial coloring of polypropylene. Currently, textiles made of polypropylene or with a significant proportion of polypropylene are dyed under quite harsh conditions, including the use of high pressures and temperatures, which makes this process energy intensive. This research presents a three-step synthesis of coloring agents, capable of adhering onto synthetic polypropylene yarns without harsh energy-consuming conditions. This is possible by encapsulation of organic pigments using trimethoxyphenylsilane, introduction of surface double bonds via modification of the silica shell with trimethoxysilylpropylmethacrylate and final attachment of highly adhesive anchor peptides using thiol-ene chemistry. We demonstrate the applicability of this approach by dyeing polypropylene yarns in a simple process under ambient conditions after giving a step-by-step guide for the synthesis of these new dyeing agents. Finally, the successful dyeing of the yarns is visualized, and its practicability is discussed.
KW  - anchor peptides
KW  - organic dye pigments
KW  - coloring agents
KW  - polypropylene
KW  - yarns
Y1  - 2020
U6  - https://doi.org/10.1177/0040517520932231
SN  - 0040-5175
SN  - 1746-7748
VL  - 91
IS  - 1-2
SP  - 28
EP  - 39
PB  - Sage Publ.
CY  - London
ER  - 
TY  - THES
A1  - Schulte-Osseili, Christine
T1  - Vom Monomer zum Glykopolymer
T1  - From monomer to glycopolymer
BT  - Anwendung als Biofunktionalitäten auf Oberflächen und als Transportmoleküle
BT  - application as biofunctionalized surfaces and transport molecules
N2  - Glykopolymere sind synthetische und natürlich vorkommende Polymere, die eine Glykaneinheit in der Seitenkette des Polymers tragen. Glykane sind durch die Glykan-Protein-Wechselwirkung verantwortlich für viele biologische Prozesse. Die Beteiligung der Glykanen in diesen biologischen Prozessen ermöglicht das Imitieren und Analysieren der Wechselwirkungen durch geeignete Modellverbindungen, z.B. der Glykopolymere. Dieses System der Glykan-Protein-Wechselwirkung soll durch die Glykopolymere untersucht und studiert werden, um die spezifische und selektive Bindung der Proteine an die Glykopolymere nachzuweisen. Die Proteine, die in der Lage sind, Kohlenhydratstrukturen selektiv zu binden, werden Lektine genannt. 
In dieser Dissertationsarbeit wurden verschiedene Glykopolymere synthetisiert. Dabei sollte auf einen effizienten und kostengünstigen Syntheseweg geachtet werden. 
Verschiedene Glykopolymere wurden durch funktionalisierte Monomere mit verschiedenen Zuckern, wie z.B. Mannose, Laktose, Galaktose oder N-Acetyl-Glukosamin als funktionelle Gruppe, hergestellt. Aus diesen funktionalisierten Glykomonomeren wurden über ATRP und RAFT-Polymerisation Glykopolymere synthetisiert. 
Die erhaltenen Glykopolymere wurden in Diblockcopolymeren als hydrophiler Block angewendet und die Selbstassemblierung in wässriger Lösung untersucht. Die Polymere formten in wässriger Lösung Mizellen, bei denen der Zuckerblock an der Oberfläche der Mizellen sitzt. Die Mizellen wurden mit einem hydrophoben Fluoreszenzfarbstoff beladen, wodurch die CMC der Mizellenbildung bestimmt werden konnte. 
Außerdem wurden die Glykopolymere als Oberflächenbeschichtung über „Grafting from“ mit SI-ATRP oder über „Grafting to“ auf verschiedene Oberflächen gebunden. Durch die glykopolymerbschichteten Oberflächen konnte die Glykan Protein Wechselwirkung über spektroskopische Messmethoden, wie SPR- und Mikroring Resonatoren untersucht werden. Hierbei wurde die spezifische und selektive Bindung der Lektine an die Glykopolymere nachgewiesen und die Bindungsstärke untersucht.   
Die synthetisierten Glykopolymere könnten durch Austausch der Glykaneinheit für andere Lektine adressierbar werden und damit ein weites Feld an anderen Proteinen erschließen. Die bioverträglichen Glykopolymere wären alternativen für den Einsatz in biologischen Prozessen als Transporter von Medikamenten oder Farbstoffe in den Körper. Außerdem könnten die funktionalisierten Oberflächen in der Diagnostik zum Erkennen von Lektinen eingesetzt werden. Die Glykane, die keine selektive und spezifische Bindung zu Proteinen eingehen, könnten als antiadsorptive Oberflächenbeschichtung z.B. in der Zellbiologie eingesetzt werden.
N2  - Glycopolymers are synthetic and naturally occurring polymers that carry a gylcan unit in the side chain of the polymer. Glycans are responsible for many biological processes due to the glycn-protein interaction. The involvement of glcans in these biological processes enables the imitation and analysis of interactions by suitable model coumponds, e.g. glycopolymers. This system of glycan-protein interaction will be investigated and studied by glycopolymers in order to demonstrate the specific and selective binding of proteins to glycopolymers. The proteins that are able to selectively bind carbohydrate structures are called lectins. 
In this dissertation different glycopolymers were synthesized. Care should be taken to ensure an effficient and cost-effective synthesis route. 
Different glycopolymers were produced by functionalized monomers with different sugars, such as mannose, lactose, galactose or N-acetyl-glucosamine as functional group. From these functionalized glycomonomers, glycopolymers were synthesized via ATRP and RAFT polymerization. 
The glycopolymers obtained were used as hydrophilic blocks in diblock copolymers and self-assembly in aqueous solution was investigated. In aqueoussolution, the polymers formed micelles in which the sugar block sits on the surface of the micelles. The micelles were loaded with a hydrophobic fluorescent dxe, which made it possible to determine the CMC of micelle formation.
In additiom, the glycopolymers were bound to various surfaces as surface coatings via “grafting from” with SI-ATRP or via “grafting to”. Through the glycopolymer-coated surfaces, the glycan-protein interaction could be investigated by spectroscpic measurement methods such as SPR and microring resonators. The specific and selective binding of lectins to the glycopolymers was detected and the binding strength was investigated.
The synthesised glycopolymers could become adressable for other lectins by exchanging the glycan unit and thus open up a broad field of other proteins. The biocompatible glycopolymers would be an alternative for use in  iological processes as transporters of drugs or dyes into the body. In addtion, the functionalised surfaces could be used in diagnostics for regognition of lectins. The glycan, which do nit bind selectively and specifically to proetins, could be used as anit-adsoptive surface coatings, e.g. in cell biology.
KW  - Glykopolymere
KW  - Polymerisation
KW  - Oberflächenbeschichtung
KW  - Lektine
KW  - Glykan-Protein-Wechselwirkung
KW  - glycopolymers
KW  - polymerization
KW  - surface modification
KW  - lectins
KW  - glycan-protein interaction
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-432169
ER  - 
TY  - JOUR
A1  - Rosencrantz, Sophia
A1  - Tang, Jo Sing Julia
A1  - Schulte-Osseili, Christine
A1  - Böker, Alexander
A1  - Rosencrantz, Ruben R.
T1  - Glycopolymers by RAFT Polymerization as Functional Surfaces for Galectin-3
JF  - Macromolecular chemistry and physics
N2  - Glycan-protein interactions are essential biological processes with many disease-related modulations and variations. One of the key proteins involved in tumor progression and metastasis is galectin-3 (Gal-3). A lot of effort is put into the development of Gal-3 inhibitors as new therapeutic agents. The avidity of glycan-protein interactions is strongly enhanced by multivalent ligand presentation. Multivalent presentation of glycans can be accomplished by utilizing glycopolymers, which are polymers with pendent glycan groups. For the production of glycopolymers, glycomonomers are synthesized by a regioselective, microwave-assisted approach starting from lactose. The resulting methacrylamide derivatives are polymerized by RAFT and immobilized on gold surfaces using the trithiocarbonate group of the chain transfer agent. Surface plasmon resonance spectroscopy enables the label free kinetic characterization of Gal-3 binding to these multivalent glycopolymers. The measurements indicate oligomerization of Gal-3 upon exposure to multivalent environments and reveal strong specific interaction with the immobilized polymers.
KW  - galectin-3
KW  - glycopolymers
KW  - multivalency
KW  - RAFT
KW  - surface plasmon resonance
Y1  - 2019
U6  - https://doi.org/10.1002/macp.201900293
SN  - 1022-1352
SN  - 1521-3935
VL  - 220
IS  - 20
PB  - Wiley-VCH
CY  - Weinheim
ER  -