<scp>3D</scp> printed‐polylactic acid scaffolds coated with natural rubber latex for biomedical application

Marcatto, Vinicius Assis; Pegorin, Giovana Sant’Ana; Barbosa, Gustavo Franco; Herculano, Rondinelli Donizetti; Guerra, Nayrim Brizuela

doi:10.1002/app.51728

Cited by 8 publications

(4 citation statements)

References 52 publications

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“…We selected PLA to represent synthetic polymers in this study because, much like how collagen exhibits many key advantages and disadvantages of natural polymers, so does PLA for synthetic ones. These advantages include the aforementioned high biocompatibility, as well as the high biodegradability, excellent mechanical and barrier properties, relatively low cost, and high tunability, which can be controlled during production or post-processing [ 16 ]. This allows for the more precise and controllable mimicry of the extracellular matrix.…”

Section: Introductionmentioning

confidence: 99%

Comparison of NIH 3T3 Cellular Adhesion on Fibrous Scaffolds Constructed from Natural and Synthetic Polymers

et al. 2023

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Polymer scaffolds are increasingly ubiquitous in the field of tissue engineering in improving the repair and regeneration of damaged tissue. Natural polymers exhibit better cellular adhesion and proliferation than biodegradable synthetics but exhibit inferior mechanical properties, among other disadvantages. Synthetic polymers are highly tunable but lack key binding motifs that are present in natural polymers. Using collagen and poly(lactic acid) (PLA) as models for natural and synthetic polymers, respectively, an evaluation of the cellular response of embryonic mouse fibroblasts (NIH 3T3 line) to the different polymer types was conducted. The samples were analyzed using LIVE/DEAD™, alamarBlue™, and phalloidin staining to compare cell proliferation on, interaction with, and adhesion to the scaffolds. The results indicated that NIH3T3 cells prefer collagen-based scaffolds. PLA samples had adhesion at the initial seeding but failed to sustain long-term adhesion, indicating an unsuitable microenvironment. Structural differences between collagen and PLA are responsible for this difference. Incorporating cellular binding mechanisms (i.e., peptide motifs) utilized by natural polymers into biodegradable synthetics offers a promising direction for biomaterials to become biomimetic by combining the advantages of synthetic and natural polymers while minimizing their disadvantages.

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Section: Introductionmentioning

confidence: 99%

Comparison of NIH 3T3 Cellular Adhesion on Fibrous Scaffolds Constructed from Natural and Synthetic Polymers

et al. 2023

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“…This polymer stands out for its behaviour in contact with biological media, as it gradually degrades into innocuous lactic acid or carbon dioxide and water and is metabolised intracellularly or excreted in urine and breath over time [ 1 , 3 ]. In addition to this immunologically inert response, PLA does not produce toxic or carcinogenic effects in local tissues, it is completely reabsorbed, and its production is relatively cost-efficient as compared to other traditional biodegradable polymers [ 4 ]. Given its biocompatible, biodegradable and bioabsorbable properties, PLA has become one of the most commonly used polymers in clinics with numerous applications including medical implants, porous scaffolds, sutures, cell carriers, drug delivery systems and a myriad of other fabrications [ 1 , 2 , 5 ].…”

Section: Introductionmentioning

confidence: 99%

3D-Printed PLA Medical Devices: Physicochemical Changes and Biological Response after Sterilisation Treatments

et al. 2022

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Polylactic acid (PLA) has become one of the most commonly used polymers in medical devices given its biocompatible, biodegradable and bioabsorbable properties. In addition, due to PLA’s thermoplastic behaviour, these medical devices are now obtained using 3D printing technologies. Once obtained, the 3D-printed PLA devices undergo different sterilisation procedures, which are essential to prevent infections. This work was an in-depth study of the physicochemical changes caused by novel and conventional sterilisation techniques on 3D-printed PLA and their impact on the biological response in terms of toxicity. The 3D-printed PLA physicochemical (XPS, FTIR, DSC, XRD) and mechanical properties as well as the hydrophilic degree were evaluated after sterilisation using saturated steam (SS), low temperature steam with formaldehyde (LTSF), gamma irradiation (GR), hydrogen peroxide gas plasma (HPGP) and CO2 under critical conditions (SCCO). The biological response was tested in vitro (fibroblasts NCTC-929) and in vivo (embryos and larvae wild-type zebrafish Danio rerio). The results indicated that after GR sterilisation, PLA preserved the O:C ratio and the semi-crystalline structure. Significant changes in the polymer surface were found after HPGP, LTSF and SS sterilisations, with a decrease in the O:C ratio. Moreover, the FTIR, DSC and XRD analysis revealed PLA crystallisation after SS sterilisation, with a 52.9% increase in the crystallinity index. This structural change was also reflected in the mechanical properties and wettability. An increase in crystallinity was also observed after SCCO and LTSF sterilisations, although to a lesser extent. Despite these changes, the biological evaluation revealed that none of the techniques were shown to promote the release of toxic compounds or PLA modifications with toxicity effects. GR sterilisation was concluded as the least reactive technique with good perspectives in the biological response, not only at the level of toxicity but at all levels, since the 3D-printed PLA remained almost unaltered.

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“…[ 6,7 ] In particular, employment in the biomedical field has always attracted much interest, thanks to PLA biocompatibility and good processability, which allows for the preparation of scaffolds, even with complex shapes. [ 8,9 ] However, PLA's poor toughness has always been a strong hurdle to its applicability in this field, especially when dealing with bone‐regeneration applications. [ 10,11 ] In the search for possible improvements of PLA's mechanical properties, one of the most investigated approaches relies on the preparation of crosslinked materials, since crosslinks impart additional dimensional stability to the polymer, improving its toughness.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Fluorine‐Containing, UV‐Responsive PLA‐Based Materials by Means of Functionalized DOX Monomer

Gazzotti

Ortenzi

Farina

et al. 2022

Macro Chemistry & Physics

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1,3‐Dioxolan‐4‐ones (DOX) chemistry is exploited for the synthesis of UV‐curable, polylactic acid (PLA)‐based copolymers. DOX monomer functionalized with 4‐fluoro‐4′‐hydroxybenzophenone is synthesized and employed as comonomer with l‐lactide. Copolymerization reactions are performed with different DOX loadings through a solvent‐free, metal‐catalyzed protocol. Products are characterized through NMR analysis in order to demonstrate the random insertion of the modified monomer within the polymeric chain. Copolymers are subjected to UV irradiation and compared to a control PLA synthesized and processed in the same conditions. The evolution of the molecular weight during prolonged UV exposure is evaluated through SEC analysis, showing the effect of the benzophenone side groups, which promote crosslinking reactions. A crosslinking mechanism is proposed and demonstrated by means of 1H NMR and FT‐IR analyses. The gel content of the samples is measured after the UV exposure, demonstrating a correlation with the concentration of DOX‐derived units. Finally, water contact angle analyses are performed to investigate the effects of the fluorination degree on the wettability properties and thermal characterization is carried out. Moreover, rheological analyses show a shear thickening behavior for the copolymers with the highest concentration of DOX‐derived units.

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3D printed‐polylactic acid scaffolds coated with natural rubber latex for biomedical application

Cited by 8 publications

References 52 publications

Comparison of NIH 3T3 Cellular Adhesion on Fibrous Scaffolds Constructed from Natural and Synthetic Polymers

Comparison of NIH 3T3 Cellular Adhesion on Fibrous Scaffolds Constructed from Natural and Synthetic Polymers

3D-Printed PLA Medical Devices: Physicochemical Changes and Biological Response after Sterilisation Treatments

Synthesis of Fluorine‐Containing, UV‐Responsive PLA‐Based Materials by Means of Functionalized DOX Monomer

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