86 TlMARIT VPl 1967 unfrozen, i.e. was kept above —1.2°C. In the light of the new information given in Figure 3, one may be more optimistic. ‘Superchilling’ of cod appears to have a prom- ising future, provided that (a) the appearance of the product is not important (b) the fish are stowed for no more than 3 weeks and (c) they are not to be processed further, e.g. by normal freezing plants or by smoking, but are to be eaten at once. This may give rise to problems if large quantities of fish have been superchilled. In the hght of what has already been said about species differences among fish, it will be realised that, for example, lemon sole (þykkva- lura) or haddock (ysa) would probably keep in good condition longer than cod under ‘super- chilling’ conditions. Rate of íreezing Generál The significance of freezing rate has exercised the minds of workers for many years, without any consistent conclusions emerging. One diffi- culty has been that the palatability and appear- ance of the products are difficult to assess ob- jectively, and it is almost impossible to compare the findings of workers in different laboratories, since definitions of freezing rate used tend to be vague. Kondrup and Boldt (1960) reviewed a number of papers on the effect of varying the freezing rate on the quality of beef and poultry, and in spite of there being much material to hand. they had to admit that the overall findings were inconclusive. The only reasonably certain outcome from all the work was that the appear- ance of the product tended to be better after rapid than after slow freezing. In the case of fish, it was concluded by Weld (1927) that quicker-frozen cod (þorskur) be- came tough and tasteless more slowly on storage than slower frozen. Reay (1934) reported that quicker-frozen herrings (sild) were slightly better, but that freezing rate had little effect on quality. Notevarp & Heen (1938) found little difference in the quality of cod frozen in 1 or in 6 hours. Quicker-frozen herring were considered slightly better in quality immediately after freezing, but the difference was found to dis- appear on cold-storage. Banks (1938) reported that rapid freezing was essential for good ap- pearance and suitability for processing of her- rings. Slowly-frozen herring showed a greater wastage when fed through a splitting machine. Reav et al. (1950) found that, for various fish, there was little detectable effect on the texture unless the freezing time was more than 4 to 10 hours, in different instances. If herring or had- dock of the best appearance and suitabihty for smoke-curing were to be obtained, then the time to cool from 0° to —5°C had to be less than 2 hours. Aalderink & Rowan (1953) found no difference in the firmness or flavour of hake (lysingur) frozen in various times from 12 to 36 hours. It is clear that the differences between fish frozen at different rates are not great enough to be obvious on every occasion, but, on the average, rapid freezing gives a better product, especiahy where appearance is concerned. Very slow freezing should be avoided anyway, because bacterial spoilage will continue during the time the fish is still unfrozen. While the effects of freezing rate may not always be apparent after thawing out, they can be perceived in the frozen product. Freezing fish causes the water from the protein gel to solidify as minute, discrete particles of ice, which are separated from each other by the dehydrated protein. The size of these ice particles depends on the rate of freezing, becoming progressively smaller as the rate increases (Plank et al., 1916). Rapidly-frozen fihets, on account of the vast number of minute ice particles, reflect much light from their surfaces, and so look white: indeed, in very rapid freezing they become so white that they have occasionally been rejected by commercial processors in the mistaken belief that they were dehydrated. Slowly-frozen fish, containing larger continuous bodies of ice, look darker and more ‘glassy’. If fish frozen at various rates are thawed out immediately, the dehydrated protein reabsorbs all the water from the melted ice, swehs, and takes on an appearance that cannot be dis- tinguished histologically from that of fish that have never been frozen at all. If, however, there has been cold-storage, resulting in denaturation, the protein loses its power to reabsorb the water and remains in the shape acquired during freezing. This shape would be governed in the first instance by the freezing rate, so here may lie the explanation for the considerable lack of agreement among investiga- tors — there is probably a better chance of de- tecting differences in the appearance of thawed fish frozen at different rates after some denatur- ation has taken place.

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