Low Concentrated Fractionalized Nanofibers as Suitable Fillers for Optimization of Structural–Functional Parameters of Dead Space Gel Implants after Rectal Extirpation
Markéta Bocková,
Aleksei Pashchenko,
Simona Stuchlíková,
Hana Kalábová,
Radek Divín,
Petr Novotný,
Andrea Kestlerová,
Karel Jelen,
Petr Kubový,
Peter Firment,
Ján Fedačko,
Taťána Jarošíková,
Jiří Rulc,
Jozef Rosina,
Alois Nečas,
Evžen Amler,
Jiří Hoch
Affiliations
Markéta Bocková
Second Faculty of Medicine, Charles University, 15000 Prague, Czech Republic
Aleksei Pashchenko
Second Faculty of Medicine, Charles University, 15000 Prague, Czech Republic
Simona Stuchlíková
Second Faculty of Medicine, Charles University, 15000 Prague, Czech Republic
Hana Kalábová
Faculty of Biomedical Engineering, Czech Technical University in Prague, 27201 Prague, Czech Republic
Radek Divín
Second Faculty of Medicine, Charles University, 15000 Prague, Czech Republic
Petr Novotný
University Centre for Energy Efficient Buildings, Czech Technical University in Prague, Trinecka 1024, 27343 Bustehrad, Czech Republic
Andrea Kestlerová
Second Faculty of Medicine, Charles University, 15000 Prague, Czech Republic
Karel Jelen
Faculty of Physical Education and Sport, Charles University, 16252 Prague, Czech Republic
Petr Kubový
Faculty of Physical Education and Sport, Charles University, 16252 Prague, Czech Republic
Peter Firment
Department of Anaesthesiology and Intensive Medicine, FNsP J. A. Reimana Prešov, Jána Hollého 5898/14, 08181 Prešov, Slovakia
Ján Fedačko
1st Department of Internal Medicine, Faculty of Medicine, Pavol Jozef Safarik University, Trieda SNP 1, 04190 Košice, Slovakia
Taťána Jarošíková
Faculty of Biomedical Engineering, Czech Technical University in Prague, 27201 Prague, Czech Republic
Dead space after rectal resection in colorectal surgery is an area with a high risk of complications. In this study, our goal was to develop a novel 3D implant based on composite hydrogels enriched with fractionalized nanofibers. We employed, as a novel approach in abdominal surgery, the application of agarose gels functionalized with fractionalized nanofibers on pieces dozens of microns large with a well-preserved nano-substructure. This retained excellent cell accommodation and proliferation, while nanofiber structures in separated islets allowed cells a free migration throughout the gel. We found these low-concentrated fractionalized nanofibers to be a good tool for structural and biomechanical optimization of the 3D hydrogel implants. In addition, this nano-structuralized system can serve as a convenient drug delivery system for a controlled release of encapsulated bioactive substances from the nanofiber core. Thus, we present novel 3D nanofiber-based gels for controlled release, with a possibility to modify both their biomechanical properties and drug release intended for 3D lesions healing after a rectal extirpation, hysterectomy, or pelvic exenteration.
