Preparação e caracterização de estruturas porosas de poli(3-hidroxibutirato)

Sader, Marcia S.; Ferreira, Mariana Nunes; Dias, Marcos L.

doi:10.1590/s0104-14282006000100006

Cited by 4 publications

(6 citation statements)

References 7 publications

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“…In this context, biodegradable polymers have attracted much attention because they can be tailored to degrade within a time frame compatible with tissue growth. Among these materials, the biopolymer poly(3‐hydroxybutyrate) (PHB) is of particular interest for bone‐tissue engineering since devices made of PHB are compatible with some cultured mammalian cells, including osteoblasts 7–11. PHB has not been used as a structural material because of its brittleness and narrow “processability window” [i.e., its melting temperature ( T m ) is very close to the point of thermal degradation] 12.…”

Section: Introductionmentioning

confidence: 99%

“…Among these materials, the biopolymer poly(3-hydroxybutyrate) (PHB) is of particular interest for bone-tissue engineering since devices made of PHB are compatible with some cultured mammalian cells, including osteoblasts. [7][8][9][10][11] PHB has not been used as a structural material because of its brittleness and narrow ''processability window'' [i.e., its melting temperature (T m ) is very close to the point of thermal degradation]. 12 One of the strategies used to improve its properties is to blend PHB with others polymers, such as chitosan (CTS), a cationic polysaccharide derived from the deacetylation of chitin.…”

Section: Introductionmentioning

confidence: 99%

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Production of 3D scaffolds applied to tissue engineering using chitosan swelling as a porogenic agent

Mendonça

Meiga

Costa

et al. 2012

J of Applied Polymer Sci

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The preparation of 3D scaffolds using poly(3‐hydroxybutyrate) (PHB) and chitosan (CTS) has been proposed because of the favorable interactions of these materials with mammalian cells in particular osteoblasts (HOB). In this work, a new method of producing porous 3D scaffolds based on the swelling of a dense matrix of PHB and CTS was developed. Scanning electron microscopy images showed the formation of an interconnected porous CTS structure inside a PHB structure. The pore formation was attributed to the swelling of CTS. The scaffolds presented 70% porosity, heterogeneous pore‐size distribution, and a compressive modulus equal to (13.07 ± 0.014) MPa, which is close to that of cancellous bone. In vitro cytotoxicity assays indicate that the scaffold was not cytotoxic. Its morphology, chemical, and physical properties indicate that the scaffold produced by this new methodology has potential applications in bone‐tissue engineering, with drug‐delivery capabilities. © 2012 Wiley Periodicals, Inc. J. Appl. Polym. Sci., 2013

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Production of 3D scaffolds applied to tissue engineering using chitosan swelling as a porogenic agent

Mendonça

Meiga

Costa

et al. 2012

J of Applied Polymer Sci

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“…Os arcabouços foram preparados pela técnica de lixiviação de sal/ evaporação do solvente, com base no procedimento descrito em [13] . Solução de PHB em clorofórmio (grau PA; Vetec Química Fina Ltda) a 10% (p/v) foi preparada sob refluxo a 63 °C.…”

Section: Methodsunclassified

Adsorção de fibronectina a arcabouços de polihidroxibutirato aplicáveis à engenharia óssea

et al. 2009

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liéster natural de origem bacteriana, biocompatível a vários tipos celulares tais como osteoblastos, células epiteliais e condrócitos [2,4,6,7] . O sucesso do uso de arcabouços em engenharia óssea depende da manutenção de uma interface apropriada à formação de tecido ósseo, visto que as propriedades de superfície, dos biomateriais e das células influenciam os eventos observados na interface célula-material resultando ou não na biocompatibilidade [8] . A modificação de superfície dos biomateriais aparece como uma alternativa para regular os eventos interfaciais sem alterar suas propriedades mecâni-cas. Neste contexto, estratégias biomiméticas vêm sendo empregadas. A principal delas consiste na imobilização de proteínas ou peptídeos biologicamente ativos na superfície de biomateriais. A adsorção de fibronectina (FN), uma das IntroduçãoAtualmente, tem sido dada muita atenção à reconstrução de ossos humanos, uma vez que, o uso de enxertos ósseos em práticas clínicas tem apresentado alguns inconvenientes, como exemplificado em [1] . A engenharia de tecidos ósseos pode, potencialmente, prover soluções para tais problemas com a utilização de arcabouços porosos temporários que tem por função sustentar e direcionar a formação do tecido ósseo [2][3][4] . A seleção do material adequado para a confecção desses arcabouços é um critério importante, pois a natureza química do material tem influência sobre sua biocompatibilidade [5] . Dentre os polímeros biodegradáveis que vêm sendo estudados para a produção de arcabouços, destaca-se o polihidroxibutirato (PHB). Trata-se de um po- Resumo: Fibronectina sérica humana foi adicionada à superfície de arcabouços de polihidroxibutirato (PHB) a fim de otimizar a adesão de osteoblastos humanos (HOB). Visando a criar sítios para a imobilização de fibronectina (FN), os arcabouços foram previamente tratados por meio de reação com etilenodiamina. O tratamento modificou a morfologia e a composição química dos arcabouços, possibilitando um aumento no teor de FN adsorvido à superfície. Imagens de AFM mostraram que as moléculas de FN assumiram conformações distintas, de acordo com a superfície na qual foi imobilizada. A FN adicionada aos arcabouços não modificados possivelmente assumiu uma conformação estendida, expondo os grupamentos RGD. Com isso, houve um aumento na adesão de HOB a estes materiais. Por outro lado, a FN na superfície dos arcabouços previamente tratados possivelmente apresentou-se na forma compacta, suprimindo a adesão de HOB. Palavras-chave:Polihidroxibutirato, engenharia óssea, biomateriais, modificação de superfície. Adsorption of Fibronectin onto Polyhydroxybutyrate Scaffolds Applied to Bone EngineeringAbstract: Human plasma fibronectin (FN) was adsorbed onto the surface of polyhydroxybutyrate (PHB) scaffolds with aim of improving adhesion of human osteoblasts (HOB). PHB scaffolds were modified via reaction with ethylenediamine in order to create sites for FN immobilization. Morphological and chemical composition changes were observed for treated scaffolds which led to an ...

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“…Compounds that are added to create pores in the gel structure are called porogens and include sucrose crystals [20], sodium chloride [30] and other salt crystals, starch [31], lipids [10] and wax particles [24]. For example, crystals of calcium salts have two functions in alginate gels: as a porogen and as reacting internal gelation agent (e.g., CaCO 3 in D-glucono-δ-lactone induced gels).…”

Section: Description and Classification Of Manufacturing Techniques Omentioning

confidence: 99%

“…Porogen-leaching. Uses a particulate porogen, such as crystals of sucrose [20,62], sodium chloride [30,63] or calcium carbonate added to the polymer solution, which are leached or dissolved after hydrogel formation.…”

Section: Oleogelsmentioning

confidence: 99%

Gels as Precursors of Porous Matrices for Use in Foods: a Review

Cuadros

Aguilera

2015

Food Biophysics

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Gelation is a structuring mechanism commonly used in foods to produce soft and homogeneous structures. Techniques applied in other areas of science (e.g., bioengineering, biotechnology and electronics) aims at producing wet and dried porous gel matrices and they may find applications in foods. This review describes several processes to manufacture porous structures such as scaffolding, ice templating, use of porogens, oleogelation, incorporation and entrapment of bubbles, enzymatic modifications, microfluidics and microfabrication techniques, among others. Several examples are also presented. Beyond textural properties, porous gels and sponges may be tailored in their mass transfer characteristics to achieve specific rates of release of bioactive molecules, nutrients and flavors.

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Preparação e caracterização de estruturas porosas de poli(3-hidroxibutirato)

Cited by 4 publications

References 7 publications

Production of 3D scaffolds applied to tissue engineering using chitosan swelling as a porogenic agent

Production of 3D scaffolds applied to tissue engineering using chitosan swelling as a porogenic agent

Adsorção de fibronectina a arcabouços de polihidroxibutirato aplicáveis à engenharia óssea

Gels as Precursors of Porous Matrices for Use in Foods: a Review

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