Microfluidization of full‐fat ice cream mixes: Effects on rheology and microstructure

Cavender, George; Kerr, William L.

doi:10.1111/jfpe.13350

Cited by 20 publications

(9 citation statements)

References 45 publications

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“…The increase in fat contents in the ice cream contributes to the richness in mouthfeel and reduces ice crystal formation (Mostafavi, 2019). The higher fat content was attributed to the higher overrun, resulting in the low formation of ice crystals, and subsequently prolonging the shelf‐life of the ice cream (Cavender & Kerr, 2019). According to Akbari et al.…”

Section: Discussionmentioning

confidence: 99%

Value addition to ice cream by fortification with okara and probiotic

Ibrahim

Kamaruding

Ismail

et al. 2021

Food Processing Preservation

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Synbiotic ice cream offers sufficient viable probiotics and value‐added nutrients to satisfy health needs. This study aimed to formulate the optimum synbiotic ice cream incorporated with okara (1–3%) and the probiotic, Lactobacillus plantarum (ATCC 8014). Results showed a viscous texture was produced when more than 2% okara was added to ice cream. This formulation also minimally caused ice cream to melt for around 90 min at a melting rate of 19–76%. Furthermore, ice cream incorporated with okara had an increase in protein content (>5%) and a decrease in fat content (>13%) compared with the control (no okara), indicating that it is a low‐fat item. The addition of more than 2% okara increased the viability of L. plantarum on day 60. Overall, 1% okara addition showed significant acceptability for potential symbiotic ice cream formulation. Novelty impact statement One of the greatest challenges in the ice cream manufacturing industry is the short shelf‐life and fast melting rate of milk‐based ice cream, as it lowers a storage period and affects the textural characteristic. To overcome the said problems, the use of soybean by‐product (okara), a potential prebiotic for dietary fiber source, was found to minimally caused ice cream to melt and was able to increase the viability of Lactobacillus plantarum. The function of dietary fiber is not only able to support the growth of probiotics, but also scientifically proven to strengthen the digestive system and reduce the possibility of developing diseases including cardiovascular diseases, diabetes, constipation, and bowel cancer.

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Section: Discussionmentioning

confidence: 99%

Value addition to ice cream by fortification with okara and probiotic

Ibrahim

Kamaruding

Ismail

et al. 2021

Food Processing Preservation

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“…Ice cream is world-famous high-vital emulsified milk sweets made from air cells milk fat, colloidal protein, fortifiers (Ghandehari, Barzegar, Gavlighi, Sahari, & Mohammadian, 2020;Pintor, Escalona, & Totosaus, 2017), stabilizers, emulsifiers, sweeteners, and colors (Cavender & Kerr, 2020;Panwar, Shubhashini, & Kapoor, 2019). It is one of the most commonly offered and enjoyed by youngsters and other age people around the world (Ayar, Siçramaz, Ozturk, & Ozturk, 2018;Azari, Khomeiri, Ghafouri, & Aghajani, 2017;Caniyilmaz, Uçarkuş, & Karaman, 2016).…”

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confidence: 99%

Utilization of jamun pomace as functional ingredients to enhance the physico‐chemical and sensory characteristics of ice cream

Shelke

Kad

Yenge

et al. 2020

J. Food Process. Preserv.

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Jamun (Syzygium cumini L.) is a tropical fruit crop that belongs to the Myrtaceae family (Singh, Paswan, & Rai, 2019).). India and Indonesia are viewed as the origin of jamun fruits. Jamun has recently become famous for its high nutritional value in food processing areas. Jamun provides ellagic acid and glucoside jamboline that reduces blood sugar and has excellent diabetes control; it is very effective to treat jaundice, kidney stone, blood pressure, sore throat, constipation, vomiting, and diarrhea. As a source of food nutrients and phytochemical, jamun fruit comes to the attention of food manufacturers and food scientists (Bukya & Madane, 2018). This fruit is only accessible in June and July months during monsoon. The production of jamun fruits is unorganized in India, with significant annual losses between 20% and 30% after the harvest (Patil, Thorat, & Rajasekaran., 2012). Jamun fruits should be preserved and processed into valuable products to minimize post-harvest losses. A large number of food products are prepared from Jamun fruits. During jamun juice processing a large amount of pomace is produced which is not finding any appropriate use except for the utilization as an animal feed or landfilling. Majority of by-products obtained from the food industry are dumped in open space (Singh, Panesar, & Nanda, 2006). Fruit pomace can lead to a number of environmental challenges, such as surface and groundwater contamination, unless managed properly. Percolates produced from such by-products are responsible for the degradation of oxygen throughout the soil and the

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“…The formulation of ice cream, process design, and effects of different microstructural elements, such as air cells, ice crystals, and fat globule clusters, are responsible for the properties of ice cream [ 9 , 19 ]. Several studies have shown that high shear force and microfluidization of fat replacers affect the physical and structural properties of frozen dairy products [ 19 , 20 ]. A few recent studies have also shown that homogenization at high pressure (200–400 MPa) decreases the need for stabilizers [ 21 ] and facilitates greater interaction between proteins and polysaccharides, thus leading to a stable network structure [ 22 ].…”

Section: Introductionmentioning

confidence: 99%

Microstructure and Physicochemical Properties of Light Ice Cream: Effects of Extruded Microparticulated Whey Proteins and Process Design

Hossain

Petrov

Hensel

et al. 2021

Foods

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This study aimed to understand the influence of extruded microparticulated whey proteins (eMWPs) and process design in light ice cream processing by evaluating the microstructure and physicochemical properties. The inulin (T1), a commercial microparticulated whey protein (MWP) called simplesse (T2), a combination (T3), as well as eMWPs (as 50% volume of total particles): d50 < 3 µm (T4), and d50 > 5 µm (T5) were used as fat replacers. The first process design was pasteurization with subsequent homogenization (PH). The second process was homogenization with subsequent pasteurization (HP) for the production of ice cream (control, 12% fat, w/w; T1 to T5, 6% fat, w/w). The overrun of light ice cream treatments of PH was around 50%, except for T4 (61.82%), which was significantly higher (p < 0.01). On the other hand, the overrun of HP was around 40% for all treatments except T1. In both the PH and HP groups, the color intensities of treatments were statistically significant (p < 0.001). The melting behavior of light ice cream was also significantly different. The viscosity of all treatments was significant (p < 0.05) at a shear rate of 64.54 (1/s) for both cases of process design. A similar firmness in both the PH and HP groups was observed; however, the products with eMWPs were firmer compared to other light ice creams.

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Microfluidization of full‐fat ice cream mixes: Effects on rheology and microstructure

Cited by 20 publications

References 45 publications

Value addition to ice cream by fortification with okara and probiotic

Value addition to ice cream by fortification with okara and probiotic

Utilization of jamun pomace as functional ingredients to enhance the physico‐chemical and sensory characteristics of ice cream

Microstructure and Physicochemical Properties of Light Ice Cream: Effects of Extruded Microparticulated Whey Proteins and Process Design

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