Topology Effects on the Structural and Physicochemical Properties of Polymer Brushes

Divandari, Mohammad; Morgese, Giulia; Trachsel, Lucca; Romio, Matteo; Dehghani, Ella S.; Rosenboom, Jan‐Georg; Paradisi, Cristina; Zenobi‐Wong, Marcy; Ramakrishna, Shivaprakash N.; Benetti, Edmondo M.

doi:10.1021/acs.macromol.7b01720

Cited by 90 publications

(111 citation statements)

References 69 publications

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“…These results further corroborated the improvement in antifouling properties by cyclic PEOXAb rushes assembled on flat TiO 2 surfaces,w hich was ascribed to their higher grafting density coupled with their less compressible character when proteins approach the functionalized surface. [22,29] In the present system, we demonstrate that cyclic PMOXA brushes fabricated via copolymer chemisorption on cartilage surfaces also showed this distinctive topology effect, reducing protein contamination on the complex and rough surface of acollagenous tissue.…”

Section: Angewandte Chemiementioning

confidence: 56%

“…Moreover,r eplacing LPMOXA with CPMOXA for a = 0.1 and 0.3 determined asubstantial and statistically relevant decrease in the measured m at the highest applied pressures tested. Thea bsence of chain ends by CPMOXA prevented interdigitation under load [22,29,30] and ensured the constant presence of afluid film between the sheared brush interfaces.…”

Section: Angewandte Chemiementioning

confidence: 99%

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Cyclic Polymer Grafts That Lubricate and Protect Damaged Cartilage

et al. 2018

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Tissue-reactive graft copolymers were designed to protect the cartilage against enzymatic degradation and restore its lubrication properties during the early stages of osteoarthritis (OA). The copolymers feature a poly(glutamic acid) (PGA) backbone bearing hydroxybenzaldehyde (HBA) functions and cyclic poly(2-methyl-2-oxazoline) (PMOXA) side chains. PGA-PMOXA-HBA species chemisorb on the degraded tissue via Schiff bases and expose the biopassive and lubricious PMOXA cyclic grafts at the interface. The smaller hydrodynamic radius by cyclic PMOXA side chains coupled to the intrinsic absence of chain ends generate denser and more lubricious films on cartilage when compared to those produced by copolymers bearing linear PMOXA. Topology effects demonstrate how the introduction of cyclic polymers within tissue-reactive copolymers substantially improve their tribological and biopassive properties, suggesting a plethora of possible applications for cyclic macromolecules in biomaterials formulations.

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Section: Angewandte Chemiementioning

confidence: 56%

Section: Angewandte Chemiementioning

confidence: 99%

Cyclic Polymer Grafts That Lubricate and Protect Damaged Cartilage

et al. 2018

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“…The replacement of L PMOXA with C PMOXA grafts determined a significant decrease in the physisorbed biofilm thickness (Supporting Information, Figure S11). These results further corroborated the improvement in antifouling properties by cyclic PEOXA brushes assembled on flat TiO 2 surfaces, which was ascribed to their higher grafting density coupled with their less compressible character when proteins approach the functionalized surface . In the present system, we demonstrate that cyclic PMOXA brushes fabricated via copolymer chemisorption on cartilage surfaces also showed this distinctive topology effect, reducing protein contamination on the complex and rough surface of a collagenous tissue.…”

Section: Methodsmentioning

confidence: 99%

Cyclic Polymer Grafts That Lubricate and Protect Damaged Cartilage

et al. 2018

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Tissue-reactive graft copolymers were designed to protect the cartilage against enzymatic degradation and restore its lubrication properties during the early stages of osteoarthritis (OA). The copolymers feature ap oly(glutamic acid) (PGA) backbone bearing hydroxybenzaldehyde (HBA) functions and cyclic poly(2-methyl-2-oxazoline) (PMOXA) side chains.P GA-PMOXA-HBAs pecies chemisorb on the degraded tissue via Schiff bases and expose the biopassive and lubricious PMOXA cyclic grafts at the interface.T he smaller hydrodynamic radius by cyclic PMOXA side chains coupled to the intrinsic absence of chain ends generate denser and more lubricious films on cartilage when compared to those produced by copolymers bearing linear PMOXA. Topology effects demonstrate howt he introduction of cyclic polymers within tissue-reactive copolymers substantially improve their tribological and biopassive properties,suggesting aplethora of possible applications for cyclic macromolecules in biomaterials formulations.

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“…[57 -59] Similarly to their PEG-based analogues, poly(2ethyl-2-oxazoline) (PEOXA) brushes assembled on TiO 2 surfaces ( Figure 4) show a lubricious character that is strictly correlated with their surface coverage (expressed as grafting density, Σ, in Figure 4). [60,61] The characterization of the nanotribological properties of PEOXA brushes by lateral force microscopy (LFM) [62] has further highlighted the effect of chain interdigitation in determining friction between brushbearing surfaces. As shown in the friction force-vs.applied load (F f L) profiles reported in Figure 4,b, when PEOXA brushes are sheared against an identical brush countersurface, friction is generally lower for all grafting densities investigated, compared to the case where the same brushes are slid past a bare TiO 2 surface.…”

Section: Alternatives To Peg Brushesmentioning

confidence: 99%

“…This phenomenon was due to the absence of linear chain ends within cyclic brushes, which hinders interpenetration between opposing grafts [81] and markedly reduces dissipative forces that are typically responsible for the increment in friction observed between linear brushes at relatively high applied loads. [60,61]…”

Section: Effect Of Brush Architecture On Protein Resistance and Lubrimentioning

confidence: 99%

Using Polymers to Impart Lubricity and Biopassivity to Surfaces: Are These Properties Linked?

Benetti

Spencer

2019

Helvetica Chimica Acta

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Polymer brushes have been widely applied for the reduction of both friction and non‐specific protein adsorption. In many (but not all) applications, such as contact lenses or medical devices, this combination of properties is highly desirable. Indeed, for many polymer‐brush systems, lubricity and resistance to biofouling appear to go hand in hand, with modifications of brush architecture, for example, leading to a similar degree of enhancement (or degradation) in both properties. In the case of poly(ethylene glycol) (PEG) brushes, this has been widely demonstrated. There are, however, examples where this behavior breaks down. In systems where linear brushes are covalently crosslinked during surface‐initiated polymerization (SIP), for example, the presence and the chemical nature of links between grafted chains might or might not influence biopassivity of the films, while it always causes an increment in friction. Furthermore, when the grafted‐chain topology is shifted from linear to cyclic, chemically identical brushes show a substantial improvement in lubrication, whereas their protein resistance remains unaltered. Architectural control of polymer brush films can provide another degree of freedom in the design of lubricious and biopassive coatings, leading to new combinations of surface properties and their independent modulation.

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Topology Effects on the Structural and Physicochemical Properties of Polymer Brushes

Cited by 90 publications

References 69 publications

Cyclic Polymer Grafts That Lubricate and Protect Damaged Cartilage

Cyclic Polymer Grafts That Lubricate and Protect Damaged Cartilage

Cyclic Polymer Grafts That Lubricate and Protect Damaged Cartilage

Using Polymers to Impart Lubricity and Biopassivity to Surfaces: Are These Properties Linked?

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