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The purpose of this paper is to study the influence of crude palm oil (PO), canola oil (CO) and their blends on characteristics of fried plantain crisps at two different stages of ripening.

Plantain (Musa paradisiaca L.) samples were peeled, sliced into 3 mm slices, blanched at 70 °C for 3 min and dried. The slices were deep fried at 180 °C for different times.

There was no significant difference (p > 0.05) in the moisture loss rate and the crispiness of the crisps produced using PO and CO. Significant differences (p < 0.05) existed in the fat uptake and color properties of the crisps fried in the two oils. PO fried crisps absorbed 15 percent less oil in the unripe crisps samples and 21 percent less oil in the fully ripened crisps than CO. The browning index showed that the PO crisps had greater color changes than the crisps fried using CO. The difference between the crisps from 50:50 blends of PO: CO and CO was not statistically significant, while 70:30 blends improved the qualities of the crisps better than CO alone. Analysis of kinetics data showed that moisture loss, oil uptake and browning index followed a first-order kinetics model.

Understanding the interactions between ripening and processing methods is enhanced and use of crude PO for industrial deep-fat frying is encouraged.

This study aims to investigate the physicochemical and sensory characteristics of fried peanut cracker snacks coated with wheat (80%) and cassava (20%) composite flours.

The peanuts were sorted, boiled, drained, roasted, coated and fried at temperature of 150–180°C for 154.6–240 s. The fried peanut cracker-coated (FPCC) snacks produced were analyzed for proximate composition (moisture, crude fat, crude protein, crude fibre, total ash and carbohydrate contents), rancidity indices (peroxide value, free fatty acid and iodine value), physical properties, colour (lightness, redness and yellowness), texture (hardness, fracturability, adhesiveness and cohesiveness) and sensory qualities (taste, crispiness, colour, odour and overall acceptability).

There were significant differences in moisture (p = 0.000), crude fat (p = 0.001), crude protein (p = 0.000), crude fibre (p = 0.001), total ash (p = 0.00) and carbohydrate (p = 0.001). The range of values for moisture content, crude fat, crude protein, crude fibre, total ash and carbohydrate contents were 2.6%–4.9%, 27.1%–34.7%, 21.0%–26.3%, 3.1%–4.1%, 2.1%–2.5% and 33.9%–36.4%, respectively, while peroxide, free fatty acid and iodine values ranged from 1.2 to 2.0 mEq/kg, 32.8–47.0 mg KOH/g and 1.2–2.0 gI₂/100 g, respectively. The physical properties of the FPCCs showed decrease as the frying temperature and time increased. The values for lightness (L*), redness (a*) and yellowness (b*) ranged from 26.5 to 52.2, 11.4 to 22.0 and 37.0 to 42.5, while the texture attributes such as hardness (p = 0.001), fracturability (p = 0.023), adhesiveness (p = 0.001) and cohesiveness (p = 0.011) were significantly different and it ranged from 28.7 to 53.4 N, 28.6 to 48.3 N, 1.0 to 2.4 N/s and 0.0–0.1, respectively. The sensory score for wheat–cassava composite flours used for coating the snacks decreased as the frying temperature and time increased. The study shows that 20% of cassava flour incorporated into the formulation of coated snacks does not affect its overall acceptability.

There are scanty information/published works on physicochemical and sensory characteristics of fried peanut cracker coated with wheat–cassava composite flour.

This research work helps in producing fried peanut cracker coated with composite wheat–cassava flours.

The study shows that 20% of cassava flour incorporated into the formulation of coated snacks does not affect its overall acceptability.