JoVE Journal > Bioengineering
Summary
Abstract
Introduction
Protocol
Resultados
Discussion
Declarações
Acknowledgements
Materials
Referências
Tadução automática
Bioengenharia

Fabricação de super-hidrofóbicas Materiais Poliméricos para aplicações biomédicas

Published: August 28, 2015
doi:
10.3791/53117
,
1Department of Biomedical Engineering,Boston University, 2Departments of Biomedical Engineering, Chemistry, and Medicine,Boston University

Summary

Two- and three-dimensional superhydrophobic polymeric materials are prepared by electrospinning or electrospraying biodegradable polymers blended with a lower surface energy polymer of similar composition.

Abstract

Materiais hidrofóbicas, com superfícies que possuam Estados não-permanentes molhada ou metaestáveis, são de interesse para um número de aplicações biomédicas e industriais. Aqui descrevemos como electrospinning electrospraying ou uma mistura contendo um polímero biodegradável, biocompatível poliéster alifático (por exemplo, policaprolactona e poli (lactido-co -glycolide)), como o componente principal, dopado com um copolímero hidrofóbico composto do poliéster e uma stearate- poli modificadas (carbonato de glicerol) proporciona um biomaterial hidrofóbicas. As técnicas de fabricação de electrospinning ou electrospraying proporcionar a rugosidade da superfície reforçada e porosidade no e no interior das fibras ou das partículas, respectivamente. A utilização de um copolímero de baixa energia de superfície dopante que se mistura com o poliéster e pode ser estavelmente ou electrospun electrosprayed proporciona estes materiais hidrofóbicas. Os parâmetros importantes, tais como o tamanho da fibra, composição de copolímero de dopante e / ou concentration, e os seus efeitos sobre a capacidade de humedecimento são discutidos. Esta combinação de química de polímeros e engenharia de processo proporciona um método versátil para desenvolver materiais específicos da aplicação usando técnicas escaláveis, que são susceptíveis generalizáveis ​​a uma classe mais ampla de polímeros para uma variedade de aplicações.

Introduction

Superfícies hidrofóbicas são geralmente classificados como apresentando aparente contato com a água ângulos superiores a 150 ° com ângulo de contacto baixo histerese. Estas superfícies são fabricadas mediante a introdução de alta rugosidade da superfície em materiais de baixa energia de superfície para estabelecer uma interface ar-líquido-sólido resultante que resiste à molhagem 1-6. Dependendo do método de fabricação, ou várias camadas finas superfícies hidrofóbicas, revestimentos em camadas múltiplas de substratos hidrofóbicas, ou estruturas hidrofóbicas, mesmo a granel pode ser preparado. Este repelência permanente ou semi-permanente de água é uma propriedade útil que é utilizado na preparação de superfícies auto-limpantes, 7 microcanais 8, anti-incrustantes superfícies de células / proteína 9,10, superfícies de redução de arrasto 11, e dispositivos de entrega de drogas 12- 15. Recentemente, estímulos materiais sensíveis hidrofóbicas são descritos em que a não-humedecido para estado molhado é desencadeada por agentes químicos, físicosOu estímulos ambientais (por exemplo, luz, pH, temperatura, ultra-som e aplicado potencial eléctrico / corrente) 14,16-20, e estes materiais estão encontrando uso em aplicações adicionais 21-25.

As primeiras superfícies hidrofóbicas sintéticas foram preparados por tratamento de superfícies de materiais com methyldihalogenosilanes 26, e eram de valor limitado para aplicações biomédicas, como os materiais utilizados não eram adequados para a utilização in vivo. Aqui, descrevemos a preparação de superfície e materiais hidrofóbicas em massa a partir de polímeros biocompatíveis. A nossa abordagem implica electrospinning electrospraying ou uma mistura de polímeros contendo, um poliéster alifático biodegradável e biocompatível como o componente principal, dopado com um copolímero hidrofóbico composto do poliéster e um poli (carbonato de glicerol) modificado com estearato de 27-30. As técnicas de fabricação de proporcionar a rugosidade da superfície e a porosidade melhorada e dentro do fibeRS ou as partículas, respectivamente, enquanto o uso de um dopante copolímero proporciona um polímero de baixa energia superficial que se mistura com o poliéster e pode ser estavelmente ou electrospun electrosprayed 27,31,32.

Poliésteres alifáticos biodegradáveis, tais como poli (ácido láctico) (PLA), poli (ácido glicólico) (PGA), poli (ácido láctico ácido-co -glycolic) (PLGA) e policaprolactona (PCL) polímeros são utilizados em dispositivos clinicamente aprovados e proeminente na pesquisa biomédica materiais por causa de sua não-toxicidade, biodegradabilidade e facilidade de síntese 33. PGA e PLGA estreou na clínica como suturas reabsorvíveis na década de 1960 e início dos anos 1970, respectivamente 34-37. Desde então, estes poli (hidroxiácidos) tenham sido transformados em uma variedade de outros fatores de forma específicas de aplicativos, tais como micro e nanopartículas 40,41 38,39, bolachas / 42 discos, malhas 27,43, espumas 44, e 45 filmes </sup>.

Poliésteres alifáticos, bem como outros polímeros de interesse biomédico, pode ser electrospun para produzir nano- ou de malha de microfibras estruturas possuindo uma elevada área superficial e a porosidade, bem como a resistência à tracção. A Tabela 1 lista o electrospun polímeros sintéticos para diversas aplicações biomédicas e os seus correspondentes referências. Electrospinning e electrospraying são técnicas rápidas e comercialmente escaláveis. Estas duas técnicas semelhantes confiar na aplicação de alta tensão (repulsão electrostática) para vencer a tensão superficial de uma solução de polímero / derreter numa configuração de bomba de seringa em que é dirigido para um alvo ligado à terra 46,47. Quando esta técnica é utilizada em conjunção com polímeros de baixa energia superficial (polímeros hidrófobos, tais como poli (co caprolactone- -glicerol monoestearato)), o superhydrophobicity materiais exibem resultante.

Para ilustrar esta abordagem geral de processamento de materiais sintéticos epara a construção de polímeros de materiais biomédicos hidrofóbicas, que descrevem a síntese de polycaprolactone- hidrofóbicas e poli (lactido-co -glycolide) baseados em materiais como exemplos representativos. O respectivo poli dopantes copolímero (co caprolactone- -glicerol monoestearato) e poli (lactido-co-glicerol monoestearato) são sintetizados em primeiro lugar, em seguida, misturado com policaprolactona e poli (lactido-co -glycolide), respectivamente, e, finalmente, electrospun ou electrosprayed. Os materiais resultantes são caracterizados por SEM de imagem e o ângulo de contacto goniometria, e testados de vitro e in vivo em biocompatibilidade. Finalmente, molhamento massa através de malhas hidrofóbicas tridimensionais é examinada por meio de tomografia microcomputed com contraste.

Protocol

1. Sintetização functionalizable poli (1,3-glicerol carbonate- co-caprolactona) e 29 de poli (1,3-glicerol -lactide carbonate- co) 27,28. A síntese de monómeros. Dissolver cis-2-fenil-1,3-dioxan-5-ol (50 g, 0,28 mol, 1 eq.) Em 500 ml de tetra-hidrofurano seco (THF) e agita-se em gelo sob atmosfera de azoto. Adiciona-se hidróxido de potássio (33,5 g, 0,84 mol, 3 eq.), Finamente trituradas com um almofariz e pilão. Coloque balão em banho de gelo….

Representative Results

Através de uma série de transformações químicas, o monómero funcional carbonato de 5-benziloxi-1,3-dioxan-2-ona é sintetizada na forma de um sólido cristalino branco (Figura 1A). 1H RMN confirma a estrutura (Figura 1B) e a espectrometria de massa e análise elementar confirma a composição. Este sólido é então copolimerizado com qualquer um de D, L ou -lactide ε-caprolactona usando uma reacção de abertura do anel catalisada-estanho a 140 ° C. Após pu…

Discussion

Nossa abordagem para a construção de materiais hidrofóbicas a partir de polímeros biomédicos combina química polímero sintético com as técnicas de processamento de polímeros de eletrofiação e electrospraying. Estas técnicas proporcionam tanto fibras ou partículas, respectivamente. Especificamente, policaprolactona e poli (lactido-co -glycolide) baseado materiais hidrofóbicas são preparados usando esta estratégia. Através da variação da composição de copolímero hidrófobo, por cento de cop…

Declarações

The authors have nothing to disclose.

Acknowledgements

Funding was provided in part by BU and the NIH R01CA149561. The authors wish to thank the electrospinning/electrospraying team including Stefan Yohe, Eric Falde, Joseph Hersey, and Julia Wang for their helpful discussions and contributions to the preparation and characterization of superhydrophobic biomaterials.

Materials

Silicone oil Sigma-Aldrich 85409
Cis-2-Phenyl-1,3-dioxan-5-ol Sigma-Aldrich 13468
Benzyl bromide Sigma-Aldrich B17905 Toxic, lacrymator/eye irritant, use in chemical fume hood
Potassium hydroxide Sigma-Aldrich 221473 Corrosive
Rotary evaporator Buchi R-124
High-vacuum pump Welch 8907
Nitrogen, ultra high purity Airgas NI UHP300 Compressed gas
Tetrahydrofuran, stabilized with BHT Pharmaco-Aaper 346000 Flammable. Dried through column of XXX
Dichloromethane Pharmaco-Aaper 313000 Flammable, toxic.
Separatory funnel (1 L) Fisher Scientific 13-678-606
Sodium sulfate Sigma-Aldrich 239313
Ethanol, absolute Pharmaco-Aaper 111USP200 Flammable, toxic.
Buchner funnel Fisher Scientific FB-966-F
Methanol Pharmaco-Aaper 339000ACS Flammable, toxic.
Hydrochloric acid Sigma-Aldrich 320331 Corrosive. Diluted to 2N in distilled water.
Ethyl chloroformate, 97% Sigma-Aldrich 185892 Toxic, flammable, harmful to environment
Triethylamine (anhydrous) Sigma-Aldrich 471283 Toxic, flammable, harmful to environment
Diethyl ether Pharmaco-Aaper 373ANHACS Highly flammable. Purified through XXX column.
3,6-Dimethyl-1,4-dioxane-2,5-dione (D,L-lactide) Sigma-Aldrich 303143
Tin (II) ethylhexanoate Sigma-Aldrich S3252 Toxic.
ε-caprolactone (97%) Sigma-Aldrich 704067
Toluene, anhydrous Sigma-Aldrich 244511 Flammable, toxic.
Glass syringe Hamilton Company 1700-series
Deuterated chloroform Cambridge Isotopes Laboratories, Inc. DLM-29-10 Toxic
Nuclear magnetic resonance instrument Varian V400
Palladium on carbon catalyst Strem Chemicals, Inc. 46-1707
Hydrogenator unit Parr 3911
Hydrogenator shaker vessel Parr 66CA
Hydrogen Airgas HY HP300 Highly flammable.
Diatomaceous earth Sigma-Aldrich 22140
2H,2H,3H,3H-perflurononanoic acid Oakwood Products, Inc. 10519 Toxic.
Stearic acid Sigma-Aldrich S4751
N,N’-dicyclohexylcarbodiimide Sigma-Aldrich D80002 Toxic, irritant.
4-(dimethylamino) pyridine Sigma-Aldrich 107700 Toxic.
Hexanes Pharmaco-Aaper 359000ACS Toxic, flammable.
Gel permeation chromatography (GPC) system Rainin
GPC column Waters WAT044228
Differential scanning calorimeter TA Instruments Q100
Chloroform Pharmaco-Aaper 309000ACS Toxic.
N,N-dimethylformamide Sigma-Aldrich 227056 Toxic, flammable.
Polycaprolactone, MW 70-90 kg/mol Sigma-Aldrich 440744
Poly(lactide-co-glycolide), MW 136 kg/mol Evonik Industries LP-712
10-mL glass syringe Hamilton Company 81620
18 AWG blunt needle BRICO Medical Supplies BN1815
Electrospinner enclosure box Custom-built N/A Made of acrylic panels
High voltage DC supply Glassman High Voltage, Inc. PS/EL30R01.5 High voltages, electrocution hazard
Linear (translating) stage Servo Systems Co. LPS-12-20-0.2 Optional
Programmable motor & power supply Intelligent Motion Systems, Inc. MDrive23 Plus Optional
24V DC motor & power supply McMaster-Carr 6331K32 Optional
Aluminum collector drum Custom-built Optional
Syringe pump Fisher Scientific 78-0100I
Inverted optical microscope Olympus IX70
Scanning electron microscope Carl Zeiss Supra V55
Conductive copper tape 3M 16072
Aluminum SEM stubs Electron Microscopy Sciences 75200
Contact angle goniometer Kruss DSA100
Propylene glycol Sigma-Aldrich W294004 Toxic.
Ethylene glycol Sigma-Aldrich 324558 Toxic.
Ioxaglate Guerbet
Fetal bovine serum American Type Culture Collection 30-2020
Micro-computed tomography instrument Scanco
Image analysis software (Analyze) Mayo Clinic
Tensile tester Instron 5848
Micrometer Multitoyo 293-340
Calipers Fisher Scientific 14-648-17
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SuperhydrophobicPolymeric MaterialsBiomedical ApplicationsElectrospinningElectrosprayingPolycaprolactonePoly(lactide-co-glycolide)Stearate-modified Poly(glycerol Carbonate)Surface RoughnessPorosityWettabilityPolymer ChemistryProcess EngineeringScalable Techniques
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Kaplan, J., Grinstaff, M. Fabricating Superhydrophobic Polymeric Materials for Biomedical Applications. J. Vis. Exp. (102), e53117, doi:10.3791/53117 (2015).
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