Functional analysis of bioactivated and antiinfective PDLLA – coated surfaces

Haidari, Selgai; Boskov, Marko; Schillinger, Ulrike; Bissinger, Oliver; Wolff, Klaus‐Dietrich; Plank, Christian; Kolk, Andreas

doi:10.1002/jbm.a.36042

Cited by 4 publications

(7 citation statements)

References 49 publications

(106 reference statements)

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“…Under the assumption that previous in vitro results are transferable to in vivo findings, we found that this limited expression level seems to be sufficient to induce NB, because of endogenous BMP‐2 release by nontransfected cells via the paracrine stimulation of cells by the gene‐activated surface within the initial 14 days postsurgery. By the gene therapeutic approach, transgene‐derived low amounts of BMP2 are produced after local transfection of cells which then can activate additional endogenous BMP2 production in non‐transfected target cells …”

Section: Discussionmentioning

confidence: 68%

“…This transfection process, however, leads to a cascade of cell differentiation and mitosis of transfected osteoprogenitor cells, which thereby enhances GF release over a longer period of time (for detailed data, please refer to Ref. ). Endogenous BMP‐2 expression, evoked by gene vectors, is more physiological in terms of, for example, host‐specific glycosylation, because of de novo synthesis by local host cells …”

Section: Discussionmentioning

confidence: 99%

“…RhBMP‐2 and pBMP‐2 have been widely investigated in preclinical settings and proven to influence osteogenesis positively by stimulating local cell growth and differentiation, although in different ways. Basing our work on previous studies in vivo and in vitro concerning the optimization of applied doses, we have now applied rhBMP‐2 and pBMP‐2 in mandibular critical size defects (CSD) of Sprague–Dawley rats and evaluated bone regeneration after four different time points. The aim of this study has been to generate and compare two different bone‐inducing surface coatings based on BMP‐2 as an osteoinductive GF in an attempt to solve the problem as to which is better: proteins or genes.…”

Section: Introductionmentioning

confidence: 99%

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Comparative analysis of bone regeneration behavior using recombinant human BMP‐2 versus plasmid DNA of BMP‐2

Kolk

Boskov

Haidari

et al. 2018

J Biomedical Materials Res

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Bone regeneration and the osteoinductive capacity of implants are challenging issues in clinical medicine. Currently, recombinant growth factors and nonviral gene transfer are the most frequently investigated methods for bone growth enhancement, although the more favorable method remains unclear. There is a lack of knowledge in literature about the in vivo comparison of these methods for bone regeneration. BMP-2, which is the most commonly used growth factor for osteogenesis, was applied at its most efficient dose as a recombinant growth factor (rhBMP-2) and as a growth-factorencoding copolymer protected gene vector (pBMP-2) in a critical size bone defect (CSD) model to determine the most suitable method for bone regeneration. CSDs were induced bilaterally in 32 Sprague-Dawley rats. RhBMP-2 (62.5 μg) or pBMP-2 (2.5 μg) was embedded in poly(D,L-)lactide-coated titanium discs. Survival times were set at 14, 28, 56, and 112 days. After euthanasia, samples were analyzed via micro-computed tomography, polychrome sequential fluorescent labeling, and immunohistochemistry. Whereas defects in both groups were bridged with new bone after 56 days, rhBMP-2 initially induced ectopic new bone formation that was later remodeled in an unorganized hypodense manner. In contrast, pBMP-2 led to slower but steady bone regeneration with physiological tissue morphology, as confirmed by high osteoblast activity shown by osteocalcin staining. CD68 and TRAP staining verified high osteoclast activity for the rhBMP-2 group. pBMP-2 successfully induced locally controlled physiological bone regeneration, whereas rhBMP-2 triggered rapid and ectopic but insufficient bone formation. Thus, nonviral gene transfer appears to be more favorable for clinical applications.

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Section: Discussionmentioning

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Comparative analysis of bone regeneration behavior using recombinant human BMP‐2 versus plasmid DNA of BMP‐2

Kolk

Boskov

Haidari

et al. 2018

J Biomedical Materials Res

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“…Similar to chemical modifications, physical modifications of the substrate impact cell-material interactions by altering the interface, yet maintain bulk material properties such as biocompatibility and hardness. Physical characteristics of the substrate have been shown to affect cellular adhesion, spreading, migration, proliferation, and morphology, presumably by spatially confining adsorbed ECM proteins and cells 40,96…”

Section: Physical Modifications That Influence Cellular Responsivenesmentioning

confidence: 99%

“…For example, some applications include coating a vascular stent with poly(lactic-co-glycolic acid) (PLGA) bilayer nanoparticles and DNA encoding vascular endothelial growth factor to prevent restenosis, 34 loading a collagen patch with bPEI and DNA encoding platelet-derived growth factor-BB to increase wound healing, 35 or coating a titanium (Ti) bone implant with poly-(d,l-lactide) and polymer vectors complexed with DNA plasmids encoding bone morphogenetic protein-2 (BMP-2) to encourage osseointegration. 36 To use a cell-material interface to prime cells for more efficient transfection, substrate properties can be tuned through chemical modifications such as the addition of natural coatings, ligands, or functional side groups, and/or physical modifications such as topography or stiffness. The cell-material interface is known to influence cell behaviors that are innately controlled by the extracellular matrix (ECM) proteins 37 that adsorb onto a culture surface or exist natively in tissue.…”

Section: Impact Statementmentioning

confidence: 99%

Biomaterial substrate modifications that influence cell-material interactions to prime cellular responses to nonviral gene delivery

Mantz

Pannier

2019

Exp Biol Med (Maywood)

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Gene delivery is the transfer of exogenous genetic material into somatic cells to modify their gene expression, with applications including tissue engineering, regenerative medicine, sensors and diagnostics, and gene therapy. Viral vectors are considered the most effective system to deliver nucleic acids, yet safety concerns and many other disadvantages have resulted in investigations into an alternative option, i.e. nonviral gene delivery. Chemical nonviral gene delivery is typically accomplished by electrostatically complexing cationic lipids or polymers with negatively charged nucleic acids. Unfortunately, nonviral gene delivery suffers from low efficiency due to barriers that impede transfection success, including intracellular processes such as internalization, endosomal escape, cytosolic trafficking, and nuclear entry. Efforts to improve nonviral gene delivery have focused on modifying nonviral vectors, yet a novel solution that may prove more effective than vector modifications is stimulating or “priming” cells before transfection to modulate and mitigate the cellular response to nonviral gene delivery. In applications where a cell-material interface exists, cell priming can come from cues from the substrate, through chemical modifications such as the addition of natural coatings, ligands, or functional side groups, and/or physical modifications such as topography or stiffness, to mimic extracellular matrix cues and modulate cellular behaviors that influence transfection efficiency. This review summarizes how biomaterial substrate modifications can prime the cellular response to nonviral gene delivery (e.g. integrin binding and focal adhesion formation, cytoskeletal remodeling, endocytic mechanisms, intracellular trafficking) to aid in improving gene delivery for future therapeutic applications. Impact statement This review summarizes how biomaterial substrate modifications (e.g. chemical modifications like natural coatings, ligands, or functional side groups, and/or physical modifications such as topography or stiffness) can prime the cellular response to nonviral gene delivery (e.g. affecting integrin binding and focal adhesion formation, cytoskeletal remodeling, endocytic mechanisms, and intracellular trafficking), to aid in improving gene delivery for applications where a cell-material interface might exist (e.g. tissue engineering scaffolds, medical implants and devices, sensors and diagnostics, wound dressings).

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Laminin 332-functionalized coating to regulate the behavior of keratinocytes and gingival mesenchymal stem cells to enhance implant soft tissue sealing

Liu

Wang

et al. 2022

Regenerative Biomaterials

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Peri-implant epithelial sealing is the first line of defense against external pathogens or stimuli; hence, an essential process to prevent peri-implantitis. Laminin 332 (LN332) is the main component of the internal basal lamina and participates in peri-implant epithelial sealing by forming hemidesmosomes with integrin α6β4. In this work, poly (D, L-lactide) (PDLLA)-LN332 composite coating was successfully constructed by a method similar to layer-by-layer assembly, displaying staged LN332 release for as long as 28 days. The PDLLA-LN332 composite coating can activate the intracellular PI3K-Akt pathway via binding to cellular integrin α6β4, which can promote adhesion, migration, and proliferation of HaCaT cells and further enhance the expression of keratinocyte hemidesmosome-related molecules, including integrin α6β4, LN332, and plectin. Furthermore, the PDLLA-LN332 composite coating can promote the adhesion, spreading, and proliferation of gingival mesenchymal stem cells（GMSCs） and accelerate their epithelial differentiation. Therefore, the PDLLA-LN332 composite coating can enhance implant soft tissue sealing, warranting further in vivo study.

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Functional analysis of bioactivated and antiinfective PDLLA – coated surfaces

Cited by 4 publications

References 49 publications

Comparative analysis of bone regeneration behavior using recombinant human BMP‐2 versus plasmid DNA of BMP‐2

Comparative analysis of bone regeneration behavior using recombinant human BMP‐2 versus plasmid DNA of BMP‐2

Biomaterial substrate modifications that influence cell-material interactions to prime cellular responses to nonviral gene delivery

Laminin 332-functionalized coating to regulate the behavior of keratinocytes and gingival mesenchymal stem cells to enhance implant soft tissue sealing

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