The present work developed keratin-based pH-sensitive nanofibers and explored the kinetics of the controlled-release effect. Extracted from wool fibers, keratin was firstly synthesized with 5- fluorouracil (5-FU). Then 5-FU/keratin was blended with poly (L-Lactide) PLLA solution and electrospun altogether to fabricate a nanofibrous scaffold, for local tumor chemotherapy. 5-FU/keratin/PLLA nanofibrous scaffolds were characterized by Fourier transform infrared spectroscopy to confirm that 5-FU was loaded within the nanofibers successfully. Scanning electron microscopy and transmission electron microscope images indicated the smooth and uniform structure of the nanofibers. Thermo-gravimetric analysis differential scanning calorimeter and X-ray diffraction techniques indicated 5-FU particles distributed in nanofibers at a molecular level. Compared with 5-FU from pure drug and 5-FU/PLLA nanofibers without keratin, the dissolution results indicated that 5- FU/keratin/PLLA nanofibers had a pH-stimuli responsive character in the acidic environment. HCT-116 tumor cell line was applied to investigate the antitumor effect of the composite nanofibers. The MTS assay indicated that adding keratin into the system increased the inhabitation of tumor cells after 120 hours observation. Zeta potential analysis was introduced to analyze the interaction effect between 5-FU and keratin. The in vitro drug release kinetics analysis indicated that due to the electrostatic interaction between keratin and 5-FU molecules, the composite nanofibers can extend the release period of 5-FU in the acidic environment which suggested a longer effective inhibition in local tumor chemotherapy.
BinnewiesMRobertsEWKerstenK, et al.Understanding the tumor immune microenvironment (TIME) for effective therapy. Nat Med2018; 24: 541–550.
2.
WetterstenHIWeisSMPathriaP, et al.Arming tumor-associated macrophages to reverse epithelial cancer progression. Cancer Res2019; 79: 5048–5059.
3.
KankalaRKLiuC-GYangD-Y, et al.Ultrasmall platinum nanoparticles enable deep tumor penetration and synergistic therapeutic abilities through free radical species-assisted catalysis to combat cancer multidrug resistance. Chem Eng2020; 383: 123138–123138.
4.
LimZZJLiJEJNgCT, et al.Gold nanoparticles in cancer therapy. Acta Pharmacol Sin2011; 32: 983–990.
5.
AriyanCEBradyMSSiegelbaumRH, et al.Robust antitumor responses result from local chemotherapy and CTLA-4 blockade. Cancer Immunol Res2018; 6: 189–200.
6.
KlecknerIRKamenCGewandterJS, et al.Effects of exercise during chemotherapy on chemotherapy-induced peripheral neuropathy: a multicenter, randomized controlled trial. Support Care Cancer2018; 26: 1019–1028.
7.
O’LearyCECollinsAHenmanMC, et al.Introduction of a dose-banding system for parenteral chemotherapy on a haematology–oncology day ward. J Oncol Pharm Pract2019; 25: 351–361.
8.
RibaLAGrunerRAFleishmanA, et al.Surgical risk factors for the delayed initiation of adjuvant chemotherapy in breast cancer. Ann Surg Oncol2018; 25: 1904–1911.
9.
LiuWWeiJWeiY, et al.Controlled dual drug release and in vitro cytotoxicity of electrospun poly (lactic-co-glycolic acid) nanofibers encapsulated with micelles. J Biomed Nanotechnol2015; 11: 428–435.
10.
IgnatovaMGManolovaNERashkovIB, et al.Poly (3-hydroxybutyrate)/caffeic acid electrospun fibrous materials coated with polyelectrolyte complex and their antibacterial activity and in vitro antitumor effect against HeLa cells. Mater Sci Eng C2016; 65: 379–392.
11.
HaidarMKErogluH. Nanofibers: new insights for drug delivery and tissue engineering. Curr Top Med Chem2017; 17: 1564–1579.
12.
LiQZhuLLiuR, et al.Biological stimuli responsive drug carriers based on keratin for triggerable drug delivery. J Mater Chem2012; 22: 19964–19973.
13.
SağiraTHuysalbMDurmuscZ, et al.Preparation and in vitro evaluation of 5-fluorouracil loaded magnetite–zeolite nanocomposite (5-FU-MZNC) for cancer drug delivery applications. Biomed Pharmacother2016; 77: 182–190.
14.
NagarwalRCKumarRPanditJK. Chitosan coated sodium alginate–chitosan nanoparticles loaded with 5-FU for ocular delivery: In vitro characterization and in vivo study in rabbit eye. Eur J Pharm Sci2012; 47: 678–685.
15.
PrabhaGRajV. Formation and characterization of β-cyclodextrin (β-CD) – polyethyleneglycol (PEG) – polyethyleneimine (PEI) coated Fe3O4 nanoparticles for loading and releasing 5-Fluorouracil drug. Biomed Pharmacother2016; 80: 173–182.
16.
ChungaT-WLindS-YLiubDZ, et al.Sustained release of 5-FU from Poloxamer gels interpenetrated by crosslinking chitosan network. Int J Pharm2009; 382: 39–44.
17.
IdrisAVijayaraghavanRRanaUA, et al.Dissolution of feather keratin in ionic liquids. Green Chem2013; 15: 525–534.
18.
ChoiJPanthiGLiuY, et al.Keratin/poly (vinyl alcohol) blended nanofibers with high optical transmittance. Polymer2015; 58: 146–152.
19.
DowlingLMCrewtherWGParryDAD. Secondary structure of component 8c-1 of α-keratin. An analysis of the amino acid sequence. Biochem J1986; 236: 705–712.
20.
AluigiAZoccolaMVineisC, et al.Study on the structure and properties of wool keratin regenerated from formic acid. Int J Biol Macromol2007; 41: 266–273.
21.
ZhangJLiYLiJ, et al.Isolation and characterization of biofunctional keratin particles extracted from wool wastes. Powder Technol2013; 246: 356–362.
22.
KattiDSRobinsonKWKoFK, et al.Bioresorbable nanofiber-based systems for wound healing and drug delivery: Optimization of fabrication parameters. J Biomed Mater Res B2004; 70: 286–296.
23.
BhattaraiSRBhattaraiNYiHK, et al.Novel biodegradable electrospun membrane: Scaffold for tissue engineering. Biomaterials2004; 25: 2595–2602.
24.
KimTGParkTG. Surface functionalized electrospun biodegradable nanofibers for immobilization of bioactive molecules. Biotechnol Prog2006; 22: 1108–1113.
25.
ZhangJLiYLiJ, et al.Generation of biofunctional and biodegradable electrospun nanofibers composed of poly (l-lactic acid) and wool isoelectric precipitate. Text Res J2014; 84: 355–367.
26.
WangXLvFLiT, et al.Correction to electrospun micropatterned nanocomposites incorporated with Cu2S nanoflowers for skin tumor therapy and wound healing. ACS Nano2019; 13: 3740–3740.
27.
NorouziM. Recent advances in brain tumor therapy: application of electrospun nanofibers. Drug Discov Today2018; 23: 912–919.
28.
WangMXiaoYLinL, et al.A microfluidic chip integrated with hyaluronic acid-functionalized electrospun chitosan nanofibers for specific capture and nondestructive release of CD44-overexpressing circulating tumor cells. Bioconjugate Chem2018; 29: 1081–1090.
29.
RadmansouriMBahmaniESarikhaniE, et al.Doxorubicin hydrochloride-loaded electrospun chitosan/cobalt ferrite/titanium oxide nanofibers for hyperthermic tumor cell treatment and controlled drug release. Int J Biol Macromol2018; 116: 378–384.
30.
LiXYangYFanY, et al.Biocomposites reinforced by fibers or tubes as scaffolds for tissue engineering or regenerative medicine. J Biomed Mater Res A2014; 102: 1580–1594.
31.
NairLSLaurencinCT. Biodegradable polymers as biomaterials. Prog Polym Sci2007; 32: 762–798.
32.
ChenB-QKankalaRKChenA-Z, et al.Investigation of silk fibroin nanoparticle-decorated poly (l-lactic acid) composite scaffolds for osteoblast growth and differentiation. Int J Nanomedicine2017; 12: 1877–1877.
33.
RasouliRBarhoumABechelanyM, et al.Nanofibers for biomedical and healthcare applications. Macromol Biosci2019; 19: 1800256–1800256.
34.
CaiXLuanYDongQ, et al.Sustained release of 5-fluorouracil by incorporation into sodium carboxymethylcellulose sub-micron fibers. Int J Pharm2011; 419: 240–246.
35.
El-KhoueiryABLenzHJ. Should continuous infusion 5-fluorouracil become the standard of care in the USA as it is in Europe?Cancer Invest2006; 24: 50–55.
36.
NistorMTChiriacAPNitaLE, et al.Characterization of the semi-interpenetrated network based on collagen and poly(N-isopropyl acrylamide-co-diethylene glycol diacrylate). Int J Pharm2013; 452: 92–101.
37.
ChenSCHuangXBCaiXM, et al.The influence of fiber diameter of electrospun poly(lactic acid) on drug delivery. Fiber Polym2012; 13: 1120–1125.
38.
ZhangJLiYLiJ, et al.Generation of biofunctional and biodegradable electrospun nanofibers composed of poly (L-lactic acid) and wool isoelectric precipitate. Text Res J2014; 84: 355–367.
39.
GreenwoodR. Review of the measurement of zeta potentials in concentrated aqueous suspensions using electroacoustics. Adv Colloid Interface Sci2003; 106: 55–81.
