Effect of Dairy Protein Blends on Texture of High Protein Bars

Imtiaz, Sameer; Kuhn-Sherlock, B.; Campbell, Monica

doi:10.1111/j.1745-4603.2011.00337.x

Cited by 33 publications

(44 citation statements)

References 10 publications

(19 reference statements)

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“…Extrusion involves combined mechanical shear, pressure and thermal energy to form products with desirable texture and can be used to produce low‐moisture, shelf‐stable crisps that can be incorporated into nutrition bars or other products. However, the direct use of high amounts of whey protein in powder form in such products increases the hygroscopic properties, thus causing deterioration of the end‐product textural and shelf life qualities (McMahon et al ., ; Imtiaz et al ., ). Extrusion is an effective process to utilise whey proteins in expanded, nutrient‐enriched new products such as protein‐fortified puffed snacks, meat analogues, cheese analogues and high‐fibre products with enhanced functional and nutritional profiles (Walsh & Wood, ; Onwulata et al ., ).…”

Section: Introductionmentioning

confidence: 97%

Prebiotic fibre‐incorporated whey protein crisps processed by supercritical fluid extrusion

Paraman

Supriyadi

Wagner

et al. 2013

Int J of Food Sci Tech

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Summary Prebiotic soluble fibre (fructooligosaccharides)‐incorporated whey protein crisps were produced by low‐shear supercritical fluid extrusion (SCFX), which utilises supercritical CO2 as an expansion agent instead of steam. Protein crisps with desirable qualities were obtained with a formulation containing 8% prebiotic fibre and 60% whey protein concentrate (WPC‐80), which gave the final product with a protein content of 49.6% (w/w). A maximum of 70% WPC‐80 and 8% prebiotic fibre could be incorporated to produce expanded protein crisps; however, increasing WPC‐80 from 50% to 70% decreased the end‐product expansion ratio from 3.1 to 1.2 and increased the product hardness and piece density from 1.3 to 2.8 kN and 0.63 to 0.75 g mL−1, respectively. Addition of 8% prebiotic fibre did not affect the textural qualities of final products. The process produced an expanded protein matrix with unique internal microstructure of uniformly distributed closed cells. Amino acid analysis indicated that 90% of the total lysine and 92% of the total essential amino acids were retained after SCFX processing and oven‐drying, indicating the preservation of protein nutritional quality during the process.

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Section: Introductionmentioning

confidence: 97%

Prebiotic fibre‐incorporated whey protein crisps processed by supercritical fluid extrusion

Paraman

Supriyadi

Wagner

et al. 2013

Int J of Food Sci Tech

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“…Formulating HPN bars with 20% to 50% protein (w/w) is a challenge as inclusion at these levels adversely affects texture and shortens sensory shelf life. High‐protein (that is, ≥ 80% protein w/w) milk protein concentrate (MPC) powders produce HPN bars that quickly harden during storage and lack cohesion (Loveday and others ; Imtiaz and others ; Banach and others ). Whey protein concentrate (WPC) or isolate (WPI), specifically their hydrolysates, produce texturally stable HPN bars (McMahon and others ).…”

Section: Introductionmentioning

confidence: 99%

Particle Size of Milk Protein Concentrate Powder Affects the Texture of High‐Protein Nutrition Bars During Storage

Banach

Clark

Lamsal

2017

Journal of Food Science

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Milk protein concentrate powder with 85% protein (MPC85) was jet-milled to give 2 particle size distributions (that is, JM-Coarse and JM-Fine) or freeze-dried (FD), in order to improve the functional properties of MPC85 for use in high-protein nutrition (HPN) bars. Volume-weighted mean diameter decreased from 86 μm to 49, 22, and 8 μm in FD, JM-Coarse, and JM-Fine, respectively (P < 0.05). The MPC85 powders modified by jet-milling and freeze-drying were significantly denser than the control MPC85 (P < 0.05). Volume of occluded air in the modified powders decreased (P < 0.05) by an order of magnitude, yet only FD possessed a lower volume of interstitial air (P < 0.05). Particle size reduction and freeze-drying MPC85 decreased its water holding capacity and improved its dispersibility by at least 20%. Contact angle measurements showed that these modifications increased initial hydrophobicity and did not improve wettability. HPN bars made from JM-Fine or FD were firmer by 40 or 17 N, respectively, than the control on day 0 (P < 0.05). HPN bar maximum compressive force increased by 38%, 33%, and 242% after 42 d at 32 °C when formulated with JM-Fine, FD, or control MPC85, respectively. HPN bars prepared with JM-Fine were less crumbly than those formulated with control or FD MPC85. Physically altering the particle structure of MPC85 improved its ability to plasticize within HPN bars and this improved their cohesiveness and textural stability. Volume-weighted mean diameter decreased from 86 micron to 49, 22, and 8 micron in FD, JMCoarse, and JM-Fine, respectively (P < 0.05). The MPC85 powders modified by jet-milling and freeze-drying were significantly denser than the control MPC85 (P < 0.05). Volume of occluded air in the modified powders decreased (P < 0.05) by an order of magnitude, yet only FD possessed a lower volume of interstitial air (P < 0.05). Physical modifications like particle size reduction or freeze-drying of MPC85 decreased water holding capacity and improved dispersibility by at least 20%. Contact angle measurements showed that these modifications increased initial hydrophobicity, yet did not improve wettability. HPN bars made from FD or JM-Fine were firmer by 40 or 17 N, respectively, than the control on day 0 (P < 0.05). HPN bar maximum compressive force increased by 38, 33, and 242% after 42 days at 32°C when formulated with FD, JM-Fine, or control MPC85, respectively. HPN bars prepared with JMFine were less crumbly than those formulated with control or FD MPC85. Physically altering the particle structure of MPC85 improved its ability to plasticize within HPN bars and this improved their cohesiveness and textural stability.Keywords: Jet-milling, freeze-drying, protein bar, texture profile analysis (TPA), cohesiveness 3 Practical ApplicationMilk protein concentrate (MPC) powder particle size significantly influences the texture of high-protein nutrition (HPN) bars. Use of finely jet-milled MPC85 powder produced HPN bars with increased firmness and cohesiveness. Particle size reduction improve...

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“…Despite having positive flavor attributes and good nutritional quality, MPCs are rarely employed in high‐protein nutrition (HPN) bars containing 20% to 50% protein (Baldwin and Pearce ). Instead, whey and soy proteins including concentrates, isolates, and hydrolysates are used for better functionality (Imtiaz and others ).…”

Section: Introductionmentioning

confidence: 99%

“…HPN bars formulated with MPCs tend to have crumbly texture and lack cohesiveness (Li and others ). Another important textural parameter in HPN bars is hardness, which during storage increases to undesirable levels in HPN bars formulated with unmodified MPCs (Imtiaz and others ). The exact mechanism of instability in HPN bars formulated with unmodified MPCs is not clear, but likely due to a combination of moisture migration, limited free water availability, phase separation, and internal disulfide bond formation (Li and others ; Zhou and others ; Loveday and others ; McMahon and others ).…”

Section: Introductionmentioning

confidence: 99%

Characterization of Extruded and Toasted Milk Protein Concentrates

Banach

Clark

Lamsal

2013

Journal of Food Science

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Important functional properties of milk protein concentrate with 80% protein (MPC80), modified with low- and high-shear extrusion, or low-temperature toasting were compared. The effect of high- and low-shear profile screws in a corotating twin-screw extruder, and 4 different ramped temperature profiles with die temperatures of 65, 75, 90, and 120 °C were compared. Extrudates were pelletized, dried, and ground to a fine powder. Toasting was done at 75 and 110 °C for 4 h for milk protein modification. Extruded and toasted MPC80 had reduced protein solubility and surface hydrophobicity. Extrusion decreased water-holding capacity (WHC). Toasted MPC80 had increased WHC when treated at 75 °C, but WHC decreased when heated at 110 °C. The treatments had no strong influence on gel strength. Reduced and nonreduced sodium dodecyl sulfate polyacrylamide gel electrophoresis revealed peptide structural changes that occurred due to processing, especially for whey proteins. Results are discussed in terms of potential for application of extruded or toasted MPC80 in high-protein nutrition bar applications.

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Effect of Dairy Protein Blends on Texture of High Protein Bars

Cited by 33 publications

References 10 publications

Prebiotic fibre‐incorporated whey protein crisps processed by supercritical fluid extrusion

Prebiotic fibre‐incorporated whey protein crisps processed by supercritical fluid extrusion

Particle Size of Milk Protein Concentrate Powder Affects the Texture of High‐Protein Nutrition Bars During Storage

Characterization of Extruded and Toasted Milk Protein Concentrates

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