Characterization of a Thermoresponsive Chitosan Derivative as a

Sep 30, 2016 - A simple forward osmosis (FO) test for dye dehydration revealed the potential use of the thermoresponsive chitosan derivative as a draw...
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Characterization of a Thermoresponsive Chitosan Derivative as a Potential Draw Solute for Forward Osmosis Rumwald Leo G. Lecaros, Zih-Chi Syu, Yu-Hsuan Chiao, S. Ranil Wickramasinghe, Yan Li Ji, Quanfu An, Wei-Song Hung, Chien-Chieh Hu, Kueir-Rarn Lee, and Juin-Yih Lai Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.6b02102 • Publication Date (Web): 30 Sep 2016 Downloaded from http://pubs.acs.org on October 2, 2016

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Environmental Science & Technology

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Characterization of a Thermoresponsive Chitosan

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Derivative as a Potential Draw Solute for Forward

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Osmosis

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Rumwald Leo G. Lecarosa, Zih-Chi Syua, Yu-Hsuan Chiaob, S Ranil Wickramasingheb, Yan-Li

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Jia, c, Quan-Fu Anc, Wei-Song Hunga*, Chien-Chieh Hua, Kueir-Rarn Leea, and Juin-Yih Laia

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a

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Yuan University, Chung Li 32023, Taiwan

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b

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United States

R&D Center for Membrane Technology and Department of Chemical Engineering, Chung

Department of Chemical Engineering, University of Arkansas, Fayetteville, Arkansas 72701,

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c

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Polymer Science & Engineering, Zhejiang University, Hangzhou 310027, China

MOE Key Laboratory of Macromolecular Synthesis and Functionalization, Department of

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KEYWORDS: Thermoresponsive polymer, Draw solute, Forward osmosis

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Abstract

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A thermoresponsive chitosan derivative was synthesized by reacting chitosan (CS) with butyl

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glycidyl ether (BGE) to break the inter- and intramolecular hydrogen bonds of the polymer. An

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aqueous solution of the thermoresponsive CS derivative exhibits a lower critical solution

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temperature (LCST) than CS, and it undergoes a phase transition separation when the

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temperature changes. Successful incorporation of BGE into the CS was confirmed by FTIR and

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XPS analyses. Varying the BGE content and the concentration of the aqueous solution produced

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different LCST ranges, as shown by transmittance vs. temperature curves. The particle size was

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observed by scanning electron microscopy, which revealed that the particles were smaller and

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well dispersed at 15 °C, whereas the particles became larger and tended to aggregate at 60 °C. A

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similar trend was observed with the mean particle size measured using dynamic light scattering.

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Positron annihilation lifetime spectroscopy data also revealed the reversibility of the particle

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properties as a function of temperature. Microstructure analysis showed that the particles had

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larger free-volume sizes at 15 °C than at 60 °C. The particles were also found to be non-toxic

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with 92% cell survival. A simple forward osmosis (FO) test for dye dehydration revealed the

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potential use of the thermoresponsive chitosan derivative as a draw solute with a flux of 8.6

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L/m2h and rejection of 99.8 %.

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Introduction

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Thermoresponsive polymers dissolve in aqueous solution at temperatures below their

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lower critical solution temperature (LCST) and are phase separated at temperatures above their

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LCST. Such stimuli-responsive polymers are important and have attracted much attention due to

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their diverse applications in biomedicine1 and separation processes.2-7 LCST behavior is

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observed when the inter- and intramolecular interactions vary with increasing temperature.8, 9

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Thus, grafting hydrophobic groups onto the polymer chain can tune the thermoresponsive

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behavior by disrupting the inter- and intramolecular hydrogen bonds of the polymers.1

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Thermoresponsive materials based on natural polymers have drawn great interest because of

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their attractive properties, which include biocompatibility, biodegradability and non-toxicity.

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Chitosan (CS), the partially acetylated cationic (1,4)-2-amino-2-deoxy-β-D-glucan, possesses

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these distinct properties, which makes it a good candidate for various applications. CS is only

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soluble in dilute aqueous acid solution. It has two reactive groups (amino and hydroxyl groups)

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where a monomer can be added through different chemical modification techniques, potentially

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changing or enhancing its properties.10, 11

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One of the modern day concerns is having a sufficient supply of potable water for the

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future. The forward osmosis (FO) process has currently gained attention as an alternative method

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of desalination12

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less than reverse osmosis.14-18 An ideal FO membrane is capable of providing high water

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permeability, high rejection of solutes, substantially reducing internal concentration polarization

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(ICP), and has high chemical stability and mechanical strength. Likewise, a good draw solution

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must have the following characteristics: high water flux, minimal reverse draw solute flux, no

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toxicity, reasonably low cost, and easy recovery. Meanwhile, it is required to be compatible with

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because it does not require high pressures, it is easy to operate, and it costs

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the FO membrane. Commonly available compounds as draw solutes can be classified into four

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types according to their physicochemical properties: volatile compounds, saccharides, inorganic

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salts, and organic salts and polymers.19-21 Butyl glycidyl ether (BGE) covalently bound to starch

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molecules has been previously demonstrated to undergo phase separation above its LCST.1 Other

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research has shown that a thermoresponsive cellulose ether composed of BGE was grafted onto

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hydroxyethyl cellulose and exhibited both LCST behavior and a critical flocculation temperature

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(CFT). This thermoresponsive cellulose ether was able to encapsulate dyes at temperatures above

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its LCST and to separate them from water at temperatures above the CFT.2 In another case, an

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ionic liquid at temperatures below its upper critical solution temperature (UCST) has been used

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in FO as a draw solute in treating high-salinity water;4 hydrophilic magnetic nanoparticles have

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also been used as draw solutes in FO.22, 23

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Herein, we developed a non-toxic draw solute using CS that has been modified using the

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hydrophobic monomer BGE, resulting in LCST behavior. The two reactive groups of CS, amine

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and hydroxyl groups, act as nucleophiles that attack the epoxide ring of BGE. In the case of the

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hydroxyl group of CS, it must first be attacked by a strong base such as NaOH, followed by the

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opening of the epoxide ring. The resulting draw solute was subsequently used in forward

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osmosis with Congo Red dye as the feed solution.

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Experimental Section

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Scheme 1. Synthesis of the thermoresponsive chitosan derivative and a schematic of its LCST

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behavior.

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Materials

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CS (90% deacetylated) was acquired from Shimakyu’s Pure Chemicals. BGE (95%) was

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purchased from Sigma-Aldrich. Glacial acetic acid (analytical grade, 99%) was acquired from

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Scharlau. All other reagents and solvents were commercially acquired and were used without

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further purification. The deionized water used in all experiment had a resistivity of 18 MΩ cm.

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Synthesis of the thermoresponsive CS derivative

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The synthesis reaction of CS with BGE is shown in Scheme 1. CS (2 g) was dissolved

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using 10 ml of 2% (v/v) acetic acid. It was stirred in a three-necked round-bottom flask at room

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temperature until all CS flakes were completely dissolved. The solution was heated under reflux

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to 75 °C in an oil bath, followed by the addition of 1.25 M NaOH and stirred for 1 h. Four

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formulations were prepared using various volumes of BGE: CS-BGE-1 (1 ml BGE); CS-BGE-2

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(3 ml BGE); CS-BGE-3 (6 ml BGE); and CS-BGE-4 (9 ml BGE). The reaction was conducted

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under continuous stirring at 75 °C. After 5 h, the mixture was cooled in an ice bath and

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neutralized to pH 7.0 using 1 M HCl. The product was washed three times with 90% (v/v)

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acetone. The product was placed in a dialysis bag and dialyzed in deionized water for 24 hours to

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purify the sample. The precipitate was filtered and then dried overnight at 50 °C.

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Characterization of the thermoresponsive chitosan derivative

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The compounds were analyzed by total reflectance Fourier transform infrared

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spectroscopy (ATR-FTIR) on a Perkin-Elmer Spectrum One over the wavenumber region from

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4000 to 900 cm-1. X-ray photoelectron spectroscopy (XPS) was carried out on a Thermo

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Scientific K-Alpha to characterize the elemental composition of the samples. LCSTs of 1 wt%

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CS-BGE aqueous solutions were measured through turbidity measurements using a UV-vis

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spectrophotometer (Perkin-Elmer Lambda 25) at 500 nm with a heating rate of 1 °C/min.

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Scanning electron microscopy (SEM, Hitachi S4800) was performed to investigate the formed

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particles. The samples were dried on a Si sample stage at 15 °C and 60 °C. The mean particle

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size distribution at 15 °C and 60 °C was measured by dynamic light scattering (DLS) using a

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Beckman Coulter DelsaNano S. The samples were measured for 90 s at each temperature.

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Positron annihilation lifetime spectroscopy

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The free volume in the 1 wt% aqueous solution of the thermoresponsive chitosan

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derivative was measured using positron annihilation lifetime spectroscopy. A conventional fast-

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fast coincidence spectrometer with a time resolution of 250 ps was used. A radioactive source of

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annihilation lifetimes were recorded using a fast-fast coincidence timing system. A time-to-

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amplitude converter was used to convert the lifetimes and to store the timing signals in a multi-

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channel analyzer (Ortec System). Two million counts were collected, and all positron

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annihilation lifetime spectra were analyzed by a finite-term lifetime analysis method using the

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PATFIT program. 24, 25

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Forward osmosis and microfiltration test

Na (0.74 MBq) sealed between 12-µm-thick Kapton films was placed in the solution. Positron

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The permeation flux was measured using small-scale U-shaped FO tubes from Narika

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Corp. (OP-25U F35-2111). A thin-film composite membrane from Hydration Technologies, Inc.

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(HTI) was placed and sealed between the two glass tubes. One side was filled with 0.025 wt%

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Congo Red dye as the feed solution. The other side was filled with 1 wt% aqueous solution of

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CS-BGE-3 as the draw solution. The temperature of the solutions was maintained at room

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temperature during the FO tests. The water permeation flux (L/m2h) was calculated as the

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volume change of the draw solution (L) over time (h) and effective surface area (m2) of the

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membrane. The percent rejection (%) was calculated as the difference of concentration in feed

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and permeate divided by the feed concentration times 100. The osmolality of the

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thermoresponsive chitosan derivatives and Congo Red dye was measured using an osmometer

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(model 3320 micro-osmometer, Advanced Instruments, Inc.). The draw solution was heated to

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60 °C to separate the water from the draw solute through microfiltration at operating pressure of

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1 bar (Gore® Microfiltration membrane, Product number: GMM-404, pore size: 0.45 µm).

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Results & Discussion

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Modification of Chitosan

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Figure 1. FTIR spectra of BGE, CS, and CS derivatives: CS-BGE-1, CS-BGE-2, CS-BGE-3 and

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CS-BGE-4.

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The FT-IR spectra of BGE, CS, CS-BGE-1, CS-BGE-2, CS-BGE-3 and CS-BGE-4 in

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transmission mode are presented in Figure 1. The spectrum of BGE exhibited peaks at 2965 cm-1,

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2940 cm-1 and 2867 cm-1, which are all attributed to alkyl –CH stretching vibrations. The peak at

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1110 cm-1 is attributed to the C–O–C stretching of the epoxide ring. The characteristic peaks of

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the CS were observed at 3347 cm-1 and 3310 cm-1; these bands are assigned to the broad O–H

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and N–H stretching, respectively. The CS spectrum also showed a –CH stretching vibration 2935

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cm-1, a strong –NH2 bending vibration at 1650 cm-1, an N–H bending vibration at 1550 cm-1, a

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C–O–C asymmetric stretching of the glycosidic linkage at 1070 cm-1, and a C–O stretching

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vibration at 1022 cm-1.

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The spectra of the CS derivatives showed a broad stretching of O–H absorption at 3347

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cm-1, which is attributed to the CS backbone. Compared with spectrum of the pristine CS, the

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spectra of the CS derivatives showed an increased band intensity for the alkyl groups (–CH

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stretching) at 2965 cm-1, 2940 cm-1, and 2867 cm-1; this increase in intensity was due to the

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addition of BGE. The band intensity also increased with increasing BGE content. The spectra of

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the CS derivatives also showed weaker bands representing N–H bending absorptions at 1650 cm-

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1

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BGE bonded to the free amine groups of CS. The C–O–C band of the epoxide ring from BGE

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was not observed in the spectra of the CS derivatives; however, the spectra of the CS derivatives

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showed a shift of the C–O stretching band at 1100 cm-1, indicating that the epoxide ring was

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opened during the reaction and bound to either the free –OH or the free –NH2 groups of the CS,

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thereby forming an ether linkage. These results indicate that BGE was successfully grafted onto

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the molecular chains of CS.

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Table 1. XPS elemental analyses of CS and its derivatives.

and 1550 cm-1 as the BGE content was increased; the emergence of these bands indicates that

CS CS-BGE-1 CS-BGE-2 CS-BGE-3 CS-BGE-4

C (%) 61.64 65.56 68.29 67.67 68.87

O (%) 31.81 30.37 28.74 30.16 28.34

N (%) 6.55 4.07 2.97 2.17 1.79

N/C 0.106 0.062 0.043 0.032 0.026

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XPS was performed to confirm changes in the elemental composition of the CS

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derivatives prepared by the addition of BGE. Table 1 lists the elemental compositions and N/C

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ratios of CS and its thermoresponsive derivatives. Compared to the carbon composition of the

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unmodified CS, that of the CS derivatives increased when BGE was added. As a result, a

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decrease in the nitrogen content was observed. These results show that upon the addition of more

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alkyl groups, the N/C ratio decreased. This noticeable trend indicates that changes occurred in

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the molecular structure due to covalent bonding of BGE to the CS backbone. Both the FTIR and

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XPS analyses demonstrate the presence of the hydrophobic moiety on the CS derivatives.

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Thermoresponsive solubility

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The LCST can be identified as the initial break point,26, 29

27

as the temperature

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corresponding to 90% transmittance28,

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transmittance1, 9, 27 in transmittance vs. temperature curves obtained by UV-Vis spectroscopy. In

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this study, we chose to define the LCST as the temperature corresponding to 90% transmittance.

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The initial break point does not apply to our curves because the curve drops too rapidly. On the

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other hand, some curves did not reach 50% transmittance.

or as the temperature corresponding to 50%

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80

Transmittance(%)

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Transmittance(%)

100

CS-BGE-1 0.5wt% 1wt% 1.5wt%

60

40

20

CS-BGE-2 0.5wt% 1wt% 1.5wt%

60

40

20

0

0 0

10

20

30

40

50 o

60

70

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0

10

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Temperature( C)

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Transmittance(%)

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Transmittance(%)

100

60

CS-BGE-3 0.5wt% 1wt% 1.5wt%

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50 o

60

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CS-BGE-4 0.5wt% 1wt% 1.5wt%

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0 0

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Temperature( C)

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50 o

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0

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Temperature( C)

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50 o

Temperature( C)

Figure 2. Transmittance vs. temperature curves of CS derivatives at 500 nm.

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Zhang et al. previously used thermoresponsive 2-hydroxy-3-butoxypropyl starch (i.e.,

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starch molecules grafted with BGE) to demonstrate that the LCST behavior of the starch changed

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with changes in molar substitution.1, 9 Figure 2 shows the transmittance vs. temperature curves

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of the modified CS derivatives with various BGE contents and different aqueous concentrations.

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LCST behavior is observed from the temperature where the solution is clear showing high

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transmittance up to the temperature where the solutions turns into a turbid solution exhibiting

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low transmittance. Neither CS-BGE-1 nor CS-BGE-2 exhibited temperature-dependent light

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transmittance. These results are attributed to the low extent of BGE addition to the amine groups

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of the CS, as confirmed by the FTIR spectra. However, CS-BGE-3 and CS-BGE-4 exhibited

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temperature-dependent light transmittance, even at different concentrations of the aqueous

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solutions. These results demonstrate that sufficient amounts of hydrophobic reagents must be

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added to the mixture to observe the LCST behavior. We also observed that lowering the polymer

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concentration increases the LCST. The 0.5 wt% solutions of CS-BGE-3 and CS-BGE-4 did not

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reach transmittances lower than ~80% and ~90%, respectively. This is due to the few particles

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formed by the presence of low solute. The particles will take time to aggregate and show a very

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slow LCST behavior. Thus a less turbid solution is observed with high transmittance. CS-BGE-3

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exhibited the best observable thermoresponsive behavior among the investigated formulations, as

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demonstrated by its sharp phase transition near ambient temperature. With an increase in the

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BGE content, the number of hydrophobic groups on the CS derivatives increased, which

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disrupted the inter- and intramolecular hydrogen bonds of the CS backbone. The excessive

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disruption of hydrogen bonds resulted in a reduced thermoresponsive effect.

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(b)

(a)

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Figure 3. (a) Transmittance vs. temperature curves of CS-BGE-3 at different concentrations. (b)

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The effect of concentration on LCST and ∆T1/2.

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CS-BGE-3 was further characterized for its phase-transition behavior. Figure 3a displays

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the effect of polymer concentration on the phase-transition behavior. Polymer solutions with

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concentrations from 0.5 wt% to 2 wt% exhibited different LCST ranges. Solutions with lower

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polymer concentrations exhibited higher LCSTs and broader phase transitions. With decreasing

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polymer concentration, the light transmittance of the solutions decreased. This result is attributed

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to the presence of less solute and insufficient polymer to aggregate and form a completely white

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turbid solution, unlike the solutions with higher polymer concentrations. A sharp phase transition

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is important for thermoresponsive smart materials. The microcalorimetric endotherm (∆T1/2),

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which is the half-value of the temperature difference between the final and initial break points in

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the transmittance vs. temperature curves, was used to better evaluate the sharpness of the phase

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transitions.27 Figure 3b shows that the phase transition of the 0.5 wt% solution was broad and

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that its ∆T1/2 was 19.5 °C. When the polymer concentration was increased to 2 wt%, the phase

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transition became sharper, with a ∆T1/2 of 5.1 °C. This result can be explained by the effect of the

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polymer concentration on the time required for aggregation.9 That is, when the polymer

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concentration is low, additional time is needed to form aggregates.

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Thermoresponsive behavior of CS derivatives (a) (b)

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Figure 4. (a) Digital photographs of 1 wt% CS-BGE-3 aqueous solution at 15 °C and 60 °C,

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along with corresponding SEM images of the particles. (b) Reversible changes in the mean

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particle size of CS-BGE-3 aqueous solution at 15 °C and 60 °C.

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We observed that the 1 wt% CS-BGE-3 solution turned turbid when heated beyond its

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LCST and was able to return to its original state when cooled below its LCST (Figure 4a). This

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observation reveals that the aqueous solution exhibits reversible thermoresponsiveness. The

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SEM images reveal that particles were formed in the solution. The size of particles obtained by

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drying the solution at 15 °C was approximately 10 µm, whereas that of particles obtained from

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drying the solution at 60 °C was approximately 30 µm. The SEM images further show that the

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particles were uniformly dispersed and that aggregates formed at higher temperatures. A similar

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trend was reported on the basis of TEM images of a thermoresponsive cellulose ether.2

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To thoroughly investigate the size of the particle and aggregation with respect to temperature

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changes, dynamic light scattering (DLS) measurements were performed at 15 °C and 60 °C

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(Figure 4b). The sample was analyzed at 15 °C for 90 s. The temperature of the sample was then

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increased to 60 °C and analyzed for another 90 s. This test was repeated for three temperature

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cycles. Interestingly, the mean particle size at 15 °C ranged from approximately 1100 nm to

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1300 nm, whereas that at 60 °C initially ranged from 3000 nm and then abruptly increased with

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time to approximately 4250–4750 nm. The size observed in the SEM images correlates with the

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DLS results. Notably, the particle size at 60 °C continually increased with time, demonstrating

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that the particles continued to aggregate. A possible reason for this behavior is the continued

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disruption of the inter- and intramolecular hydrogen bonds in the polymer. The CS derivative has

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an amphiphilic nature; thus, the hydrophobic groups from the hydrophobic reagent bonded onto

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the CS chain provide a means for the molecule to form particles in solution.

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Microstructure analysis of the thermoresponsive property by positron annihilation lifetime

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spectroscopy

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(a)

(b)

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Figure 5. Positron annihilation lifetime spectroscopy analysis for 1 wt% CS-BGE-3 aqueous

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solution at 15 °C and 60 °C. Reversible thermoresponsive behavior effect on (a) o-Ps lifetime

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and free-volume size and (b) o-Ps intensity.

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Positron annihilation lifetime spectroscopy (PALS) is a highly sensitive technique for

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monitoring conformational, structural and microenvironmental transformations arising from

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subtle geometric changes in the molecular geometry of polymers.30-34 Quantitative analysis of the

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free-volume size and the free-volume size distribution for the thermoresponsive polymeric

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aqueous solutions were determined by the PALS technique for the first time. Figure 5 shows the

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o-Ps lifetime and o-Ps intensity of a 1 wt% CS-BGE-3 solution. The o-Ps lifetime is related to

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the free-volume that is available between polymer chains. A longer o-Ps lifetime corresponds

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with free-volumes with larger radii. As evident in Figure 5a, the free-volume size of the solution

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was larger at lower temperatures than when heated to higher temperatures. At 15 °C, the o-Ps

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lifetime was high at approximately 3.8–4.0 ns, corresponding to radii between 4.02 and 4.24 Å.

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When the solution temperature was increased to 60 °C, the o-Ps lifetime decreased substantially

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to 2.1–2.4 ns, corresponding to radii between 2.86 and 3.20 Å. The temperature was then cycled.

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These experiments show that the particles at 15 °C exhibit a larger free-volume than those at 60

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°C, suggesting a reversible thermoresponsiveness. Next, we monitored the o-Ps intensities,

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shown in Figure 5b, to assess the available free-volume. Large o-Ps intensity values indicate

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large amounts of free-volume holes. A similar trend was observed at 15 °C, where the intensity

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is higher, indicating approximately 21–22% free-volume. However, when the temperature was

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increased to 60 °C, the o-Ps intensity decreased to approximately 10–12%. The data also show

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the reversibility of the free-volume. These results suggest that at low temperatures, the

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hydrophobic part of the CS derivative is hidden within the well-dispersed particles. By contrast,

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at high temperatures, the polymer chains tend to rearrange to expose the hydrophobic moiety and

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aggregate, which leads to smaller free-volume holes. These events explain the dramatic changes

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in the o-Ps lifetime and o-Ps intensity during the phase transition. A better representation of this

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idea is shown in Scheme 1. At temperatures below the LCST, the polymer chains are linear and

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form hydrogen bonds with water molecules, resulting in larger free-volume spaces. During the

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transition at temperatures greater than the LCST, the polymer chains tend to fold and rearrange.

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In this phase, the hydrogen bonds decrease, and the free-volume spaces shrink.

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Thermoresponsive chitosan derivative as a draw solute 800

Osmolality (mOsm)

700 600 500 400 300

CS-BGE-1 CS-BGE-2 CS-BGE-3 CS-BGE-4

200 100 0

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congo 0.0 red dye

0.5

1.0

1.5

2.0

Concentration (wt%)

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Figure 6. Osmolality of Congo Red dye and different concentrations of CS derivatives aqueous

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solution.

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Current challenges in FO involve the development of good draw solutes. In this study, we

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used a simple FO setup to initially study the potential of the thermoresponsive CS-BGE-3

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derivative as a draw solute. The osmolality of the Congo Red dye and different concentrations of

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CS derivatives aqueous solution was evaluated; the results are shown in Figure 6. The

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osmolality of the dye was lower than that of the thermoresponsive CS derivative at different

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concentrations in aqueous solutions. The lower BGE content resulted to a higher osmolality.

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However, these CS derivatives with low BGE content do not exhibit LCST behavior. Notably,

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the osmolality of the best thermoresponsiveness at 1 wt% CS-BGE-3 (492 mOsm) was higher

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than that of the dye (133 mOsm). Thus, a 0.025 wt% Congo Red dye solution was used as the

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feed solution and 1 wt% CS-BGE-3 as the draw solution. A commercial FO membrane was used.

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The experiment was performed at room temperature, which is below the LCST of the 1 wt% CS-

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BGE-3 solution.

290 291

Figure 7. Simple FO test for 1 wt% CS-BGE-3 as draw solute and microfiltration recovered CS

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derivatives. Feed solution: 0.025 wt% Congo Red dye.

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Figure 7 shows the setup used for FO and microfiltration. Initially, an equal volume of

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both the feed and draw solutions were placed on either side of a commercial FO membrane. The

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ability of the draw solute to draw water from the feed solution was initially investigated using

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deionized water as the feed solution. The flux was 9.1 L/m2h and CS derivative rejection 99.8 %.

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In the case of dye dehydration, a 10 cm difference in height was observed between the feed and

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draw solutions after a period of time. The calculated flux was 8.6 L/m2h and CS derivative

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rejection 99.8 %, indicating good permeation and negligible solute back diffusion. The small

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particles may have enhanced the drawability of the solution because they are more hydrophilic.

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The water from the draw solution was collected and heated to 60 °C, a temperature above its

302

LCST. The CS derivative aggregation can facilitate separation of the particles via microfiltration

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(pore size 1.0 µm), 99.9 % was recovered enabling the particles to be reused (See Figure 7.

304

right). We followed the ISO 10993-535 method for CSBGE-3 cytotoxicity test. The CSBGE-3

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was extracted for cell culture. Results showed a cell survival of 92% and it has been determined

306

to be zero-grade (non-toxic). The synthesized thermoresponsive CS derivative showed potential

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to be used as a draw solute in the FO process.

308

In conclusion, a thermoresponsive CS derivative, CS-BGE, was synthesized from

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hydrophilic CS reacted with hydrophobic BGE. The successful addition of BGE functional

310

groups was confirmed by FTIR spectroscopy and XPS elemental analysis. These experiments

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showed that BGE was bound to both the amine and the hydroxyl reactive groups of the CS.

312

Varying the BGE content changed the LCST range, and the CS-BGE-3 formulation was

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observed to exhibit the best response via a turbidity test by UV-vis spectroscopy. Increasing the

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concentration of the thermoresponsive CS aqueous solution led to a decrease in the LCST. This

315

change was due to aggregation of more particles in solution with increasing temperature. SEM

316

images showed the aggregation of particles from 15 °C to 60 °C. A similar trend was observed

317

for the mean particle size determined by DLS; particles aggregated when the temperature was

318

increased. When the temperature was increased to 60 °C, the mean particle size continually

319

increased within 90 s and returned to a smaller size when the temperature was lowered back to

320

15 °C. Interestingly, the PALS data also showed the reversibility of the particle formation. The

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free-volume sizes at lower temperatures was larger than those at higher temperatures. These

322

results demonstrate that changes in the microstructures occurred during the phase transition.

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Furthermore, the thermoresponsive CS derivative was found to be non-toxic with 92% cell

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survival. The results of simple FO tests suggest that the synthesized thermoresponsive CS

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derivative can potentially be used as a draw solute because it gives a flux of 8.6 L/m2h and

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rejection of 99.8 % upon dye dehydration.

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Corresponding Author

328

*E-mail: [email protected]

329

Acknowledgements

330

The authors wish to sincerely thank the Ministry of Science and Technology of Taiwan for

331

financially supporting this work.

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Table of Contents Graphic

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Reaction between chitosan and butyl glycidyl ether, producing a thermoresponsive chitosan

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derivative; the photographs show particles exhibiting lower critical solution temperature

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behavior.

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