Unraveling the Effect of Citric Acid on Microstructure, Rheology, and Structural Recovery of Thermoplastic Potato Starch

Javidi, Zeinab; Nazockdast, Hossein; Ghasemi, Ismaeil

doi:10.1002/star.202000193

Cited by 4 publications

(7 citation statements)

References 43 publications

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“…The hydrolysed amylopectin chain behaves like the linear amylose chain, promoting stable single helix crystalline formation during drying. The same observation was also found in the study of Javidi et al 21 where they found that the TPCS chain liberated from the amylopectin has a high potential to recrystallize into a single helix helical structure during the post-processing stage. Besides that, they also concluded that adding the carboxylic acids could effectively reduce the retrogradation in the corn starch films due to the cross-linking reaction between the TPCS chains.…”

Section: Crystalline Structure Of Cr-tpcs and Cr-4b1c Studies Through...supporting

confidence: 82%

“…Coplasticization between glycerol and carboxylic acid has higher plasticization effect than single plasticizer system (glycerol) in reducing the intermolecular interaction of the TPCS chains and promoting higher film's flexibility. Co-plasticization has higher efficiency to disrupt the intra and inter-molecular structure of TPCS and promote greater dynamic motions of the molecules 21 Generally, the CA-TPCS films showed marginally higher tensile strength and Young's modulus than the TA-TPCS films in their respective pH values. The different mechanical properties between the CA-TPCS and TA-TPCS may be attributed to the different carboxyl groups in their chemical structure.…”

Section: Resultsmentioning

confidence: 99%

“…Carboxylic acid is expected to interact with the TPCS as internal plasticizer or external plasticizer by forming physical or chemical bonding between the TPCS chain, plasticizer, and nanocellulose. 21,42,45 As reported in the literature, the carboxylic acid can act as internal plasticizer form covalent bonding with the TPCS chain through mono-esterification without cross-linking the intermolecular TPCS chains. The mono-esterification formed starch citrate in the TPCS chain, which acts as the internal plasticizer and interrupts the inter and intramolecular hydrogen bond of the TPCS chain, as shown in Figure 2.…”

Section: Crystalline Structure Of Cr-tpcs and Cr-4b1c Studies Through...mentioning

confidence: 86%

“…19 The incorporation of the carboxylic acid can enhance the TPS film’s mechanical and hydration properties by forming strong hydrogen bonding and ester chemical bonding with the TPS chains. 20,21 The carboxylic acid can function as an external plasticizer and as an internal plasticizer in the TPS matrix. The dual function carboxylic acid is due to the partial esterification ability of carboxylic acid with the TPS chains, which interrupts the intra and inter TPS molecular chains by chemically attaching to them.…”

Section: Introductionmentioning

confidence: 99%

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Thermoplastic starch hybrid biocomposite films with improved strength and flexibility produced through crosslinking via carboxylic acid

Lai

Osman

Adnan

et al. 2023

Journal of Thermoplastic Composite Materials

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Thermoplastic starch (TPS) suffers from its intrinsic low mechanical strength and high brittleness due to its strong hydrogen bonding and low chain mobility. The conventional way to crosslink the TPS film can improve the strength and stiffness of the films, but usually reduces the flexibility of the film, and increases its brittleness. In this study, the incorporation of the hybrid nanofiller [1 wt% nanocellulose (C) and 4 wt% nano bentonite (B)] into the TPS proved to improve greatly the films’ strength and flexibility. The hybrid nanofillers with ratio 4B:1C was incorporated into the crosslinked thermoplastic corn starch (CR-TPCS) film to increase the its flexibility and toughness and produced a high mechanical strength fully biodegradable film. Two different aqueous carboxylic acids: citric acid (CA) and tartaric acid (TA) with different pH values (2,4,6) as the green crosslinker were employed. Substantial increase of tensile strength (3.98 to 9.17 MPa), Young’s modulus (9.10 to 46.30 MPa) and elongation at break (55.2 to 135.7%) was observed for the CA- 4B1C/pH2 films compared to the CR-TPCS films. The melting temperature (Tm) of the CA-4B1C/pH2 improved compared to the TPCS/4B1C (un-crosslinked) film due to its crosslinking effect. Meanwhile, the CA-4B1C films exhibited the highest degree of substitution and di-esterification with the lowest swelling and water solubility properties due to the formation of a special “bridge” structure between the CA, nanocellulose and plasticizer. The “bridge” structure developed between the TPCS chains serves as the toughener to motivate higher chain stress relaxation and load endurance. The crosslinked “bridge structure” also proved to effectively reduce the retrogradation phenomenal in the TPCS films. This combination method of hybridization and crosslinking is an efficient, low cost, and environmentally friendly technique to overcome the low flexibility and brittleness problem of the TPS based packaging film.

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Section: Crystalline Structure Of Cr-tpcs and Cr-4b1c Studies Through...supporting

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Crystalline Structure Of Cr-tpcs and Cr-4b1c Studies Through...mentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Thermoplastic starch hybrid biocomposite films with improved strength and flexibility produced through crosslinking via carboxylic acid

Lai

Osman

Adnan

et al. 2023

Journal of Thermoplastic Composite Materials

View full text Add to dashboard Cite

show abstract

“…The crosslinking of starches with crosslinkers such as CA, [ 6‐9 ] STMP, [ 10‐13 ] and epichlorohydrin [ 14 ] have reported to introduce intra‐ and inter‐molecular bonds at selected hydroxyl (─OH) groups of two adjoining intact starch molecule. It mainly occurrs in the amorphous region of starch, and induces amylopectin–amylopectin and amylose–amylopectin crosslinking.…”

Section: Introductionmentioning

confidence: 99%

Effect of Citric Acid and Sodium Trimetaphosphate Induced Crosslinking on Functional, Rheological, Structural, and Thermal Properties of Buckwheat Starch

2023

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The present study utilizes citric acid (CA, 12-60% of dry starch) and sodium trimetaphosphate (STMP, 6-30% of dry starch) to crosslink buckwheat starch. The major morphological changes are observed for CAinduced crosslinking, which erodes the polygonal and irregular shaped granules surface leading to formation of indentation and disappearance of pores. FTIR analysis confirms CA crosslinking, which introduces a new peak at 1720 cm −1 (stretching vibration of C═O). XRD pattern reveals both crosslinkers disrupt the crystalline region of native granules leading to reduction in crystallinity index. These changes detrimentally affect the solubility and swelling power even at higher temperature (95 °C). As a result, the pasting curve gets flattened and very poor gel is formed. The crosslinked starch gels are highly flowable, have low yield stress, and show shear thinning behavior. The thermal analysis shows that CA starches gelatinize at lower temperatures due to poor crystalline structure and require lower energy. Thermogravimetric analysis shows crosslinked starches have higher residual mass (10.20-25.17%) at 450 °C compared to native (8.66%). Conclusively, as the concentration of crosslinkers increases, the properties of BS undergo more pronounced changes, resulting in severe alterations in its functional, rheological, and thermal properties at higher concentrations.

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Effect of graphene/graphene oxide on microstructure development and its impact on electrical conductivity and shape recovery behavior of plasticized starch-based nano-biocomposites

2022

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Unraveling the Effect of Citric Acid on Microstructure, Rheology, and Structural Recovery of Thermoplastic Potato Starch

Cited by 4 publications

References 43 publications

Thermoplastic starch hybrid biocomposite films with improved strength and flexibility produced through crosslinking via carboxylic acid

Thermoplastic starch hybrid biocomposite films with improved strength and flexibility produced through crosslinking via carboxylic acid

Effect of Citric Acid and Sodium Trimetaphosphate Induced Crosslinking on Functional, Rheological, Structural, and Thermal Properties of Buckwheat Starch

Effect of graphene/graphene oxide on microstructure development and its impact on electrical conductivity and shape recovery behavior of plasticized starch-based nano-biocomposites

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