Continuous flow microwave processing has been successfully utilized in commercial production of homogenous foods, and now there is an opportunity to use this technology to enhance the quality of multiphase foods. However, due to the high temperatures and mechanical stress incurred by continuous processing, it is challenging to maintain food particulate shape, which would be necessary for consumer acceptance in products like soups. Covington, NC 413 and Oriental sweetpotato cubes (Ipomoea batatas), with orange, purple and white flesh, respectively, were subjected to various pretreatments in order to investigate their effects on reducing degradation of texture due to thermal processing. Control and treated samples were loaded into a stainless steel cell, heated in an oil bath to an internal temperature of 125 °C and held for 30 sec. Among the pretreatments examined a 2-step pretreatment that included soaking in 0.3M Na2CO3 at 25 °C for 1 h followed by low temperature blanching at 62 °C in 1% (w/v) CaCl 2 provided the greatest firmness retention for all sweetpotato cultivars. Covington cubes, which are the most sensitive to thermal degradation, were pretreated by the 2-step process and evaluated at temperatures ranging from 115-130 °C for 0-12.22 min. Across all temperatures and times, peak force to fracture of the tested cubes showed no significant difference (p0.05) illustrating the robustness of the pretreatment. The Hunter L*a*b* color values showed that the pretreatment application and subsequent processing caused significant decreases in all components, but the values stayed within what has been commonly reported for sweetpotatoes.;Since texture measurements indicated sweetpotatoes prepared by the 2-step pretreatment can maintain firmness at a level adequate to survive commercial processes, potential for use in high temperature thermal applications such as microwave processing was investigated. Dielectric property measurements showed that while dielectric constant did not change due to pretreatment, dielectric loss factor increased for pretreated Oriental and NC 413 sweetpotatoes when compared to raw samples and this was attributed to the application of CaCl2 during the pretreatment. Five microwave runs with the target temperatures of 115, 121, and 125 °C were conducted utilizing a pilot scale 100 kW system. Pretreated cubes were inserted into a carrier fluid of orange-fleshed sweetpotato puree and received microwave application at three points. After passing through the hold tube they were cooled, and collected in a pressurized tank outfitted with a sieve. All inserted sweetpotato cubes were recovered, and subjected to firmness and color measurements. For all cultivars, microwave processing caused a significant decrease in firmness as measured by peak compression force (N), however texture was firm enough for all cubes to stay intact after going through the microwave heating process. Microwave processing also caused a significant decrease in color components, but not to a level outside of what has been previously reported.;After creating a food particulate that could withstand continuous flow microwave processing, microbiological validation of a pilot scale 100 kW microwave system was attempted utilizing immobilized spore beads of Geobacillus stearothermophilus. Immobilized beads were placed in prefabricated cube-shaped particles made of polymethylpentene, which has been proven to heat more conservatively than food particles made from various vegetables. Prefabricated particles also contained magnets, which tracked their movement throughout the system and allowed for calculation of residence times. The prefabricated particles were inserted into a stream of orange-fleshed sweetpotato puree utilized as the carrier fluid and subjected to microwave application. At the end of the process they were collected and the immobilized spore beads were enumerated to determine surviving populations. Magnetic tracking showed that each particle was accounted for as it moved throughout the system unobstructed and spent 78+/-1 sec in the hold tube. Hold tube exit temperatures ranged from 96.9-129.9 °C due to variable microwave power. Log inactivation of G. stearothermophilus spores ranged from 0.20--2.05 and was most consistent when temperatures at the hold tube exit were stable. Based on the success of achieving free particle flow and utilization of immobilized spore beads as bioindicators, this study shows promise in achieving microbiological validation for a continuous flow microwave system.
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机译:连续流微波处理已成功用于同质食品的商业生产中,现在有机会使用该技术来提高多相食品的质量。然而,由于连续加工引起的高温和机械应力,保持食物颗粒形状是挑战性的,这对于消费者接受汤类产品来说是必需的。对NC,Covington,NC 413和东方甜薯块(Ipomoea batatas)分别具有橙色,紫色和白色的果肉进行了各种预处理,以研究其对减少热处理引起的质地降解的影响。将对照和处理过的样品装入不锈钢池中,在油浴中加热至内部温度125°C,并保持30秒。在所检查的预处理中,分两步进行的预处理包括在25°C的0.3M Na2CO3中浸泡1 h,然后在62°C的1%(w / v)CaCl 2低温热烫处理中,为所有甘薯提供了最大的牢固度品种。对热降解最敏感的Covington立方体通过两步过程进行了预处理,并在115-130°C的温度下评估了0-12.22分钟。在所有温度和时间范围内,测试立方体的断裂峰值力均无显着差异(p <0.05),说明了预处理的稳健性。 Hunter L * a * b *颜色值表明,预处理的应用和后续处理导致所有成分的显着减少,但该值仍保持在报道的甘薯范围内。由于纹理测量表明,通过两步法制备的甘薯预处理可以将牢固度维持在足以在商业流程中生存的水平,因此研究了在高温热应用(如微波处理)中使用的潜力。介电性能测量表明,尽管介电常数未因预处理而变化,但与原始样品相比,经预处理的Oriental和NC 413甘薯的介电损耗因子有所增加,这归因于在预处理过程中使用了CaCl2。使用中试规模100 kW系统进行了五次微波运行,目标温度分别为115、121和125°C。将经过预处理的立方体插入橙皮甜土豆泥的载体液中,并在三个点施加微波。通过保持管后,将它们冷却,并收集在装有筛子的加压罐中。回收所有插入的甘薯块,并进行硬度和颜色测量。对于所有品种,通过峰值压缩力(N)进行测量,微波处理都会导致硬度显着下降,但是质地坚硬,所有立方体在经过微波加热过程后仍能保持完整。微波处理还导致颜色成分显着减少,但未达到先前报道的水平。;在产生了可以承受连续流微波处理的食物颗粒后,尝试了中试规模100 kW微波系统的微生物学验证利用固定的嗜热地热芽孢杆菌的孢子珠。将固定的珠子放在由聚甲基戊烯制成的预制立方体形状的颗粒中,事实证明,该颗粒比由各种蔬菜制成的食物颗粒更保守地加热。预制颗粒还包含磁体,该磁体跟踪它们在整个系统中的运动并允许计算停留时间。将预制的颗粒插入用作载体流体的橙皮甜土豆泥流中,并进行微波处理。在该过程结束时,将它们收集起来,并枚举固定的孢子珠,以确定存活的种群。磁跟踪表明,每个粒子在整个系统中畅通无阻地占据了空间,并在固定管中停留了78 +/- 1秒。由于微波功率的变化,保温管的出口温度范围为96.9-129.9°C。嗜热链球菌孢子的对数失活范围为0.20--2.05,当保持管出口温度稳定时最一致。基于成功实现自由颗粒流动和利用固定的孢子珠作为生物指示剂的成功,这项研究显示了实现连续流微波系统微生物验证的希望。
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