Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
Ogier, J.-C.
Lafarge, V.
Girard, V.
Rault, A.
Maladen, V.
Gruss, A.
Leveau, J.-Y.
and
Delacroix-Buchet, A.
2004.
Molecular Fingerprinting of Dairy Microbial Ecosystems by Use of Temporal Temperature and Denaturing Gradient Gel Electrophoresis.
Applied and Environmental Microbiology,
Vol. 70,
Issue. 9,
p.
5628.
Deeth, H. C.
and
Fitz-Gerald, C. H.
2006.
Advanced Dairy Chemistry Volume 2 Lipids.
p.
481.
Marchand, Sophie
Coudijzer, Katleen
Heyndrickx, Marc
Dewettinck, Koen
and
De Block, Jan
2008.
Selective determination of the heat-resistant proteolytic activity of bacterial origin in raw milk.
International Dairy Journal,
Vol. 18,
Issue. 5,
p.
514.
Arvanitoyannis, Ioannis S.
Varzakas, Theodoros H.
and
Koukaliaroglou‐Van Houwelingen, Maria
2009.
HACCP and ISO 22000.
p.
89.
Izidoro, Thiago Braga
Pereira, Juliano Gonçalves
Soares, Vanessa Mendonça
Spina, Thiago Luiz Belém
and
Pinto, José Paes de Almeida Nogueira
2013.
Atividade proteolítica de bactérias psicrotróficas em leites estocados em diferentes temperaturas.
Revista Ceres,
Vol. 60,
Issue. 4,
p.
452.
Burdychová, Radka
and
Hoferková, Petra
2014.
Monitoring of psychrotrophic microorganisms in raw milk.
Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis,
Vol. 56,
Issue. 4,
p.
21.
Remenant, Benoît
Jaffrès, Emmanuel
Dousset, Xavier
Pilet, Marie-France
and
Zagorec, Monique
2015.
Bacterial spoilers of food: Behavior, fitness and functional properties.
Food Microbiology,
Vol. 45,
Issue. ,
p.
45.
Stoeckel, Marina
Lidolt, Melanie
Stressler, Timo
Fischer, Lutz
Wenning, Mareike
and
Hinrichs, Jörg
2016.
Heat stability of indigenous milk plasmin and proteases from Pseudomonas: A challenge in the production of ultra-high temperature milk products.
International Dairy Journal,
Vol. 61,
Issue. ,
p.
250.
Stoeckel, Marina
Lidolt, Melanie
Achberger, Veronika
Glück, Claudia
Krewinkel, Manuel
Stressler, Timo
von Neubeck, Mario
Wenning, Mareike
Scherer, Siegfried
Fischer, Lutz
and
Hinrichs, Jörg
2016.
Growth of Pseudomonas weihenstephanensis, Pseudomonas proteolytica and Pseudomonas sp. in raw milk: Impact of residual heat-stable enzyme activity on stability of UHT milk during shelf-life.
International Dairy Journal,
Vol. 59,
Issue. ,
p.
20.
Brasca, Milena
Decimo, Marilù
Morandi, Stefano
Machado, Solimar Gonçalves
Bagliniére, François
and
Vanetti, Maria Cristina Dantas
2017.
Microbiology in Dairy Processing.
p.
37.
Martin, Nicole H.
Boor, Kathryn J.
and
Wiedmann, Martin
2018.
Symposium review: Effect of post-pasteurization contamination on fluid milk quality.
Journal of Dairy Science,
Vol. 101,
Issue. 1,
p.
861.
Anema, Skelte G.
2019.
Age Gelation, Sedimentation, and Creaming in UHT Milk: A Review.
Comprehensive Reviews in Food Science and Food Safety,
Vol. 18,
Issue. 1,
p.
140.
Zhang, Chunyue
Bijl, Etske
Svensson, Birgitta
and
Hettinga, Kasper
2019.
The Extracellular Protease AprX from Pseudomonas and its Spoilage Potential for UHT Milk: A Review.
Comprehensive Reviews in Food Science and Food Safety,
Vol. 18,
Issue. 4,
p.
834.
D'Incecco, Paolo
Brasca, Milena
Rosi, Veronica
Morandi, Stefano
Ferranti, Pasquale
Picariello, Gianluca
and
Pellegrino, Luisa
2019.
Bacterial proteolysis of casein leading to UHT milk gelation: An applicative study.
Food Chemistry,
Vol. 292,
Issue. ,
p.
217.
Colantuono, Antonio
D'Incecco, Paolo
Fortina, M. Grazia
Rosi, Veronica
Ricci, Giovanni
and
Pellegrino, Luisa
2020.
Milk substrates influence proteolytic activity of Pseudomonas fluorescens strains.
Food Control,
Vol. 111,
Issue. ,
p.
107063.
Lau, S.
Trmcic, A.
Martin, N.H.
Wiedmann, M.
and
Murphy, S.I.
2022.
Development of a Monte Carlo simulation model to predict pasteurized fluid milk spoilage due to post-pasteurization contamination with gram-negative bacteria.
Journal of Dairy Science,
Vol. 105,
Issue. 3,
p.
1978.
Lott, T.T.
Stelick, A.N.
Wiedmann, M.
and
Martin, N.H.
2023.
Gram-negative post-pasteurization contamination patterns of single-serve fluid milk produced in 4 different processing facilities.
Journal of Dairy Science,