Lithuanian University of Health Sciences Research Management System (CRIS)
 
Use this url to cite publication: https://hdl.handle.net/20.500.12512/18206

Customization of direct laser lithography-based 3D scaffolds for optimized in vivo outcome

Type of publication
Straipsnis Web of Science ir Scopus duomenų bazėje / Article in Web of Science and Scopus database (S1)
Author(s)
AuthorAffiliation
Mačiulaitis, Justinas
Sporto medicinos klinika (U542100)
Rekštytė, Sima
Vilniaus universitetas
Bratchikov, Maksim
Vilniaus universitetas
Gudas, Rimtautas
Sporto medicinos klinika (U542100)
Malinauskas, Mangirdas
Vilniaus universitetas
Pockevičius, Alius
Veterinarinės patobiologijos katedra (U630500)
Ūsas, Arvydas
Fiziologijos ir farmakologijos institutas (U520400)
Rimkūnas, Augustinas
Fiziologijos ir farmakologijos institutas (U520400)
Jankauskaitė, Virginija
Kauno technologijos universitetas
Grigaliūnas, Valdas
Kauno technologijos universitetas
Mačiulaitis, Romaldas
Fiziologijos ir farmakologijos institutas (U520400)
Title
Customization of direct laser lithography-based 3D scaffolds for optimized in vivo outcome
[en]
Publisher (trusted)
Elsevier Science Publishers
Is Referenced by
Science Citation Index Expanded
Scopus
INSPEC
Date Issued
Date
2019-05-05
Extent
p. 692-702
Is part of
Applied surface science. Amsterdam : Elsevier Science, 2019, vol. 487.
Version
Originalus / Original
Field of Science

Medicina / Medicine (...

Biologija / Biology (...

Keywords (en)

Cartilage, articular

Cartilage, articular

Tissue scaffolds

Tissue engineering

Printing, three-dimen...

Abstract (en)

Direct laser writing 3D lithography in pre-polymers was employed to microstructure custom 3D siliconzirconium hybrid organic-inorganic polymer SZ2080 scaffolds (HOI) of varying morphology for cartilage repair in a preclinical xenogeneic model. Scaffolds were fabricated to contain tetragonal and hexagonal pores, followed by pore scaling of 1.5 and 2 times. HOI scaffolds were seeded with human chondrocytes (cells) and biocompatibility was analysed in vitro. Tissue engineered cartilage (TEC) potency, efficacy and shelf-life in vitro was assessed by morphological, biomechanical, metabolic activity, cell count, ELISA and PCR analysis. Optimal HOI scaffold was implanted in a long-term preclinical osteochondral defect of immunodeficient rat model and analyzed for the translated efficacy in experimental groups. Collagen scaffold was a positive comparator for in vitro and in vivo studies. Treatment efficacy was evaluated after 3 months using standardized macroscopical and histological scores. Biocompatibility was superior in tetragon-pored scaffold (HOI-T) compared to hexagon-pored HOI in vitro. Cartilage tissue formation in HOI with tetragonal pores scaled 1.5 times was comparable to HOI-T at least for up to 7 days in vitro. HOI-T with and without cells im

Type of document
type::text::journal::journal article::research article
ISSN (of the container)
0169-4332
WOS
000471996400080
Other Identifier(s)
(LSMU ALMA)990000993300107106
Coverage Spatial
Naujoji Kaledonija / New Caledonia (NC)
Language
Anglų / English (en)
URI
URI
https://hdl.handle.net/20.500.12512/18206
Bibliographic Details
69
Affiliation(s)
Funding(s)
Funding(s)Project ID
Lietuvos Mokslo taryba
Date Reporting
2019