Browsing by Author "Figueira, Daniela Sofia Rodrigues"
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- 3D Printed scaffolds with bactericidal activity aimed for bone tissue regenerationPublication . Correia, Tiago R.; Figueira, Daniela Sofia Rodrigues; Sá, Kevin; Miguel, Sónia P.; Fradique, Ricardo Gil; Mendonça, António; Correia, I.J.Nowadays, the incidence of bone disorders has steeply ascended and it is expected to double in the next decade, especially due to the ageing of the worldwide population. Bone defects and fractures lead to reduced patient’s quality of life. Autografts, allografts and xenografts have been used to overcome different types of bone injuries, although limited availability, immune rejection or implant failure demand the development of new bone replacements. Moreover, the bacterial colonization of bone substitutes is the main cause of implant rejection. To vanquish these drawbacks, researchers from tissue engineering area are currently using computer-aided design models or medical data to produce 3D scaffolds by Rapid Prototyping (RP). Herein, Tricalcium phosphate (TCP)/Sodium Alginate (SA) scaffolds were produced using RP and subsequently functionalized with silver nanoparticles (AgNPs) through two different incorporation methods. The obtained results revealed that the composite scaffolds produced by direct incorporation of AgNPs are the most suitable for being used in bone tissue regeneration since they present appropriate mechanical properties, biocompatibility and bactericidal activity.
- 3D scaffolds coated with nanofibers displaying bactericidal activity for bone tissue applicationsPublication . Sá, Kevin; Figueira, Daniela Sofia Rodrigues; Miguel, Sónia P.; Correia, Tiago R.; Silva, Abílio Manuel Pereira da; Correia, I.J.Bone-limited capacity to fully repair large defects requires the development of new implants. In this context, new approaches have been used to promote bone regeneration and also to avoid the side effects associated with the therapeutics currently used in the clinic. Herein, 3D tricalcium phosphate/alginic acid scaffolds were produced and then coated with an electrospun mesh loaded with two different antibacterial agents, silver nanoparticles, and salicylic acid. The obtained results showed that the produced scaffolds have suitable mechanical properties, swelling, biodegradation, biomineralization activity, enhanced cellular adhesion/proliferation and bactericidal activity, and features essential for bone regeneration.
- Desenvolvimento de novas abordagens terapêuticas para a regeneração da pelePublication . Figueira, Daniela Sofia Rodrigues; Correia, Ilídio Joaquim Sobreira; Correia, Tiago Ruivo; Miguel, Sónia Alexandra PereiraEvery year, millions of patients suffer burns, chronic or surgical-related wounds. Autografts are still the gold standard used for the treatment of these injuries, although they have several drawbacks like limited availability of donor sites, patient morbidity, and long periods of hospitalization. To surpass such drawbacks, several studies have been focused on the development of polymeric matrices that are able to reproduce the skin native structure and also improve its regeneration. Herein, a bilayer membrane was produced by electrospinning and its properties have been characterized through in vitro assays. The upper layer of the membrane was comprised of hyaluronic acid and polycaprolactone in order to provide mechanical support and also to act as a physical barrier against external threats. Chitosan and zein were used to produce the bottom layer. Furthermore, salicylic acid was also incorporated in this layer for conferring anti-inflammatory and antimicrobial properties to the membrane. The obtained results showed that the produced electrospun meshes display an ideal porosity, appropriate mechanical properties, controlled evaporative water loss and an initial burst release of SA. Moreover, the membranes did not exhibit any toxic effects for human fibroblast cells and promoted their adhesion, spread, and proliferation. In addition, no biofilm formation was noticed on their surface along the experiments. The obtained data reveal that this electrospun membrane possesses the required properties to be used in wound healing.
- Electrospun polymeric nanofibres as wound dressings: A reviewPublication . Miguel, Sónia P.; Figueira, Daniela Sofia Rodrigues; Simões, Déborah; Ribeiro, MP.; Coutinho, Paula; Ferreira, Paula; Correia, Ilídio Joaquim SobreiraSkin wounds have significant morbidity and mortality rates associated. This is explained by the limited effectiveness of the currently available treatments, which in some cases do not allow the reestablishment of the structure and functions of the damaged skin, leading to wound infection and dehydration. These drawbacks may have an impact on the healing process and ultimately prompt patients’ death. For this reason, researchers are currently developing new wound dressings that enhance skin regeneration. Among them, electrospun polymeric nanofibres have been regarded as promising tools for improving skin regeneration due to their structural similarity with the extracellular matrix of normal skin, capacity to promote cell growth and proliferation and bactericidal activity as well as suitability to deliver bioactive molecules to the wound site. In this review, an overview of the recent studies concerning the production and evaluation of electrospun polymeric nanofibrous membranes for skin regenerative purposes is provided. Moreover, the current challenges and future perspectives of electrospun nanofibrous membranes suitable for this biomedical application are highlighted.
- Production and characterization of polycaprolactone- hyaluronic acid/chitosan-zein electrospun bilayer nanofibrous membrane for tissue regenerationPublication . Figueira, Daniela Sofia Rodrigues; Miguel, Sónia P.; Sá, Kevin; Correia, Ilídio Joaquim SobreiraA bilayered electrospun membrane was produced in this study, using the electrospinning technique, to be applied as a skin substitute. The upper layer of the membrane was comprised by hyaluronic acid and polycaprolactone in order to provide mechanical support and also to act as a physical barrier against external threats. Chitosan and zein were used to produce the bottom layer that was loaded with salicylic acid, in order to confer anti-inflammatory and antimicrobial activity to this layer. The physicochemical properties of the membranes were determined and the obtained results showed that the produced electrospun membrane display an ideal porosity, appropriate mechanical properties, controlled water loss and a suitable salicylic acid release profile. In addition, membranes did not exhibit any toxic effects for human fibroblast cells, since cells were able to adhere, spread and proliferate. Furthermore, no biofilm formation was noticed on membranes’ surface along the experiments. In conclusion, the gathered data reveal that this electrospun membrane has suitable properties to be used as a wound dressing.
- Production of new 3D scaffolds for bone tissue regeneration by rapid prototypingPublication . Fradique, Ricardo Gil; Correia, Tiago R.; Miguel, Sónia P.; Sá, Kevin; Figueira, Daniela Sofia Rodrigues; Mendonça, António; Correia, Ilídio Joaquim SobreiraThe incidence of bone disorders, whether due to trauma or pathology, has been trending upward with the aging of the worldwide population. The currently available treatments for bone injuries are rather limited, involving mainly bone grafts and implants. A particularly promising approach for bone regeneration uses rapid prototyping (RP) technologies to produce 3D scaffolds with highly controlled structure and orientation, based on computer-aided design models or medical data. Herein, tricalcium phosphate (TCP)/alginate scaffolds were produced using RP and subsequently their physicochemical, mechanical and biological properties were characterized. The results showed that 60/40 of TCP and alginate formulation was able to match the compression and present a similar Young modulus to that of trabecular bone while presenting an adequate biocompatibility. Moreover, the biomineralization ability, roughness and macro and microporosity of scaffolds allowed cell anchoring and proliferation at their surface, as well as cell migration to its interior, processes that are fundamental for osteointegration and bone regeneration.