Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-29T15:58:14.863Z Has data issue: false hasContentIssue false

Changes occurring in stabilized ultra-high-temperature-treated whole milk during storage

Published online by Cambridge University Press:  22 August 2018

Fernando César dos Santos
Affiliation:
Dairy Science and Technology Graduate Programme, University North of Paraná (UNOPAR), Londrina, 86041-100, Brazil
Fabiano Érisson da Cunha
Affiliation:
Department of Quality Assurance and Food Safety, CONFEPAR Cooperative Inc., Londrina, 86066-000, Brazil
Érika de Pádua Alves
Affiliation:
Dairy Science and Technology Graduate Programme, University North of Paraná (UNOPAR), Londrina, 86041-100, Brazil Department of Quality Assurance and Food Safety, CONFEPAR Cooperative Inc., Londrina, 86066-000, Brazil
Flávia de Almeida Bergonse Pereira
Affiliation:
Dairy Science and Technology Graduate Programme, University North of Paraná (UNOPAR), Londrina, 86041-100, Brazil
Elsa Helena Walter de Santana
Affiliation:
Dairy Science and Technology Graduate Programme, University North of Paraná (UNOPAR), Londrina, 86041-100, Brazil
Bruno Garcia Botaro*
Affiliation:
Dairy Science and Technology Graduate Programme, University North of Paraná (UNOPAR), Londrina, 86041-100, Brazil Department of Quality Assurance and Food Safety, CONFEPAR Cooperative Inc., Londrina, 86066-000, Brazil
*
*For correspondence; e-mail: [email protected]

Abstract

This Research Communication describes the relationship between casein, free fatty acids (FFAs) and the storage period of ultra-high temperature-treated (UHT) whole milk observed for a period of 120 d of labelled shelf-life. Moreover, we aim to estimate the daily rate of casein degradation in UHT whole milk, and the total length of time estimated for its full degradation. With this aim, ten sets of samples were evaluated from batches of UHT milk manufactured by a dairy processing plant in Parana State, Brazil on 10 different days. Each set was comprised of one liter of raw milk and 12 units of 1 litre cartons of UHT milk, and represented one batch of production. Total mesophilic (TMC), psychrotrophic (TPC), and somatic cell counts (SCC) of raw milk were assessed. UHT milk was assessed for fat (%), sialic acid (mg/l), casein (%), and FFA contents. TMC ranged from 3·5 × 106 to 3·1 × 107 CFU/ml; TPC, from 106 UFC/ml and higher; and SCC, from 18 × 104 SC/ml to 4·83 × 105 CS/ml. Casein (r = −0·991; R2 = 0·9822) and FFA (r = 0·962; R2 = 0·9245) contents, and storage time of UHT milk were correlated (P < 0·05). The rate of casein hydrolysis was estimated as 0·021 g/100 g UHT whole milk/day. A complete breakdown of casein was estimated to occur by the 560th day post-manufacture. Although age gelation was not observed in our study, the report herein corroborates the understanding that the microbiological quality and SCC of raw milk are important components involving the integrity of casein and lipids of UHT milk during shelf-life.

Type
Research Article
Copyright
Copyright © Hannah Dairy Research Foundation 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

Current address: Livestock Systems Research Department, Animal & Grassland Research and Innovation Centre Teagasc, Moorepark, Fermoy, Co. Cork, P61C 996, Ireland.

References

Association of Official Analytical Chemists – AOAC 2005 Dairy products: milk. In Official Methods of Analysis of AOAC INTERNATIONAL, 18th edition, pp. 451 (Eds. Horwitz, W & Latimer, GW Jr). Gaithersburg, USA: AOAC InternationalGoogle Scholar
Datta, N & Deeth, HC 2001 Age gelation of UHT milk – A review. Food and Bioproducts Processing 79 197210Google Scholar
Fernandes, AM, Bovo, F, Moretti, TS, Rosim, RE, Goncalves de Lima, C & Fernandes de Oliveira, CA 2008 Relationship between the somatic cell count in raw milk and the casein fractions of UHT milk. Australian Journal of Dairy Technology 63 4549Google Scholar
Houghtby, G, Marturin, L, Koenig, E & Messer, J 1992 Microbiological count methods. In Standard Methods for the Examination of Dairy Products, 16th edition, pp. 213246 (Ed. Marshall, RT). Washington, USA: American Public Health AssociationGoogle Scholar
Mahieu, H 1984 [Fast method of determination of free fatty acids in milk: ‘Lipo R’ method]. Revue de Médécine Vétérinaire 135 709716Google Scholar
Murphy, SC, Martin, NH, Barbano, DM & Wiedmann, M 2016 Influence of raw milk quality on processed dairy products: how do raw milk quality test results relate to product quality and yield? Journal of Dairy Science 99 1012810149Google Scholar
Neelima, PSRR, Sharma, R & Rajput, YS 2012 Direct estimation of sialic acid in milk and milk products by fluorimetry and its application in detection of sweet whey adulteration in milk. Journal of Dairy Research 79 495501Google Scholar
Oliveira, AP & Faria, RB 2010 [Non-integer orders in chemical kinetics]. Química Nova 33 14121415Google Scholar
Panfil-Kuncewicz, H, Kuncewicz, A & Juskiewicz, M 2005 Influence of storage conditions on changes in the fat fraction of UHT milk. Polish Journal of Food and Nutrition Sciences 14/55 341348Google Scholar
Pinto, CLO, Machado, SG, Cardoso, RR & Vanetti, MCD 2016 [Sedimentation, proteolytic activity and proteolysis of whole UHT milk during storage]. Revista do Instituto de Laticínios Cândido Tostes 71 197205Google Scholar
Vorob'ev, MM & Kochetkov, KA 2016 Determination of kinetic parameters for casein hydrolysis by chymotrypsin using two ranges of substrate concentration. International Dairy Journal 61 7684Google Scholar