Effects of ink characteristics and piezo-electric inkjetting parameters on lysozyme activity

Self Cite

A major number of studies used enzymes during pre-processing in the form of beads, pellets, otherwise during post-processing, for example, surface cleaning and effluent treatment. [2,3] A few studies used flat film and paper like supports, however, use of non-flat textile like surfaces for immobilization is very limited. [4] Textile fabrics can be a more suitable support for enzyme immobilization due to their inherent advantages of being strong, flexible, and lightweight, along with providing low pressure drop in chemical processes. Thus, they show potential to be used in a range of advanced applications, for example, controlled release, drug delivery, bacterial inhibition, and biosensing. [5] Such advanced application often requires highly controlled, precise, contactless, and customizable production method such as digital inkjet printing. [6] Compared to conventional production methods, for example, coating, finishing and screen printing, resource efficient inkjet technology minimizes use of water, energy, chemical and wastes of valuable functional materials, for example, enzymes. [7] Drop-on-demand (DOD) inkjet technology has been successfully used for printing of enzymes on textiles for various applications, compared to the continuous system. [8] Among two ejection mechanisms of DOD printheads, that is, thermal and piezoelectric, the latter one is preferred due to less possible influence on the protein structure of enzymes and resulting activity. [9,10] Along with printhead mechanics, inkjet printing of enzyme on textiles comes with challenges on ink recipe optimization for a specific enzyme-printhead combination and ensuring proper fabric-enzyme interaction. [11] Optimization strategy of ink-containing enzyme for rheological, ionic, and printhead parameters has been demonstrated in our previous work. [12] In this work, fabric surface characteristics necessary for efficient inkjet printing and retention of active enzymes are studied. Polyethylene terephthalate (PET) fiber based synthetic products are being used in applications ranging from apparel and home furnishing to medical textiles with rising market trend for more advanced applications. [13] This inert fiber offers superior physiochemical and mechanical properties. Nevertheless, such fibers retain challenges for printing because of their hydrophobic surface caused by lack of polar groups. Additionally, synthetic fiber surfaces may induce greater hydrophobic interaction with enzymes, for example, lysozyme to cause confirmation changes and denaturation. [14] Due to this fact, studies regarding immobilization of this enzyme on synthetic fiber Enzymes immobilized on synthetic polyethylene terephthalate (PET) textile surface by resource-efficient inkjet printing technology can promote developments for various novel applications. Synthetic fabrics often require adequate pretreatments to facilitate such printing process. This work discusses PETwoven fabric pretreatment routes to improve wettability by alkaline, enzymatic, and plasma processes for effective pri...

Section: Resultsmentioning

confidence: 93%

Section: Resultsmentioning

confidence: 99%

Section: Ink Formulation and Jettabilitymentioning

confidence: 95%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Effective Pretreatment Routes of Polyethylene Terephthalate Fabric for Digital Inkjet Printing of Enzyme

Biswas

Nierstrasz

2021

Self Cite

Effective Pretreatment Routes of Polyethylene Terephthalate Fabric for Digital Inkjet Printing of Enzyme

Biswas¹,

Yu²,

Nierstrasz³

2021

A major number of studies used enzymes during pre-processing in the form of beads, pellets, otherwise during post-processing, for example, surface cleaning and effluent treatment. [2,3] A few studies used flat film and paper like supports, however, use of non-flat textile like surfaces for immobilization is very limited. [4] Textile fabrics can be a more suitable support for enzyme immobilization due to their inherent advantages of being strong, flexible, and lightweight, along with providing low pressure drop in chemical processes. Thus, they show potential to be used in a range of advanced applications, for example, controlled release, drug delivery, bacterial inhibition, and biosensing. [5] Such advanced application often requires highly controlled, precise, contactless, and customizable production method such as digital inkjet printing. [6] Compared to conventional production methods, for example, coating, finishing and screen printing, resource efficient inkjet technology minimizes use of water, energy, chemical and wastes of valuable functional materials, for example, enzymes. [7] Drop-on-demand (DOD) inkjet technology has been successfully used for printing of enzymes on textiles for various applications, compared to the continuous system. [8] Among two ejection mechanisms of DOD printheads, that is, thermal and piezoelectric, the latter one is preferred due to less possible influence on the protein structure of enzymes and resulting activity. [9,10] Along with printhead mechanics, inkjet printing of enzyme on textiles comes with challenges on ink recipe optimization for a specific enzyme-printhead combination and ensuring proper fabric-enzyme interaction. [11] Optimization strategy of ink-containing enzyme for rheological, ionic, and printhead parameters has been demonstrated in our previous work. [12] In this work, fabric surface characteristics necessary for efficient inkjet printing and retention of active enzymes are studied.Polyethylene terephthalate (PET) fiber based synthetic products are being used in applications ranging from apparel and home furnishing to medical textiles with rising market trend for more advanced applications. [13] This inert fiber offers superior physiochemical and mechanical properties. Nevertheless, such fibers retain challenges for printing because of their hydrophobic surface caused by lack of polar groups. Additionally, synthetic fiber surfaces may induce greater hydrophobic interaction with enzymes, for example, lysozyme to cause confirmation changes and denaturation. [14] Due to this fact, studies regarding immobilization of this enzyme on synthetic fiber Enzymes immobilized on synthetic polyethylene terephthalate (PET) textile surface by resource-efficient inkjet printing technology can promote developments for various novel applications. Synthetic fabrics often require adequate pretreatments to facilitate such printing process. This work discusses PETwoven fabric pretreatment routes to improve wettability by alkaline, enzymatic, and plasma processes for effective prin...

Sequential Inkjet Printing of Lysozyme and Tyrosinase on Polyamide Fabric: Sustainable Enzyme Binding on Textile Surface

Biswas

Nierstrasz

2022

Self Cite

has been covalently bound on various fibrous materials, for example, cotton, [7] polyester (PET), [8] polyamide-6,6 (PA), [9] and wool, [10] but mostly using harsh surface binding chemicals such as glutaraldehyde. Most of these studies involved dipping the fabrics in enzyme containing solutions and lengthy incubating procedures. Amount of enzyme loading and deposition manner was less controllable. A better approach would be free from the use of harsh chemicals, minimize enzyme waste and processing time, ensure more process control, and flexibility. Lysozyme contains three tyrosine residues which tyrosinase can catalyze to covalently bind on a fibrous surface containing amino group. To the best of our knowledge, this unique approach has not been studied prior to this work, specially involving inkjet printing these two enzymes in same process. Inkjet technology ensures direct and precise deposition of biomaterials with highresolution designs for more resource efficient and flexible-scale production compared to conventional approaches, for example, screen printing and coating. However, there are fundamental differences between the working principles and manner of enzyme deposition between these technologies, thus the obtained results might not be directly comparable.Digital inkjet printing of enzymes on textile surfaces has great potential for applications ranging from bacterial inhibition to controlled drug delivery. [11] Textile surfaces can provide greater surface area for accommodating higher numbers of enzyme, along with a flexible, light-weight, and strong support medium, compared to flat film-like surfaces. Textiles made of synthetic fibers are of high industrial interest due to their physical strength, chemical inertness, recyclability, reusability, and applicability in various fields. [12] Several enzymes have been studied to include in an ink solution and optimize their activity after printing. [13] Synthetic textiles have been modified using several pretreatment techniques [14,15] to ensure proper ink adhesion, enzyme adsorption, and activity retention.Plasma pretreatment of PET and PA fabrics was found to be beneficial for inkjet printing of enzymes, replacing the needs of harsh chemical based pretreatment processes. [16][17][18][19] Plasma treatment of PA can modify its topography, increase surface energy, and introduce new functional groups. [20][21][22] Such modification can promote better adsorption of printed enzymes through their amino end groups. [23] However, a considerable amount of enzymes were rinsed away from printed fabrics An ink containing tyrosinase catalyzes the tyrosine residues on lysozyme protein to bind it on a plasma-treated polyamide-6,6 (PA) fabric. Inkjet printing enables controlled and sequential deposition of two enzymes on PA which is necessary for proper binding. The effect of different printing sequences on crosslinking stability and enzymatic activity is presented. The lysozyme bound on the fabric shows satisfactory antimicrobial activity. The printed fabric retains about 6...