The present study aims to optimize the enzymatic hydrolysis condition and determine the
functional properties of eel (Monopterus albus) protein hydrolysate (EPH) at different
hydrolysate concentrations (0.1%, 0.5%, 1.0%). The enzymatic hydrolysis (using alcalase)
condition; namely, temperature (°C), enzyme to substrate concentration (%) and pH on both
the yield and degree of hydrolysis (DH), as responses, was optimized using the response
surface methodology (RSM) by employing three factors, 3-level, Central Composite Design
(CCD). The optimum hydrolysis condition suggested was a temperature of 55.76 °C, enzyme
concentration of 1.80% and pH of 9. The experimental result for yield (9.45%) was higher while
the experimental result for DH (15.01%) was lower than the predicted values of the responses
using the quadratic model, which were 5.67% and 16.73%, respectively. The findings for the
functional properties showed that the Nitrogen Solubility Index (NSI) of EPH was 85%. The
emulsion stability index (ESI) of EPH was shown to decrease with the increase hydrolysate
concentration (0.1%, 0.5%, 1.0%) while the foam expansion of EPH showed an increase with
the increase in concentration. High solubility and the ability of EPH to emulsify and form foam
show its potential for use as a natural binding and emulsifying agent.
The objective of this study is to establish conditions that allow optimal yield and antioxidant
activity for Golden Apple Snail (GAS) (Pomacea canaliculata) protein hydrolysate by employing
response surface methodology (RSM). A three level, face-centered, central composite design
(CCD) was adapted to assess the effects of temperature (45–65˚C); pH (8–10); the ratio of
enzyme to substrate (2–4%); and hydrolysis time (60–180 min). The antioxidative activity
of the hydrolysate obtained under optimized conditions was then evaluated via the following
metrics: hydroxyl radical scavenging, reducing power, and chelating effects on ferrous ion.
Established optimal conditions for the enzymatic protein hydrolysis of GAS were a temperature
of 45˚C, a pH of 10, an enzyme concentration of 2%, and hydrolysis time of 159 minutes. The
optimized GAS protein hydrolysate produced an experimental yield of 9.72% and antioxidant
activity of 73.54%—slightly less than the predicted yield of 11.36% and antioxidant activity of
78.88%. The optimized GAS protein hydrolysate formed demonstrated both higher chelating
effects and hydroxyl scavenging activity but had lower reducing power. These results suggest
that GAS protein hydrolysate holds potential as a natural antioxidant for use in food processing.
The aim of this work is to study the effect of hydrocolloids; guar gum (GG), xanthan gum (XG) and carboxymethyl cellulose (CMC) on the physicochemical properties, microbiological quality and sensory properties in order to investigate the potential of applying fermented cassava (tapai ubi) in ice cream. Fermented cassava ice cream (FCI) incorporated with the three types of hydrocolloid was prepared and the protein content, pH value, overrun, colour, hardness, microstructure, FTIR spectrum and sensory acceptance of all samples were determined. Fermented cassava ice cream incorporated with XG showed the highest protein content (14.88%), pH value (pH 6.07), and overrun value (4.27%) as compared to the fermented cassava ice cream incorporated with GG and CMC. Meanwhile, ice cream incorporated with GG possessed the highest L* (94.43) and hardness (3693.15 g) value as compared to XG and CMC. The microstructure study showed that the difference in uniformity at the interface obtained with different types of the hydrocolloids added demonstrated the effect of fat absorption at the air interfaces. The FTIR spectrum investigated indicated that the addition of the fermented cassava to FCI had increased the OH group in the ice cream as compared to the control. All samples were microbial safe as the total plate counts in all samples were below the standard as prescribed in Food Act 1983 with no presence of E. coli . In conclusion, fermented cassava ice cream with XG showed the good quality in terms of its pH value, overrun, total plate count and overall acceptability.
The aim of this work is to study the effect of hydrocolloids (guar gum, xanthan gum and carboxymethyl cellulose (CMC) on the physical properties and sensory evaluation of ice cream produced in order to investigate the potential of applying fermented glutinous rice (tapai pulut) as a value-added ingredient. The addition of 25% fermented glutinous rice was the most reliable amount to enhance the physical and sensory properties of ice cream when incorporating hydrocolloids. The addition of hydrocolloids significantly (p < 0.05) increased the pH, firmness, overrun, and melting rate of fermented glutinous rice ice cream. The addition of guar gum scored the highest firmness value (5403 g) followed by CMC (4630 g) and xanthan gum (3481g). Fermented glutinous rice ice cream with xanthan gum added, induced a noticeable change in overrun value (62%) while the addition of CMC decreased the melting rate compared to the control. The FTIR spectrum of fermented glutinous rice ice cream with different hydrocolloids containing carboxyl, amide and carbonyl group was appeared at 3362-3379 cm-1 , 1639-1640 cm-1 and 1026-1064 cm-1, respectively. In conclusion, the addition of xanthan gum presented great potential to improve the quality of fermented glutinous rice ice cream produced in terms of its firmness, overrun and melting rate.
This study determined the antioxidant and angiotensin I-converting enzyme (ACE) inhibitory
activity of fractionated (3, 5, 10kDa) eel protein hydrolysate (EPH), which was prepared
enzymatically using alcalase. The bioactivities observed were reducing power, metal chelating
activity, 1, 1-diphenyl-2-picrylhydrazyl (DPPH) radical scavenging activity, hydroxyl radical
scavenging activity, and ACE inhibitory activity. The results showed that the EPH at 5 kDa
had significantly (p
The enzymatic hydrolysis of lead tree seed protein with alcalase to obtain Lead Tree Seed Hydrosylate (LTSH) was optimized using response surface methodology (RSM). A three- tiered, factor face centered, central composite design (CCD) was used to study the influence of four independent variables namely: pH (7–9); hydrolysis temperature (50oC, 55oC, 60oC); hydrolysis time (30 min, 60 min, 90 min); and enzyme/substrate (1%, 2%, 3%) ratio on both yield and antioxidant activity. The CCD consisted of twenty-four experimental points and six replicates of central points. All data were analyzed using Design-Expert Software. The optimum conditions obtained from experiments were a pH of 9; an enzyme to substrate ratio of 2%; a hydrolysis time of 90 min; and a temperature of 55°C. Results showed that LTSH derived from optimized hydrolysis exhibited effective ferrous ion chelating activity (92.79%) and strong reducing power (A700 = 3.82) at a concentration of 20 mg/ml. LTSH also demonstrated high DPPH radical scavenging activity (76.21%; IC50 1.99 mg/ml), as well as hydroxyl radical scavenging activity (66.72%; IC50 2.45 mg/ml). Superoxide anion scavenging activity was 55.71% (IC50 3.89 mg/ml) at 20 mg/ml. These results suggest that LTSH has potential as a natural antioxidant of functional food and for use in food processing.