Calcium hydroxide as a processing base in alkali-aided pH-shift protein recovery process

The agricultural sector is thought to be responsible for around 30% of the anthropogenic climate change and it is well established that high meat consumption has a tremendous impact on the environment. Rapeseed is mainly used for production of vegetable oil, but press cake has high protein content with the potential for incorporation into new plant protein-based foods. Protein was recovered from press cakes generated from different oil pressing processes. Industrially cold-pressed, hot-pressed, and solvent-extracted rapeseed press cake and the effect of heat treatment in the recovery process was assessed. Protein recovery yield, protein concentration and emulsifying properties were analyzed. Cold-pressed rapeseed press cake (RPC) recovered in the absence of heat, yielded the highest protein recovery (45%) followed by hot-pressed rapeseed meal (RM) (26%) and solvent-extracted RM (5%). Exposure to heat during recovery significantly reduced the yield for cold-pressed RPC but no difference was found for hot-pressed RM. The protein recovery yield was improved for solvent-extracted RM when heat was applied in the recovery process. The ability to stabilize emulsions was highest for protein recovered from cold-pressed RPC, followed by hot-pressed RM and solvent-extracted RM, and was in the same range as commercial emulsifying agents. Heat treatment during recovery significantly reduced the emulsifying properties for all pressing methods examined. This study suggests that cold-pressed rapeseed press cake without heat in the recovery process could be a successful strategy for an efficient recovery of rapeseed protein with good emulsifying properties.

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Optimization of protein recovery from bovine lung by pH shift process using response surface methodology

Journal of the Science of Food and Agriculture ◽

10.1002/jsfa.8678 ◽

2017 ◽

Vol 98 (5) ◽

pp. 1951-1960 ◽

Cited By ~ 11

Author(s):

Sarah A Lynch ◽

Carlos Álvarez ◽

Eileen E O'Neill ◽

Derek F Keenan ◽

Anne Maria Mullen

Keyword(s):

Response Surface Methodology ◽

Response Surface ◽

Protein Recovery ◽

Ph Shift

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Suppression of proteolysis of North Pacific krill Euphausia pacifica meat during protein recovery process to improve the thermal gel-forming ability of the recovered protein by using protease inhibitors

NIPPON SUISAN GAKKAISHI ◽

10.2331/suisan.17-00051 ◽

2018 ◽

Vol 84 (2) ◽

pp. 261-268 ◽

Cited By ~ 1

Author(s):

KAYO AMANO ◽

KIGEN TAKAHASHI ◽

EMIKO OKAZAKI ◽

KAZUFUMI OSAKO

Keyword(s):

Protease Inhibitors ◽

North Pacific ◽

Recovery Process ◽

Protein Recovery ◽

Euphausia Pacifica ◽

Gel Forming Ability

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Survival of Escherichia coli after Isoelectric Solubilization and Precipitation of Fish Protein

Journal of Food Protection ◽

10.4315/0362-028x-72.7.1398 ◽

2009 ◽

Vol 72 (7) ◽

pp. 1398-1403 ◽

Cited By ~ 19

Author(s):

L. R. LANSDOWNE ◽

S. BEAMER ◽

J. JACZYNSKI ◽

K. E. MATAK

Keyword(s):

Escherichia Coli ◽

Recovery Process ◽

Alkaline Treatment ◽

Insoluble Fraction ◽

Microbial Reduction ◽

Protein Recovery ◽

Protein Solution ◽

Initial Inoculum ◽

E Coli ◽

Log Reduction

Protein recovery for fish processing by-products utilizes extreme pH shifts for isoelectric solubilization and precipitation. The purpose of this study was to determine if Escherichia coli would survive exposure to the extreme pH shifts during the protein recovery process. Fresh rainbow trout were beheaded, gutted, and minced and then inoculated with approximately 109 CFU of E. coli ATCC 25922 per g, homogenized, and brought to the target pH of 2.0, 3.0, 11.5, or 12.5 by the addition of concentrated hydrochloric acid or sodium hydroxide to solubilize muscle proteins. The homogenate was blended and centrifuged to separate the lipid and insoluble components (bones, skin, insoluble protein, etc.) from the protein solution. The protein solution was subjected to a second pH shift (pH 5.5) resulting in protein precipitation that was recovered with centrifugation. Microbial analysis was conducted on each fraction (i.e., lipid, insoluble components, protein, and water) with selective and nonselective media. The sums of the surviving E. coli in these fractions were compared with the initial inoculum. The greatest total microbial reduction occurred when the pH was shifted to 12.5 (P < 0.05), i.e., a 4.4-log reduction of cells on nonselective media and a 6.0-log reduction of cells on selective media. The use of selective and nonselective media showed that there was significant (P < 0.05) injury sustained by cells exposed to alkaline treatment (pH 11.5 and 12.5) in all fractions except the insoluble fraction at pH 11.5. Increasing the exposure time or the pH may result in greater bacterial reductions in the recovered protein.

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Optimization of an industrial primary protein recovery process by Design of Experiment

New Biotechnology ◽

10.1016/j.nbt.2014.05.1906 ◽

2014 ◽

Vol 31 ◽

pp. S120-S121

Author(s):

Tanja Buch ◽

Ian Marison

Keyword(s):

Design Of Experiment ◽

Recovery Process ◽

Protein Recovery

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ISOLASI PROTEIN SELAMA PROSES PENGAMBILAN KITIN DARI KULIT UDANG

Jurnal Teknik Kimia USU ◽

10.32734/jtk.v5i2.1534 ◽

2016 ◽

Vol 5 (2) ◽

pp. 43-48

Author(s):

Kherliyanda Febriani ◽

Fitri Hariani Nurza ◽

Iriany

Keyword(s):

Reaction Temperature ◽

Protein Extraction ◽

Economic Value ◽

Reaction Times ◽

Recovery Process ◽

Extraction Process ◽

High Yield ◽

Protein Recovery ◽

Shrimp Shells ◽

Shrimp Shell

Shrimp is one of the Indonesia fishery commodities with high economic value. The production of shrimp shells is usually 40-45% from crude shrimp. Shrimp shell contain protein, chitin, minerals and carotenoids. It is very potential to be used as materials for isolation of protein.This experiment is to determine factors that effect protein recovery and optimize deproteination processconditions to produce high yield of protein. The design of experiment used response surface methodology. It is 2 steps consist of deproteination and protein extraction process using shrimp shells and KOH solution in comparison 1:10 (w/v). The concentration of KOH are1,3 M; 2 M; 3 M; 4 M; 4,7 M. The reaction temperatures are37 oC; 40 oC; 45 oC; 50 oC; 53 oCand the reaction times are 40 minutes, 60 minutes, 90 minutes, 120 minutes, 140 minutes. Reaction temperature is the main factor influence protein recovery process. The highest protein yield obtained is 64,5826 % with protein content is 86,24% using KOH solution 2,98 M, reaction temperature 45,76 ºC and reaction time 90,51 minute. Economic potential by protein recovery during isolation of chitin from shrimp shells is profitable.

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Impact of Processing Technology on Macro- and Micronutrient Profile of Protein-Enriched Products from Fish Backbones

Foods ◽

10.3390/foods10050950 ◽

2021 ◽

Vol 10 (5) ◽

pp. 950

Author(s):

Mehdi Abdollahi ◽

Haizhou Wu ◽

Ingrid Undeland

Keyword(s):

Protein Isolate ◽

Processing Technology ◽

Protein Recovery ◽

Food Ingredients ◽

Protein Isolates ◽

Ph Shift ◽

Vitamins E And C ◽

Copper Zinc ◽

Mechanical Separation ◽

Mechanically Separated Meat

Impacts of processing technology (mechanical separation and pH-shift processing) on protein recovery from salmon, herring and cod backbones and the content of macro- and micronutrients in the recovered protein enriched products were investigated. Mechanical separation led to higher protein recovery compared with the pH-shift process and using both techniques, recovery ranked the species as herring > salmon > cod. However, the pH-shift process up-concentrated protein from herring and salmon backbones more efficiently than mechanical separation by removing more fat and ash. This consequently reduced n-3 PUFA and vitamin D content in their protein isolates compared with the backbones and mechanically separated meat (MSM). Cod protein isolate, however, contained higher levels of these nutrients compared with MSM. Mechanical separation concentrated vitamins E and C in salmon MSM but not for cod and herring. Opposite, pH-shift processing reduced levels of these two vitamins for cod and herring backbones, while vitamins D and C were reduced for salmon. For minerals, selenium, calcium, magnesium, and potassium were lower in protein isolates than MSM, while copper, zinc, iron and manganese were similar or higher. Overall, there is a major potential for upcycling of fish backbones to food ingredients, but processing technology should be carefully balanced against the desired nutrient profile and final application area.

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