Electrospinning of PCL/natural rubber blends
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Abstract
In this study, a thermoplastic/elastomeric binary blend of non-vulcanized natural rubber (NR) and polycaprolactone (PCL) was electrospun using polymer solutions consisting of varying proportions of PCL and NR. Specifically, an 8 % (w/v) NR/toluene solution was mixed with an 8 % (w/v) PCL/chloroform solution at proportions of 2, 15, 30, and 50 % (v/v). The morphological, thermal, and mechanical properties of the electrospun mats were investigated by scanning electron microscopy (SEM), differential scanning calorimetry, and uniaxial tensile tests. The SEM images demonstrated the production of micrometer- and sub-micrometer-sized fibers with no bead formation. Fibers with diameters ranging from 1.3 μm for samples with 0 % NR to 210 nm for samples containing 50 % NR were observed. Fibers with rough and smooth morphologies were observed, showing that the PCL/NR mats had phase-separated. The blend miscibility was evaluated by thermal analysis, which showed that blending did not improve the thermal stability of the systems. An investigation of the mechanical properties of the electrospun mats showed that adding NRL to the blend increased the tensile modulus, the ultimate elasticity, and the strain. Thus, non-vulcanized NR was successfully incorporated into electrospun mats, which exhibited useful mechanical properties that could be harnessed in biomaterials applications.
Keywords
Fiber Diameter Natural Rubber Natural Rubber Latex Ultimate Tensile Stress Average Fiber DiameterNotes
Acknowledgements
The authors thank Prof. E. C. Venancio (UFABC) for the high voltage source. This work was supported by CEM-UFABC, Embrapa Instrumentação Agropecuária, CNPq (471709/2012-3) and Program-CAPES Rede Nanobiotec-Brasil (Edital CAPES04/CII-2008).
References
- 1.Ayres CE, Jha BS, Sell SA, Bowlin GL, Simpson DG (2010) Wiley Interdiscip Rev Nanomed Nanobiotechnol 2:20CrossRefGoogle Scholar
- 2.Pham QP, Sharma U, Mikos AG (2006) Tissue Eng 12:1197CrossRefGoogle Scholar
- 3.Zander NE, Orlicki JA, Rawlett AM, Beebe TP (2013) J Mater Sci Mater Med 24:179CrossRefGoogle Scholar
- 4.Balguid A, Mol A, van Marion MH, Bank RA, Bouten CVC, Baaijens FPT (2009) Tissue Eng Part A 15:437CrossRefGoogle Scholar
- 5.Zhang H, Lou SF, Williams GR, Branford-White C, Nie HL, Quan J, Zhu LM (2012) Int J Pharm 439:100CrossRefGoogle Scholar
- 6.Ma ZW, Kotaki M, Ramakrishna S (2005) J Membr Sci 265:115CrossRefGoogle Scholar
- 7.Yoshimatsu K, Ye L, Lindberg J, Chronakis IS (2008) Biosens Bioelectron 23:1208CrossRefGoogle Scholar
- 8.Son WK, Youk JH, Park WH (2006) Carbohydr Polym 65:430CrossRefGoogle Scholar
- 9.Taepaiboon P, Rungsardthong U, Supaphol P (2007) Eur J Pharm Biopharm 67:387CrossRefGoogle Scholar
- 10.Sant S, Hwang CM, Lee SH, Khademhosseini A (2011) J Tissue Regen Med 5:283CrossRefGoogle Scholar
- 11.Borg E, Frenot A, Walkenstrom P, Gisselfalt K, Gretzer C, Gatenholm P (2008) J Appl Polym Sci 108:491CrossRefGoogle Scholar
- 12.Frade MAC, Valverde RV, de Assis RVC, Coutinho-Netto J, Foss NT (2001) Int J Dermatol 40:238CrossRefGoogle Scholar
- 13.Neves WFP, Graeff CFD, Ferreira M, Mulato M, Bernardes MS, Coutinho-Netto J (2006) J Appl Polym Sci 100:702CrossRefGoogle Scholar
- 14.Neves-Junior WFP, Ferreira M, Alves MCO, Graeff CFO, Mulato M, Coutinho-Netto J, Bernardes MS (2006) Braz J Phys 36:586CrossRefGoogle Scholar
- 15.Davi CP, Galdino LFMD, Borelli P, Oliveira ON Jr, Ferreira M (2012) J Appl Polym Sci 125:2137CrossRefGoogle Scholar
- 16.Mendonca RJ, Mauricio VB, Teixeira LD, Lachat JJ, Coutinho-Netto J (2010) Phytother Res 24:764Google Scholar
- 17.Sithornkul S, Threepopnatkul P (2009) In: Yin YS, Wang X (eds) Multi-functional materials and structures II, Pts 1 and 2., p 1583Google Scholar
- 18.Tarachiwin L, Sakdapipanich J, Ute K, Kitayama T, Tanaka Y (2005) Biomacromolecules 6:1858CrossRefGoogle Scholar
- 19.Rippel MM, Leite CAP, Lee LT, Galembeck F (2005) Colloid Polym Sci 283:570CrossRefGoogle Scholar
- 20.Sansatsadeekul J, Sakdapipanich J, Rojruthai P (2011) J Biosci Bioeng 111:628CrossRefGoogle Scholar
- 21.Magalhães ASG, Feitosa JPdA (1999) Polimeros 9:65CrossRefGoogle Scholar
- 22.Ferreira M, Mendonça RJ, Coutinho-Netto J, Mulato M (2009) Braz J Phys 39:564CrossRefGoogle Scholar
- 23.Kim GH, Shin HG, Cho WJ, Ha CS (2002) J Appl Polym Sci 86:1071CrossRefGoogle Scholar
- 24.Kolarik J, Fambri L, Slouf M, Konecny D (2005) J Appl Polym Sci 96:673CrossRefGoogle Scholar
- 25.Kweon H, Yoo MK, Park IK, Kim TH, Lee HC, Lee HS, Oh JS, Akaike T, Cho CS (2003) Biomaterials 24:801CrossRefGoogle Scholar
- 26.Martins MA, Moreno RMB, McMahan CM, Brichta JL, Gonçalves PdS, Mattoso LHC (2008) Thermochim Acta 474:62CrossRefGoogle Scholar
- 27.Campos A, Marconcini JM, Martins-Franchetti SM, Mattoso LHC (2012) Polym Degrad Stab 97:1948CrossRefGoogle Scholar
- 28.Kaavessina M, Ali I, Elleithy RH, Al-Zahrani SM (2012) J Polym Res 19:9818CrossRefGoogle Scholar
- 29.de Oliveira LCS, de Arruda EJ, da Costa RB, Gonçalves PS, Delben A (2003) Thermochim Acta 398:259CrossRefGoogle Scholar
- 30.Tammaro L, Russo G, Vittoria V (2009) J Nanomater 2009:1CrossRefGoogle Scholar
- 31.Lizymol PP, Thomas S (1993) Polym Degrad Stab 41:59CrossRefGoogle Scholar
- 32.Del Gaudio C, Bianco A, Folin M, Baiguera S, Grigioni M (2009) J Biomed Mater Res 89A:1028CrossRefGoogle Scholar