Thermosensitive Hydrogel Based on PEO–PPO–PEO Poloxamers for a Controlled In Situ Release of Recombinant Adeno‐Associated Viral Vectors for Effective Gene Therapy of Cartilage Defects

Madry, Henning; Rey‐Rico, Ana; Venkatesan, Jagadeesh K.; Müller-Brandt, Kathrin; Cai, Xiaoyu; Goebel, Lars; Schmitt, Gertrud; Speicher-Mentges, Susanne; Zurakowski, David; Menger, Michael D.; Laschke, Matthias W.; Cucchiarini, Magali

doi:10.1002/adma.201906508

Cited by 135 publications

(114 citation statements)

References 29 publications

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“…Controlled release of the therapeutic SOX9 from the poloxamer gel improved repair of full-thickness chondral defects. 238 To further enhance adhesiveness of poloxamer 407 for local viral delivery to organ surfaces, it was blended with >1% polycarbophil, a polyacrylic acid cross-linked with divinyl glycol. Addition of polycarbophil changed the sol-gel transition temperature and led to higher adhesiveness due to numerous carboxylic groups, which can easily form bonds with surrounding molecules.…”

Section: Review Biomaterials Sciencementioning

confidence: 99%

Materials promoting viral gene delivery

Kaygisiz

Synatschke

2020

Biomater. Sci.

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Section: Review Biomaterials Sciencementioning

confidence: 99%

Materials promoting viral gene delivery

Kaygisiz

Synatschke

2020

Biomater. Sci.

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“…Scaffold-assisted gene therapy is a powerful tool to durably and safely enhance the processes of cartilage repair [10][11][12] via single-step, controlled delivery of clinically adapted rAAV gene transfer vectors [25][26][27][28][29][30][31][32][33]. In the current work, we tested the ability of mechanically stable, biocompatible PCL scaffolds functionalized with a bioactive pNaSS molecule to transfer rAAV vectors coding for the cartilage-specific SOX9 transcription factor to human bone marrow aspirates as a means to generate more efficient, non-invasive systems to treat focal cartilage lesions compared with a less stable scaffold-free vector application lacking scaffolding benefits for the cell targets [42] or with complex, indirect transplantation of rAAV-modified aspirates via such materials [43].…”

Section: Discussionmentioning

confidence: 99%

“…As a matter of fact, a number of studies reported the potential of applying rAAV for experimental cartilage research via hydrogel systems (alginate, fibrin, poloxamers/poloxamines, self-assembling peptides, polypseudorotaxanes) [25][26][27][28][29][30][31][32][33] while there is still little information on the potential benefits of solid, mechanically more stable biomaterials that may provide scaffolding and stability to the target cells [34] for rAAV-mediated gene transfer. In this regard, we recently provided evidence that biocompatible solid polyester poly(ε-caprolactone) (PCL) [35], an aliphatic polyester approved by the FDA [36,37], further grafted with poly(sodium styrene sulfonate) (pNaSS) to activate reparative cellular responses [38] is capable of supporting the delivery of reporter rAAV gene vectors to effectively modify human bone marrow aspirates [39].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Chondrogenic Differentiation Activities in Human Bone Marrow Aspirates via sox9 Overexpression Mediated by pNaSS-Grafted PCL Film-Guided rAAV Gene Transfer

et al. 2020

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Background: The delivery of therapeutic genes in sites of articular cartilage lesions using non-invasive, scaffold-guided gene therapy procedures is a promising approach to stimulate cartilage repair while protecting the cargos from detrimental immune responses, particularly when targeting chondroreparative bone marrow-derived mesenchymal stromal cells in a natural microenvironment like marrow aspirates. Methods: Here, we evaluated the benefits of providing a sequence for the cartilage-specific sex-determining region Y-type high-mobility group box 9 (SOX9) transcription factor to human marrow aspirates via recombinant adeno-associated virus (rAAV) vectors delivered by poly(ε-caprolactone) (PCL) films functionalized via grafting with poly(sodium styrene sulfonate) (pNaSS) to enhance the marrow chondrogenic potential over time. Results: Effective sox9 overexpression was observed in aspirates treated with pNaSS-grafted or ungrafted PCL films coated with the candidate rAAV-FLAG-hsox9 (FLAG-tagged rAAV vector carrying a human sox9 gene sequence) vector for at least 21 days relative to other conditions (pNaSS-grafted and ungrafted PCL films without vector coating). Overexpression of sox9 via rAAV sox9/pNaSS-grafted or ungrafted PCL films led to increased biological and chondrogenic differentiation activities (matrix deposition) in the aspirates while containing premature osteogenesis and hypertrophy without impacting cell proliferation, with more potent effects noted when using pNaSS-grafted films. Conclusions: These findings show the benefits of targeting patients’ bone marrow via PCL film-guided therapeutic rAAV (sox9) delivery as an off-the-shelf system for future strategies to enhance cartilage repair in translational applications.

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“…Next, the apparent absence of an immune response in all defects (lack of expression of CD3 for T-lymphocytes, of CD11b for activated macrophages, and of human leukocyte antigen isotype DR alpha—HLA-DRα—for class II major histocompatibility complex—MHC—antigens) supported the use of such PEO-PPO-PEO poloxamers to protect rAAV-mediated gene transfer from neutralization by antibodies directed against the AAV capsid. Although not directly applied to an osteochondral defect model, this study showed by a comprehensive analyses of the entire osteochondral unit that rAAV-FLAG-h sox9 /PEO-PPO-PEO hydrogel-augmented microfracture significantly improves osteochondral repair [ 151 ].…”

Section: Scaffold-mediated Viral In Vivo Gene Delivery For Osteochmentioning

confidence: 99%

Scaffold-Mediated Gene Delivery for Osteochondral Repair

et al. 2020

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Osteochondral defects involve both the articular cartilage and the underlying subchondral bone. If left untreated, they may lead to osteoarthritis. Advanced biomaterial-guided delivery of gene vectors has recently emerged as an attractive therapeutic concept for osteochondral repair. The goal of this review is to provide an overview of the variety of biomaterials employed as nonviral or viral gene carriers for osteochondral repair approaches both in vitro and in vivo, including hydrogelsPEVuZE5vdGU+PENpdGU+PEF1dGhvcj5QdWVydGFzLUJhcnRvbG9tZTwvQXV0aG9yPjxZZWFyPjIw MTg8L1llYXI+PFJlY051bT4xMTk8L1JlY051bT48RGlzcGxheVRleHQ+PHN0eWxlIHNpemU9IjEw Ij5bMV08L3N0eWxlPjwvRGlzcGxheVRleHQ+PHJlY29yZD48cmVjLW51bWJlcj4xMTk8L3JlYy1u dW1iZXI+PGZvcmVpZ24ta2V5cz48a2V5IGFwcD0iRU4iIGRiLWlkPSJ4NXIwYTlwdnV6MGYwMmU5 c3dkeDB2MGh0ZXBleHA5ZjlwcDkiIHRpbWVzdGFtcD0iMTU5ODgwODM4NyI+MTE5PC9rZXk+PC9m b3JlaWduLWtleXM+PHJlZi10eXBlIG5hbWU9IkpvdXJuYWwgQXJ0aWNsZSI+MTc8L3JlZi10eXBl Pjxjb250cmlidXRvcnM+PGF1dGhvcnM+PGF1dGhvcj5QdWVydGFzLUJhcnRvbG9tZSwgTS48L2F1 dGhvcj48YXV0aG9yPkJlbml0by1HYXJ6b24sIEwuPC9hdXRob3I+PGF1dGhvcj5PbG1lZGEtTG96 YW5vLCBNLjwvYXV0aG9yPjwvYXV0aG9ycz48L2NvbnRyaWJ1dG9ycz48YXV0aC1hZGRyZXNzPklu c3RpdHV0ZSBvZiBQb2x5bWVyIFNjaWVuY2UgYW5kIFRlY2hub2xvZ3ktSUNUUC1DU0lDLCBDL0p1 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Pn== , solid scaffolds, and hybrid materials. The data show that a site-specific delivery of therapeutic gene vectors in the context of acellular or cellular strategies allows for a spatial and temporal control of osteochondral neotissue composition in vitro. In vivo, implantation of acellular hydrogels loaded with nonviral or viral vectors has been reported to significantly improve osteochondral repair in translational defect models. These advances support the concept of scaffold-mediated gene delivery for osteochondral repair.

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Thermosensitive Hydrogel Based on PEO–PPO–PEO Poloxamers for a Controlled In Situ Release of Recombinant Adeno‐Associated Viral Vectors for Effective Gene Therapy of Cartilage Defects

Cited by 135 publications

References 29 publications

Materials promoting viral gene delivery

Materials promoting viral gene delivery

Enhanced Chondrogenic Differentiation Activities in Human Bone Marrow Aspirates via sox9 Overexpression Mediated by pNaSS-Grafted PCL Film-Guided rAAV Gene Transfer

Scaffold-Mediated Gene Delivery for Osteochondral Repair

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