3D printable composites of modified cellulose fibers and conductive polymers and their use in wearable electronics

“…Treatment • Bio-compatible bio-ink assisted the cell encapsulation at 5 million cells/mL cell density. [139] carried out in the present section makes clear the emerging and cutting-edge applications of NCs as rheology modulators in the coating [117] and paint industries [118] as well as a rheology modulator for cement, [119] composites, [118,[120][121][122] electronic devices, [122][123][124][125] cosmetics, foods, [117,[126][127][128][129][130] drilling fluids, [122,131] and so forth. The superior mechanical, shear thinning, and bio-compatible/non-cytotoxic qualities of NC have also piqued researchers' attention in developing 3D bio-printing materials for creating viable living human organs/tissues.…”

“…[ 84,120–149 ] Some of the top‐notch characteristics that specifically define the distinctive rheological features of NC suspensions and their ability to act as rheology modifiers in diverse applications include their large water retention/holding potential, remarkable shear thinning behavior, their capabilities to align at high shear rates, thickening impact, and their capacity to form thixotropic frameworks that excellent restoration phenomena. The literature review carried out in the present section makes clear the emerging and cutting‐edge applications of NCs as rheology modulators in the coating [ 117 ] and paint industries [ 118 ] as well as a rheology modulator for cement, [ 119 ] composites, [ 118,120–122 ] electronic devices, [ 122–125 ] cosmetics, foods, [ 117,126–130 ] drilling fluids, [ 122,131 ] and so forth. The superior mechanical, shear thinning, and bio‐compatible/non‐cytotoxic qualities of NC have also piqued researchers' attention in developing 3D bio‐printing materials for creating viable living human organs/tissues.…”

Impact of physico‐chemical properties of nanocellulose on rheology of aqueous suspensions and its utility in multiple fields: A review

“…Treatment • Bio-compatible bio-ink assisted the cell encapsulation at 5 million cells/mL cell density. [139] carried out in the present section makes clear the emerging and cutting-edge applications of NCs as rheology modulators in the coating [117] and paint industries [118] as well as a rheology modulator for cement, [119] composites, [118,[120][121][122] electronic devices, [122][123][124][125] cosmetics, foods, [117,[126][127][128][129][130] drilling fluids, [122,131] and so forth. The superior mechanical, shear thinning, and bio-compatible/non-cytotoxic qualities of NC have also piqued researchers' attention in developing 3D bio-printing materials for creating viable living human organs/tissues.…”

“…[ 84,120–149 ] Some of the top‐notch characteristics that specifically define the distinctive rheological features of NC suspensions and their ability to act as rheology modifiers in diverse applications include their large water retention/holding potential, remarkable shear thinning behavior, their capabilities to align at high shear rates, thickening impact, and their capacity to form thixotropic frameworks that excellent restoration phenomena. The literature review carried out in the present section makes clear the emerging and cutting‐edge applications of NCs as rheology modulators in the coating [ 117 ] and paint industries [ 118 ] as well as a rheology modulator for cement, [ 119 ] composites, [ 118,120–122 ] electronic devices, [ 122–125 ] cosmetics, foods, [ 117,126–130 ] drilling fluids, [ 122,131 ] and so forth. The superior mechanical, shear thinning, and bio‐compatible/non‐cytotoxic qualities of NC have also piqued researchers' attention in developing 3D bio‐printing materials for creating viable living human organs/tissues.…”

Impact of physico‐chemical properties of nanocellulose on rheology of aqueous suspensions and its utility in multiple fields: A review

“…Degut a les seves propietats mecàniques i físiques molt notables, gràcies a la particularitat estructural i mida nano-mètrica, el fa molt interessant en àrees industrials i potencials aplicacions en productes de CNC, CNF i BC . De les dues primeres, es destaquen aplicacions per a fabricació de materials compostos com a reforç amb altres categories de materials millorant la resistència i rigidesa (Balea, Fuente, Blanco & Negro, 2019), desenvolupament de films i recobriments a través de la formació de pel•lícules primes i recobriments amb propietats barrera (Fernández-Santos, Valls, Cusola & Roncero, 2021), additius en materials per a la construcció, per millorar la seva resistència i durabilitat com a compost d'altres ceràmics, com pot ser el formigó, aplicacions biomèdiques, degut a la seva biocompatibilitat, s'utilitza com a bastides per cultius de teixits i altres materials per l'enginyeria mèdica (Immonen, Lahtinen & Pere, 2017;Kuhnt & Camarero-Espinosa, 2021;Kumar & Han, 2021;Lafuente-Merchan et al, 2022), i en electrònica flexible, degut sobretot per les seves propietats flexibles, conductivitat i transparència (Brooke, Fall, Borras, Yilma, Edberg, Martinez-Crespiera et al, 2021;Jain, Wang, Garma, Engel, Ciftci, Fager et al, 2023). En el cas particular de la BC es detallen àrees industrials i aplicacions en productes per a biotecnologia mèdica, per la seva biocompatibilitat i retenció de líquids, tan per la fabricació d'apòsits i bandatges, així com l'ús en enginyeria de regeneració de teixits i òrgans (Cai, Chang, Gan, Ma, Lu & Yen, 2022;Gona & Meyer, 2020), productes alimentaris, per la seva propietat biodegradable, com a embolcalls més sostenibles (Escursell, Llorach-Massana & Roncero, 2021), però també com a agents en els mateixos productes alimentaris, en la indústria tèxtil, per la seva resistència i flexibilitat com a fibra, per la producció de fibres tèxtils (Liu et al, 2019), materials biomèdics, igual com s'ha esmentat anteriorment, gràcies a les seves propietats bio-compatibles, en aplicacions de medicina regenerativa de cèl•lules i teixits, així com en producció de dispositius mèdics, implants i sutures (Kumar & Han, 2021), i en electrònica flexible, similar que els anteriors materials, degut a la seva alta transparència i capacitat de retenció d'aigua, s'utilitza per a dispositius flexibles com pantalles i sensors.…”

“…Val a dir però, que actualment la viabilitat de la fabricació additiva és complexa per varis motius. I així ho esmenten moltes de les publicacions recents relacionades amb la impressió 3D amb CNF,CNC i BC (Finny et al, 2021;Jain et al, 2023;Klar, Pere, Turpeinen, Karki, Orelma & Kuosmanen, 2019). Principalment perquè la imprimibilitat en 3D depèn fortament de la reologia dels materials, així com la consistència de la polimerització.…”

Research advances in Graphic and Design Engineering at the UPC BarcelonaTech

“…Notably, due to their high charge-carrier mobility, excellent thermal and chemical stability, and inherent flexibility, graphene and graphene oxide (GO) have been widely used in chemical 21 and thermal sensors, 22 micro supercapacitors, 23 film heaters 24 and other printed electronics. 25 While the main challenge in integrating carbon materials with conventional printing technologies is to produce inks suitable for various deposition processes. Large spacing exists between the graphene sheets under a low mass fraction of ink, therefore the electrons have to overcome large resistance before being transmitted between different layers.…”

Multi-scale GO/CNT/AlN nanocomposites for high-performance flexible electrothermal film heaters