Fishery Products brings together details of all the major methodologies used to assess the quality of fishery products in the widest sense. Subject coverage of this important book includes chapters on assessment of authenticity, and several chapters on quality assessment using various methods, such as:
- Texture measurement
- Electronic nose and tongue
- Colour measurement
Chapter 1 Basic facts and figures (Jörg Oehlenschläger and Hartmut Rehbein).
1.2 World fishery production
1.3 Categories of fish species
1.4 Fish muscle
1.5 Nutritional composition
1.8 Post mortem changes in fish muscle
1.9 References and further reading
Chapter 2 Traditional methods (Peter Howgate).
2.4 Volatile acids
2.5 Volatile reducing substances
2.7 Proteolysis and amino acids
2.9 Refractive index of eye fluids
2.10 Discussion and summary
Chapter 3 Biogenic amines (Rogério Mendes).
3.2 Factors affecting amine decarboxylase activity
3.3 Safety aspects
3.4 Quality assessment
3.5 Regulatory issues
3.6 Methods of biogenic amine determination
Chapter 4 ATP–derived products and K–value determination (Margarita Tejada).
4.1 In vivo role of nucleotides
4.2 Post mortem changes
4.3 Methodology for evaluating the K–value or related compounds
Chapter 5 VIS/NIR spectroscopy (Heidi Anita Nilsen and Karsten Heia).
5.2 Analytical principles and measurements
5.3 Constituents: assessment of chemical composition
5.4 Freshness and storage time
5.7 Other quality parameters
5.8 Summary and future perspectives
Chapter 6 Electronic nose and electronic tongue (Corrado Di Natale and Gudrun Ólafsdóttir).
6.1 Introduction to the electronic nose and olfaction
6.2 Application of the electronic nose and electronic tongue
6.3 Colorimetric techniques, optical equipment and consumer electronics
6.4 Classification of fish odours
6.5 Quality indicators in fish during chilled storage: gas chromatography analysis of volatile compounds
6.6 Application of the electronic nose for evaluation of fish freshness
6.7 Combined electronic noses for estimating fish freshness
6.8 Conclusions and future outlook
Chapter 7 Colour measurement (Reinhard Schubring).
7.3 Novel methods of colour evaluation
7.4 Colour measurement on fish and fishery products
Chapter 8 Differential scanning calorimetry (Reinhard Schubring).
8.2 Principle of function of the instruments
8.3 First applications of DSC on fish muscle and other seafood
8.4 Recent applications of DSC for investigating quality and safety
Chapter 9 Instrumental texture measurement (Mercedes Careche and Marta Barroso).
9.2 Instrumental texture
9.3 Texture measurement for quality classification or prediction
Chapter 10 Image processing (Michael Kroeger).
10.2 Quality characteristics from images
10.3 Spectral signature of images
10.4 Elastic properties from images
10.5 Analysis of image data
10.6 Results and discussion
10.7 Freshness determination from images
10.8 Firmness information from images
Chapter 11 Nuclear magnetic resonance (Marit Aursand, Emil Veliyulin, Inger B. Standal, Eva Falch, Ida G. Aursand and Ulf Erikson).
11.2 Magnetic resonance imaging
11.3 Low–field NMR
11.4 High–resolution NMR
11.5 The future of NMR in seafood
Chapter 12 Time domain spectroscopy (Michael Kent and Frank Daschner).
12.2 Measurement system
12.3 Time domain reflectometry measurements
Chapter 13 Measuring electrical properties (Michael Kent and Jörg Oehlenschläger).
13.4 Use of the Fischtester
Chapter 14 Two–dimensional gel electrophoresis (Flemming Jessen).
14.2 Two–dimensional gel electrophoresis (2DE)
14.3 2DE applications in seafood science
14.4 2DE–based seafood science in the future
Chapter 15 Microbiological methods (Ulrike Lyhs).
15.1 Microorganisms in fish and fish products
15.2 General aspects of microbiological methods
15.3 Most probable number method
15.4 Molecular methods
Chapter 16 Protein–based methods (Hartmut Rehbein).
16.2 Fish muscle proteins
16.3 Electrophoretic methods for fish species identification
16.4 High–performance liquid chromatography
16.5 Immunological methods and detection of allergenic proteins
16.6 Determination of heating temperature
16.7 Differentiation of fresh and frozen/thawed fish fillets
Chapter 17 DNA–based methods (Hartmut Rehbein).
17.2 DNA in fishery products
17.3 Genes used for species identification
17.5 Conclusions and outlook
Chapter 18 Other principles: analysis of lipids, stable isotopes and trace elements (Iciar Martinez).
18.2 Species and breeding stock identification by lipid analysis
18.3 Verification of the production method
18.4 Identification of the geographic origin
18.5 Future prospects
Chapter 19 Sensory evaluation of seafood: general principles and guidelines (Emilia Martinsdóttir, Rian Schelvis, Grethe Hyldig and Kolbrun Sveinsdóttir).
19.1 General principles for sensory analysis
19.2 Application of sensory evaluation to fish and other seafood
Chapter 20 Sensory evaluation of seafood: methods (Emilia Martinsdóttir, Rian Schelvis, Grethe Hyldig and Kolbrun Sveinsdóttir).
20.2 Difference tests
20.3 Grading schemes
20.4 Quality index method
20.5 Descriptive sensory analysis
20.6 Consumer tests (hedonic)
Chapter 21 Data handling by multivariate data analysis (Bo M. Jørgensen).
21.2 What is multivariate data analysis?
21.3 Arrangement of data for bi–linear modelling
21.4 The outcome of bi–linear modelling
21.5 Validation and prediction
21.6 Real examples and further reading
Chapter 22 Traceability as a tool (Erling P. Larsen and Begoña Pérez Villarreal).
22.2 Traceability from older times to the present
22.3 Traceability research in the seafood sector and other EU–funded food traceability projects
22.4 Validation of traceability data
22.5 Traceability in a global perspective