Data di Pubblicazione:
2022
Abstract:
Neural tube defects (NTDs) represent the second most common cause of congenital malformations in the children.
Aim of the work is the development of a shape memory engineered scaffold (SMES) focused to potentially
improve Myelomeningocele (most common type of spina bifida defect) repair in fetus. Copolymer poly-L-lactideco-
ε-caprolactone (PLA-PCL) 70:30 M ratio, due to its glass transition temperature (Tg◦) close to physiologic
temperature (32–42 ◦C) was used to produce electrospun scaffolds that were engineered with MSCs from amniotic
fluid. The engineered scaffolds were rolled up and then underwent a cycle of high (T◦ > Tg◦) and low
temperature (T◦ < Tg◦) in order to induce solid status change from rubbery to glassy and fix their rolled shape.
The scaffolds were characterized for the shape memory parameters Rf% (ability to fix new temperature induced
shape) and Rr% (ability to recover the primary shape). Biological characterization included cell viability %
determination by MTT test, cytofluorimetry and microscope analysis for DAPI stained and Live-Dead Assay.
Scaffold degradation test was performed in amniotic fluid and mechanical properties of electrospun scaffold were
evaluated up to 4 months incubation in amniotic fluid simulated in vivo conditions.
The preliminary and innovative results obtained from this work permit to consider this SMES a good shape
memory material (Rf% =79 ± 5.2; Rr% = 98 ± 3.1) and suitable support for MSCs proliferation.
Aim of the work is the development of a shape memory engineered scaffold (SMES) focused to potentially
improve Myelomeningocele (most common type of spina bifida defect) repair in fetus. Copolymer poly-L-lactideco-
ε-caprolactone (PLA-PCL) 70:30 M ratio, due to its glass transition temperature (Tg◦) close to physiologic
temperature (32–42 ◦C) was used to produce electrospun scaffolds that were engineered with MSCs from amniotic
fluid. The engineered scaffolds were rolled up and then underwent a cycle of high (T◦ > Tg◦) and low
temperature (T◦ < Tg◦) in order to induce solid status change from rubbery to glassy and fix their rolled shape.
The scaffolds were characterized for the shape memory parameters Rf% (ability to fix new temperature induced
shape) and Rr% (ability to recover the primary shape). Biological characterization included cell viability %
determination by MTT test, cytofluorimetry and microscope analysis for DAPI stained and Live-Dead Assay.
Scaffold degradation test was performed in amniotic fluid and mechanical properties of electrospun scaffold were
evaluated up to 4 months incubation in amniotic fluid simulated in vivo conditions.
The preliminary and innovative results obtained from this work permit to consider this SMES a good shape
memory material (Rf% =79 ± 5.2; Rr% = 98 ± 3.1) and suitable support for MSCs proliferation.
Tipologia CRIS:
1.1 Articolo in rivista
Keywords:
Shape memory polymer; Electrospinning; Polymeric nanofibers; Engineered scaffold; Neural tube defect
Elenco autori:
Pisani, Silvia; Calcaterra, Valeria; Croce, Stefania; Dorati, Rossella; Bruni, Giovanna; Genta, Ida; Avanzini, Antonia; Benazzo, Marco; Pelizzo, Gloria; Conti, Bice
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