Process Intensification for Enzyme Assisted Turmeric Starch Hydrolysis at Hydrotropic and Supercritical Condition

FoodSciRN: Other Functional Foods Pub Date : 2020-09-28 DOI:10.2139/ssrn.3701162

Yogita P. Labrath, Prafulla V. Belge, U. G. Kulkarni, V. Gaikar

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Abstract

The turmeric rhizome (Curcuma longa) contains curcuminoids embedded in the starch matrix. It is important to target starch removal by hydrolysis to enhance the rate and extent of extraction of curcuminoids. Enzymes are green catalysts and their activity can be enhanced by working on certain parameters. In the case of starch hydrolysis, α- amylase is more efficient when the starch is in the gelatinized form than when it is in its natural form. α-Amylase activity improves under supercritical carbon dioxide (scCO2) conditions. Certain surfactants improve α- amylase activity. Hydrotropes are a mild form of the surfactants. However, there are no reports on hydrolysis of turmeric starch in hydrotropic or supercritical (SFC) conditions. The work in this report shows beneficial effect of hydrotrope on the enzymatic reactions. There is marked enhancement in the diffusion coefficient (De) for curcuminoid extraction. The increased starch hydrolysis also improves the solid filtration rates after hydrotropic extraction of the curcuminoids. In the case of hydrotropic extraction of curcuminoids alone otherwise the filtration rate decreases due to the sticky nature of the extraction mass, caused by swelling of the starch. The present work includes hydrolysis of turmeric starch in its natural and gelatinized forms using α-amylase in hydrotrope solution (HS) and scCO2.The starch hydrolysis parameters include α-amylase concentration, solid loading concentration, scCO2 flow rate, presence of modifier in scCO2, residence time and scCO2 backpressure. The optimum hydrolysis parameters are 200 IU.cm-3 of α-amylase, at 328 K, 10 % (w/w) of turmeric loading concentration, 6.5 reaction pH, 900 rpm agitation speed for hydrotropic hydrolysis while the optimum conditions are 5 % w/w turmeric loading concentration, 40 min of scCO2 residence time, 15 cm3 of scCO2 phase modifier and 15 MPa as the scCO2 backpressure. The De for hydrolysis in the HS for turmeric starch in gelatinized form (A) was 4.1 x 10-11 m2s-1 and De for starch hydrolysis methods including in HS for turmeric starch in natural state (B), SFC condition for turmeric starch in natural state (C) and SFC for turmeric starch in gelatinized (D) were approximately 4.1 x 10-12 m2s-1. De for native turmeric starch in the absence of hydrotrope and SFC (E), and in case of gelatinized turmeric starch hydrolysis in absence of SFC and hydrotrope were 4.1x 10-14 and 4.1x 10-13 m2s-1, respectively. The filtration rates for (A), (D), (B), (C), (E) were 2 x 10-4, 1.25 x 10-11, 1.4 x 10-11, 7.3 x 10-11, 8.2 x 10-11 kgm2s-1 respectively. The De and filtration rate were noted in order (A) > (D) > (B) > (C) > (E) > (F). The 2.5 h SFC and 2.15 h HS enzyme treated turmeric powder gave 6.56 and 2.44 x 106 times increased filtration rate for curcuminoid extraction compared to untreated turmeric powder.

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酶助姜黄淀粉在水热和超临界条件下水解的工艺强化

姜黄根茎(Curcuma longa)含有嵌入淀粉基质中的姜黄素。提高姜黄素的提取率和提取率，对水解脱除淀粉具有重要意义。酶是绿色催化剂，其活性可以通过特定的参数来增强。在淀粉水解的情况下，α-淀粉酶在淀粉处于糊化形式时比在其自然形式时效率更高。超临界二氧化碳(scCO2)条件下α-淀粉酶活性提高。某些表面活性剂可提高α-淀粉酶的活性。亲水剂是表面活性剂的一种温和形式。然而，目前还没有关于姜黄淀粉在亲水或超临界条件下水解的报道。本报告的工作表明了水异构物对酶促反应的有益作用。姜黄素提取的扩散系数(De)有明显的提高。淀粉水解程度的提高也提高了亲水提取姜黄素后的固体滤过率。在单水萃取姜黄素的情况下，由于淀粉膨胀引起的萃取物的粘性，过滤速率降低。目前的工作包括用α-淀粉酶在疏水溶液(HS)和scCO2中水解天然和糊化形式的姜黄淀粉。淀粉水解参数包括α-淀粉酶浓度、固载浓度、scCO2流速、scCO2中改性剂的存在、停留时间和scCO2背压。最佳水解参数为200iu。α-淀粉酶的分子量为cm-3，在328 K、10% (w/w)姜黄负载浓度、6.5反应pH、900 rpm搅拌速度下进行亲水水解，最佳条件为5% w/w姜黄负载浓度、40 min scCO2停留时间、15 cm3 scCO2相改性剂、15 MPa scCO2背压。糊化形式的姜黄淀粉(A)在HS中水解的De为4.1 × 10-11 m2s-1，包括自然状态的姜黄淀粉(B)在HS中水解的De，自然状态的姜黄淀粉(C)的SFC条件和糊化形式的姜黄淀粉(D)的SFC约为4.1 × 10-12 m2s-1。原生姜黄淀粉在不含水变性物和水变性物的情况下的De (E)，以及在不含水变性物和水变性物的情况下糊化姜黄淀粉的De分别为4.1 × 10-14和4.1 × 10-13 m2s-1。(A)、(D)、(B)、(C)、(E)的过滤速率分别为2 × 10-4、1.25 × 10-11、1.4 × 10-11、7.3 × 10-11、8.2 × 10-11 kgm2s-1。De和滤过率依次为(A) > (D) > (B) > (C) > (E) > (F)。经2.5 h SFC和2.15 h HS酶处理的姜黄粉的姜黄素提取率分别比未处理的姜黄粉高6.56和2.44 × 106倍。

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FoodSciRN: Other Functional Foods

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