Natural plant dyes offer functional properties and have been widely used in various applications. Curcumin, a compound derived from plant rhizomes, holds promise beyond its medicinal and food uses, with potential applications in biomedical auxiliary materials. However, its limited water solubility and low extraction efficiency hinder its practical use. This study aimed to enhance the water solubility of curcumin by formulating a bioactive ink and utilizing inkjet printing to deposit it onto silk fabric, thereby imparting antioxidant and antibacterial properties. We employed ultrahigh-performance liquid chromatography (UPLC) to analyze the composition of extracted curcumin derivatives and investigated the effects of cationic surfactants (CTAB) and nonionic polymers (P407) on the physical properties of curcumin solutions. The antioxidant and antibacterial activities of both homemade curcumin bioactive inks (Bio-CP inks) and curcumin derivative standards (curcumin, CUR; demethoxycurcumin, DMC; bismethoxycurcumin, BDMC) were compared. The surface structure, water binding properties, and crystalline structure of Bio-CP ink-treated silk fibers (Bio-CP@Silk) were characterized using scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS), X-ray diffraction (XRD), and differential scanning calorimetry (DSC). Our findings revealed that curcumin is a mixture of CUR, DMC, and BDMC. By pretreating silk fibers with sodium alginate (SA) and sodium carboxymethylcellulose (CMC) (SA-CMC@Silk), the fabric’s surface hydrophilicity was reduced from 60.90° to 115.2°, improving the pattern clarity during inkjet printing of Bio-CP ink. The resulting functional silk fabric (Bio-CP@Silk) demonstrated excellent antioxidant and antibacterial properties. For example, Bio-CP@Silk showed DPPH (2,2-diphenyl-1-picrylhydrazyl) scavenging rate of 69.38%, whereas in untreated silk it was only 4.82%. While the crystalline structure of Bio-CP@Silk fibers remained unchanged, the interaction between curcumin and silk fibers was strengthened, leading to improved water retention capabilities. This approach offers a novel avenue for the functional application of curcumin in silk fiber-based materials.
ReizabalACostaCMPérez-ÁlvarezLVilas-VilelaJLLanceros-MéndezS.The new silk road: Silk fibroin blends and composites for next generation functional and multifunctional materials design. Polymer Rev2023, 63: 1014–1077.
2.
SilvaASCostaECReisS, et al. Silk sericin: A promising sustainable biomaterial for biomedical and pharmaceutical applications. Polymers2022; 14: 4931.
3.
ChenKXuJYangK, et al. Highly conductive and elastic electronic silk fabrics via 3D textile macro-design and microscopic plasma activation for personal care and information interaction. Adv Fiber Mat2024; 1: 130-143.
4.
ChenKXuJZhengYLiJHongX.Three woven structures of reduced graphene oxide conductive silk fabrics prepared by two different methods for electrical setting and sensing. J Ind Text2022; 52: 152808372211444.
5.
ZhangYYeSCaoL, et al. Natural silk spinning-inspired meso-assembly-processing engineering strategy for fabricating soft tissue-mimicking biomaterials. Adv Funct Mater2022; 32: 2200267.
6.
AhmedHBEl-HawaryNSMashalyHMEmamHE.End-to-end surface manipulation of dyed silk for perfection of coloration, UV-resistance and biocidal performance. J Mol Struct2024; 1305: 137766.
7.
MahdyAMohamedMGAlyKIAhmedHBEmamHE.Liquid crystalline polybenzoxazines for manufacturing of technical textiles: Water repellency and ultraviolet shielding. Polym Testing2023; 119: 107933.
8.
EmamHEZaghloulSAhmedHB.Full ultraviolet shielding potency of highly durable cotton via self- implantation of palladium nanoclusters. Cellulose2022; 29: 4787-4804.
9.
AbdelhameedRMEl-ShahatMIvanovaEMihaylovMHadjiivanovKEmamHE.Fasten UV-resistant cotton textiles by modification with mixed metal–Ce–MOF. Fibers Polym2024; 25: 4651-4663.
10.
MaraeISSharmoukhWBakhiteEAMoustafaOSAbbadyMSEmamHE.Durable fluorescent cotton textile by immobilization of unique tetrahydrothienoisoquinoline derivatives. Cellulose2021; 28: 5937-5956.
11.
EmamHEEl-ShahatMHasaninMSAhmedHB.Potential military cotton textiles composed of carbon quantum dots clustered from 4–(2,4–dichlorophenyl)–6–oxo–2–thioxohexahydropyrimidine–5–carbonitrile. Cellulose2021; 28: 9991-10011.
12.
EmamHEAbdelhameedRMDarweshOMAhmedHB.Ln-MOF in production of durable antimicrobial and UV-Protective fluorescent cotton fabric for potential application in military textiles. Sci Rep2025; 15: 1070.
13.
SharmaVAliSW.Functionalization of cellulosic and polyester textiles using reduced Schiff base (RSB) of eco-friendly vanillin. Cellulose2023; 30: 3317–3338.
14.
RehanMEmamE-AMEmamHE.Immobilization of silver nanoparticles and silver iodide within bamboo fabrics for wastewater treatment. Sci Rep2025; 15: 11050.
15.
DoKLAhsanTWahabA, et al. Bioactive silk revolution: harnessing curcuminoid dye and chitosan for superior antimicrobial defence and UV shielding. Pharmaceutics2024; 16: 1510.
16.
BhattacharjeeARudolphSKaplanD.Thermoplastic molding of silk-curcumin sustainable composite materials with antibacterial properties. ACS Appl Bio Mater2024; 7(12): 8272–8280.
17.
ShawSMondalRDamP, et al. Synthesis, characterization and application of silk sericin-based silver nanocomposites for antibacterial and food coating solutions. RSC Adv2024; 14: 33068–33079.
18.
SharmoukhWMaraeISBakhiteEAAhmedHBEmamHE.Cutting edge for technical textiles (fluorescent, antibacterial and UV-protective) by incroporation of thienoisoquinoline-quinazoline derivatives. BMC Chem2025; 19: 173.
19.
El-KholySAHelalMHZaghloulSEmamH.In-situ hydrothermally immobilization of nano palladium for cutting-edge of multi-finishing viscose textile with enhancing the durability. J Ind Text2025; 55: 15280837251345839.
20.
AlqahtaniAMAlharbiHAlqarniSA, et al. Biopolymers blend for microwave-synthesized carbon sots and iodine entrapping for potential biomedical bandages. Fibers Polym2025; 26: 3317–3334.
21.
KasiriMBSafapourS.Natural dyes and antimicrobials for green treatment of textiles. Environ Chem Lett2014; 12: 1-13.
22.
ShahidMSalamSMohammadF.Recent advancements in natural dye applications: A review. J Clean Prod2013; 53: 310-331.
23.
ur-RehmanFAdeelSLiaqatS, et al. Environmental friendly bio-dyeing of silk using Alkanna tinctoria based Alkannin natural dye. Ind Crop Prod2022; 186: 115301.
24.
SivakumarVVijaeeswarriJAnnaJL.Effective natural dye extraction from different plant materials using ultrasound. Ind Crop Prod2011; 33: 116-122.
25.
JordevaSKertakovaMZhezhovaSGolomeova-LongurovaSMojsovK.Dyeing of textiles with natural dyes. Tekstilna Industrija2020; 68: 12-21.
26.
DevVRGVenugopalJSudhaSRamakrishnaS. Dyeing and antimicrobial characteristics of chitosan treated wool fabrics with henna dye. Carbohydr Polym2009; 75: 646-650.
27.
GrifoniDBacciLZipoliGCarrerasG.Laboratory and outdoor assessment of UV protection offered by flax and hemp fabrics dyed with natural dyes. Photochem Photobiol2009; 85: 313-320.
28.
ShiranHSBaghbanbashiMAhsaieFGPazukiG.Study of curcumin partitioning in polymer-salt aqueous two-phase systems. J Mol Liquids2020; 303: 112629.
29.
KocaadamBŞanlierN.Curcumin, an active component of turmeric (Curcuma longa), and its effects on health. Crit Rev Food Sci Nutr2017; 57: 2889-2895.
30.
AliZSaleemMAttaBKhanSSHammadG.Determination of curcuminoid content in turmeric using fluorescence spectroscopy. Spectrochim Acta A2019; 213: 192-198.
31.
JiangTGhoshRCharcossetC.Extraction, purification and applications of curcumin from plant materials - A comprehensive review. Trends Food Sci Technol2021; 112: 419-430.
32.
NabatiMMahkamMHeidariH.Isolation and characterization of curcumin from powdered rhizomes of turmeric plant marketed in Maragheh city of Iran with Soxhlet technique. Iran Chem Commun2014; 2: 236-243.
33.
DuttaB.Study of secondary metabolite constituents and curcumin contents of six different species of genus Curcuma. J Med Plants Stud2015; 3: 116-119.
34.
WangSYangZPengN, et al. Optimization of ionic liquids-based microwave-assisted hydrolysis of puerarin and daidzein derivatives from Radix puerariae Lobatae extract. Food Chem2018; 256: 149-155.
35.
RosarinaDNarawangsaDRChandraNSRSariEHermansyahH.Optimization of ultrasonic-assisted extraction (UAE) method using natural deep eutectic solvent (NADES) to increase curcuminoid yield from Curcuma longa L., Curcuma xanthorrhiza, and Curcuma mangga val. Molecules2022; 27: 6080.
36.
XuJ.WangW.LiangH.ZhangQ.Optimization of ionic liquid based ultrasonic assisted extraction of antioxidant compounds from Curcuma longa L. using response surface methodology. Ind Crop Prod2015; 76: 487-493.
37.
SahneFMohammadiMNajafpourGMoghadamniaAK. Enzyme-assisted ionic liquid extraction of bioactive compound from turmeric (Curcuma longa L.): Isolation, purification and analysis of curcumin. Ind Crop Prod2017; 95: 686-694.
38.
KiamahallehMVNajafpourGRahimnejadMMoghadamniaAK.High performance curcumin subcritical water extraction from turmeric (Curcuma longa L.). J Chromatography B2016; 1022: 191-198.
39.
RameshGKaviyilJEPaulWSasiRJosephR.Gallium-curcumin nanoparticle conjugates as an antibacterial agent against pseudomonas aeruginosa: Synthesis and characterization. ACS Omega2022; 7: 6795-6809.
40.
OglahMKMustafaYFBashirMKJasimM.Curcumin and its derivatives: A review of their biological activities. Syst Rev Pharm2020; 11: 472-481.
41.
GórnickaJMikaMWróblewskaOSiudemP.Methods to improve the solubility of curcumin from turmeric. Life2023; 13: 207.
42.
ZhangMZhangXTianT, et al. Anti-inflammatory activity of curcumin-loaded tetrahedral framework nucleic acids on acute gouty arthritis. Bioact Mater2022; 8: 368-380.
43.
Morillo-BarguesMJOsornoAOGuerriCPradasMMMartinez-RamosC.Characterization of electrospun BDMC-loaded PLA nanofibers with drug delivery function and anti-inflammatory activity. Int J Mol Sci2023; 24: 10340.
44.
TamegartLAbbaouiAEl KhiatABouyatasMMGamraniH.Lead (Pb) exposure induces physiological alterations in the serotoninergic and vasopressin systems causing anxiogenic-like behavior in Meriones shawi: Assessment of BDMC as a neuroprotective compound for Pb-neurotoxicity and kidney damages. J Trace Elem Med Biol2021; 65: 126722.
45.
LimDWSonHJUmMY, et al. Enhanced cognitive effects of demethoxycurcumin, a natural derivative of curcumin on scopolamine-induced memory impairment in mice. Molecules2016; 21: 1022.
46.
ZhouYZhangJTangR-CZhangJ.Simultaneous dyeing and functionalization of silk with three natural yellow dyes. Ind Crop Prod2015; 64: 224-232.
47.
CarvalhoJPTeixeiraMCLameirinhasNS, et al. Hydrogel bioinks of alginate and curcumin-loaded cellulose ester-based particles for the biofabrication of drug-releasing living tissue analogs. ACS Appl Mater Interf2023; 15: 40898-40912.
48.
ZhangTZhangWDengYChuY.Curcumin-based waterborne polyurethane-gelatin composite bioactive films for effective UV shielding and inhibition of oil oxidation. Food Control2022; 141: 109199.
49.
BenameurTFrota GabanSVGiacomucciG, et al. The effects of curcumin on inflammasome: Latest update. Molecules2023; 28: 742.
50.
RinkunaiteISimoliunasEAlksneMDapkuteDBukelskieneV.Anti-inflammatory effect of different curcumin preparations on adjuvant-induced arthritis in rats. BMC Complement Med Ther2021; 21: 1-12.
51.
LiGLiuHLiTWangJ.Surface modification and functionalization of silk fibroin fibers/fabric toward high performance applications. Mater Sci Eng C2012; 32: 627-636.
52.
ChenCJinSXiangX, et al. Enrichment and cytotoxic activity of curcuminoids from turmeric using macroporous resins. J Food Sci2017; 82: 2024-2030.
53.
TsengJDLeeHLYehKLLeeT.Recyclable positive azeotropes for the purification of curcumin with optimum purity and solvent capacity. Chem Eng Res Design2022; 180: 200-211.
54.
HeffernanCUkrainczykMGamidiRKHodnettBKRasmusonAC.Extraction and purification of curcuminoids from crude curcumin by a combination of crystallization and chromatography. Org Process Res Dev2017; 21: 821-826.
55.
PanYJuRCaoXPeiHZhengTWangW.Optimization extraction and purification of biological activity curcumin from Curcuma longa L by high-performance counter-current chromatography. J Sep Sci2020; 43: 1586-1592.
56.
PriyadarsiniKI.Chemical and structural features influencing the biological activity of curcumin. Curr Pharm Des2013; 19: 2093-2100.
57.
GaoCXingTHouX, et al. The influence of ink viscosity, water and fabric construction on the quality of ink-jet printed polyester. Color Technol2020; 136: 45-59.
58.
SySJiangGZhangJ, et al. A near-isotropic proton-conducting porous graphene oxide membrane. ACS Nano2020; 14: 14947-14959.
59.
LiMZhangLAnYMaWFuS.Relationship between silk fabric pretreatment, droplet spreading, and ink-jet printing accuracy of reactive dye inks. J Appl Polym Sci2018; 135: 46703.
60.
WangLDuYZhuQ, et al. Regulating the alkyl chain length of quaternary ammonium salt to enhance the inkjet printing performance on cationic cotton fabric with reactive dye ink. ACS Appl Mater Interf2023; 15: 19750-19760.
61.
LiFLiQKimuraH, et al. Morphology controllable urchin-shaped bimetallic nickel-cobalt oxide/carbon composites with enhanced electromagnetic wave absorption performance. J Mater Sci Technol2023; 148: 250-259.
62.
LiCTangQWeiH, et al. Smart wearable fluorescence sensing of bacterial pathogens and toxic contaminants by Eu3+-induced sodium alginate/Ag nanoparticle aggregates. ACS Appl Nano Mater2022; 5: 8393-8403.
63.
WangSKimMCKangOHKwonDY.The mechanism of bisdemethoxycurcumin enhances conventional antibiotics against methicillin-resistantStaphylococcus aureus. Int J Mol Sci2020; 21: 7945.
64.
NuanjohnTSuphromNNakaewN, et al. Actinomycins from soil-inhabiting Streptomyces as sources of antibacterial pigments for silk dyeing. Molecules2023; 28: 5949.
