Younsook Shin

Antimicrobial finishing of polypropylene nonwoven fabric by treatment with chitosan oligomer

Water-soluble chitosan oligomer was prepared for finishing polypropylene nonwoven fabrics to impart antimicrobial activity. The weight average molecular weight was 1814 and its degree of deacetylation was 84%. Polypropylene nonwoven fabrics were treated with chitosan oligomer solution by the pad-dry method. Antimicrobial activity was measured by the shake flask method. The chitosan oligomer showed high antimicrobial activities against Proteus vulgaris, Staphylococcus aureus, and Escherichia coli at 0.01% and 0.05% level, respectively, showing above 90% of reduction rate. Chitosan oligomer was the most effective against Proteus vulgaris. However, it was not effective against Klebsiella pneumoniae and Pseudomonas aeruginosa below the treatment concentration of 1.0%. Fabrics became stiffer and less air permeable with the increase of treatment concentration. Tensile strength of the treated samples was lower than that of the untreated one. Liquid strike-through time of the sample treated with 0.5% chitosan oligomer solution (3.0 s) was comparable with that of a hydrophilic finished sample available commercially (2.6 s).

Use of Chitosan to improve dyeability of DP-finished cotton (II)

Chitosan was used to improve the dyeability of DP-finished cotton. Cotton fabric was treated with a mixture of chitosan, 4,5-dihydroxy-1,3-dimethyl-2-imidazolidinone (DHDMI), and catalyst in a one-step process. To investigate the effect of molecular weight of chitosan on the dyeability of treated fabrics, six chitosan samples of different molecular weights were prepared by depolymerization with sodium nitrite; 185,300, 73,200, 59,000, 21,000, 14,000, and 3,800, respectively. Chitosan improves dye uptake of direct and acid dyes considerably, and the dye uptake increases with the increase of the molecular weight of chitosan. Reactive dye uptake increases slightly in alkaline condition as the molecular weight of chitosan decreases. Higher dye uptake is obtained in acidic condition than in alkaline condition. Chitosan treatment has no discernable effect on the colorfastness to washing, but decreases the colorfastness to wet crocking by about half a point. And chitosan affects other properties of treated fabric; lower wrinkle recovery, stiffer handle, and higher breaking strength as the molecular weight of chitosan increases.

Dyeing Properties and Color of Silk Fabrics Dyed with Safflower Yellow Dye

The objective of this study is to investigate the dyeing properties of safflower yellow dye on silk for the standardization of dyeing process and color reproducibility. Yellow colorants were water-extracted from safflower petals, concentrated, and freeze-dried to obtain colorants powder. The effects of dye concentration, dyeing temperature, and pH of dye bath were studied in terms of dye uptake and shade. Fastness to dry cleaning and light was evaluated. Dye uptake increased with raising temperature and brighter and more vivid yellow shade was obtained when dyed at . As colorants concentration increased, dye uptake increased progressively and the shade got darker and deeper. Maximum color strength was obtained at pH 3.5. It was speculated that the adsorption of colorants seemed to occur mainly by hydrogen bonding and physical force at pH 5.5 and by ionic bonding as well as hydrogen bonding below isoelectric point(pH 3.8-4.0). The results of reproducibility test showed acceptable color difference in the range of . Washing fastness was fairly good as 4/5 rating, while light fastness was 2/3 rating.

Tencel Dyeing by Natural Indigo Prepared from Dyer`s Knotweed

Natural indigo dye in powder form was prepared by modifying traditional Niram method, using instead of baked oyster powder for precipitating indigo dye. The prepared dye was applied to dyeing Tencel fabrics to investigate the effect of experimental conditions for the optimization of dyeing process. The indigo dye powder contained 15.2%(w/w) of indigo content and 0.757%(w/w) of indirubin content on the basis of HPLC analysis. Maximum dye uptake was obtained at for 20min. Almost saturated dye uptake was obtained at 2g/L of sodium hydrosulfite concentration up to 4g/L of indigo dye and then slowly increased for further increase of sodium hydrosulfite. Whereas at higher indigo dye concentration(8g/L) more than 3g/L of reducing agent concentration was required for obtaining the maximum dye uptake. At the same indigo dye and reducing agent concentration, K/S value of the sample dyed without sodium hydroxide(pH 5.75) was 15.19, much higher than one dyed in alkaline condition(K/S 5.76). There was no difference in colorfastness ratings among samples with different color strength. However, more fading was occurred for the sample with low color strength.

Structural changes in Tencel by enzymatic hydrolysis

The NaOH-, fibrillation-, and cellulase- treated Tencel fabrics were characterized by weight loss, tensile strength, scanning electron microscopy (SEM) analysis, X-ray diffraction analysis, measurements of moisture regain and dye adsorption (K/S value), degree of polymerization (DP), and copper number. Weight loss increased and tensile strength decreased with increase in cellulase concentration and treatment time. At a similar weight loss, tensile strength retentions of the NaOH-pretreated samples were better than those of the NaOH-nontreated samples because of more uniform enzymatic hydrolysis. SEM photographs showed more surface peeling and interfibrillar splitting as enzymatic hydrolysis progressed. Crystalline structure and degree of crystallinity were not much changed by cellulase treatment. As enzymatic hydrolysis progressed, moisture regain and K/S value increased slightly due to increase of specific surface area by fibrils. DP initially decreased as enzymatic hydrolysis progressed and then leveled off. Copper number increased largely at an initial stage of degradation and then decreased gradually. The NaOH-pretreated samples showed higher degree of crystallinity, DP, moisture regain, and K/S value, but lower copper number than the NaOH-nontreated ones. These results were attributed to extraction of short chain molecules in the amorphous region during NaOH pretreatment and change of amorphous region into the open-up structure.

Natural Indigo Dyeing of Cotton Fabric - One-step reduction/dyeing process -

The objective of this study is to investigate the characteristics of natural indigo dyeing of cotton fabric. Reduction and dyeing were carried out by one-step process using an infrared dyeing machine at the liquor ratio of 1:100, and subsequently oxidation and washing in water were followed. Dye uptake was increased with the increase of indigo concentration. Over the full range of dyeing tests, the dyeing condition was optimized to 40℃ for 40min. For most of dye concentrations, the cotton fabrics showed mainly PB color. Maximum K/S value was shown at 4g/L of sodium hydrosulfite concentration and the color strength increased with the increase of dye concentration. Value(lightness) decreased with the increase of dye uptake irrespective of mercerization or reduction method, while the mercerized cotton showed two times higher dye uptake than the untreated cotton. Whereas hue of the untreated cotton showed large decrease of P character(5.6~3.5 PB) with the increase of dye uptake, that of the mercerized cotton increased P character(4.7~5.5 PB). Irrespective of mercerization, value and chroma decreased with the increased of dye uptake. In addition, the untreated showed lower chroma than the mercerized cotton. In the case of traditional reduction, hue of the untreated cotton was changed very little with the increase of dye uptake. For hydrosulfite reduction, P character decreased with the increase of dye uptake. The difference of hue value was small with the change of reduction method(hydrosulfite reduction or traditional fermentation). Color character was not influenced by the changed maximum absorption wavelength. Washing fastness showed 4~4/5 shade change rating without any staining. And dry rubbing fastness was good at low color strength. The bacterial reduction ratios of dyed cotton fabric were also increased.

Preparation of Regenerated Cellulose Fiber via Carbonation. I. Carbonation and Dissolution in an Aqueous NaOH Solution

Cellulose carbonate was prepared by the reaction of cellulose pulp and CO2 with treatment reagents, such as aqueous ZnCl2 (20–40 wt%) solution, acetone or ethyl acetate, at −5–0°C and 30–40 bar (CO2) for 2 hr. Among the treatment reagents, ethyl acetate was the most effective. Cellulose carbonate was dissolved in 10% sodium hydroxide solution containing zinc oxide up to 3 wt% at −5–0°C. Intrinsic viscosities of raw cellulose and cellulose carbonate were measured with an Ubbelohde viscometer using 0.5 M cupriethylenediamine hydroxide (cuen) as a solvent at 20°C according to ASTM D1795 method. The molecular weight of cellulose was rarely changed by carbonation. Solubility of cellulose carbonate was tested by optical microscopic observation, UV absorbance and viscosity measurement. Phase diagram of cellulose carbonate was obtained by combining the results of solubility evaluation. Maximum concentration of cellulose carbonate for soluble zone was increased with increasing zinc oxide content. Cellulose carbonate solution in good soluble zone was transparent and showed the lowest absorbance and the highest viscosity. The cellulose carbonate and its solution were stable in refrigerator (−5°C and atmospheric pressure).

Optimization of Cellulose Dyeing with Natural Indigo: Ramie dyeing by One-step Reduction/dyeing Process

One-step reduction/dyeing method was applied for ramie dyeing with natural indigo powder. The effect of reduction/dyeing conditions including the pH of bath, dye temperature and time, and concentration of indigo powder and reduction agent on dye uptake and color properties were investigated. Regardless of addition of alkali, the dyed fabrics appeared in the PB Munsell color range(: 660 nm) and the dye uptake was much higher with no addition of sodium hydroxide. Dyeing was carried out through the use of only sodium hydrosulfite in the bath. The maximum dye uptake was obtained at 60 for 30min. Saturated dye uptake was obtained at 2 g/L of sodium hydrosulfite concentration up to 2 g/ L of indigo powder. Whereas, at higher indigo powder concentration (4 g/L), more than 3 g/L of reducing agent concentration was required for obtaining the saturated dye uptake. Color reproducibility was reliable with color difference in the range of 0.03~0.16. Regardless of color strength, fastness to rubbing was acceptable with a 3/4~4/5. Fastness to washing, dry cleaning, and light of samples with low color strength were poor. Whereas, fastness to washing, dry cleaning, and light of samples with high color strength were very good.

Production of natural indirubin from indican using non-recombinant Escherichia coli

Indirubin is an important natural substance and has positive effects on various diseases. However, the current process of producing indirubin is inefficient, making it difficult to produce indirubin of high purity; thus, it is commercially unavailable. In this study, a method of indirubin using non-recombinant Escherichia coli as a whole cell enzyme with indican as a substrate was developed. After confirming that indirubin was produced from indican by non-recombinant E. coli under general conditions, attempts to compare the yield and purity of indirubin were conducted under various pH, temperature and culturing media conditions. Under the optimum conditions, the yield was reliably determined to be about 25-35%, and it was further increased (1.8-2.1 fold) by replenishing the catalyst with freshly prepared whole cells. Since the established method was simple and reproducible, high purity indirubin would expected to be produced efficiently through improvement of whole cell enzymes and development of scale-up processes.

Dyeing Properties and Storage Stability of Leaf Powder Prepared from Dyer`s Knotweed (I) - by Freeze Drying method -

Abstract ― The objective of this study is to investigate the efficacy of l eaf powder colorants as substitutes for traditional fresh juice extract dyeing. Three kinds of leaf powder colorants were prepared by freeze drying method with or without deep freezing as pre-treatment: one powder colorant from fresh leaf juice wit h deep freezing; two kinds of powder colorant from fresh leaves with and without deep freezing. Their dyeing properties and sto rage stabilities were studied and compared with the traditional fresh juice extract dyeing. The presence of indigo in the powde r colorants was confirmed by UV/Visible absorption spectra. The y showed absorption peak at 602nm which was same with indigo abso rption peak. Dyeing was done at low temperature around 6 ℃. All three powder colorants produced B colors on silk fabrics, s howing similar color to the one dyed traditionally with fresh j uice extract. The powder colorants from leaves gave higher color str ength than the powder from leaf juice. The powder colorant prepared from leaves with deep freezing was the most stable for long term storage as its color and color strength were not changed after 360 days. So, this was used for further dyeing to study the effects of concentration and repeat dyeing on color strength and colorfastness. Fastnesses to dry cleaning and rubb ing were fairly good above 4 rating. Further study is needed to improve light fastness. It was concluded that the leaf powder c olorant with deep freezing could be used as a substitute for traditional juice extract dyeing at all seasons.