Fish Handling and Processing
What is
fresh? Correct use of ‘fresh’ can be
(1) newly
produced , not stored or preserved and
(2) having
its original qualities unimpaired, i.e. not deteriorated in any
way. Fish which have been carefully frozen and thawed and are
otherwise of high quality might well be considered fresh by the second
definition, although not by the first. Both aspects of the definition must be
kept in mind for consideration of freshness
Some guides for
descriptions of fresh fish characteristics include the following:
1.
Flesh: Firm, elastic
flesh not separating from bones, indicates that fish and
flesh has been handled carefully.
2.
Odour: Fresh and mild. A fish
just taken from the water has practically no fishy (ammoniacal) odour. The fish
odour becomes more pronounced with passage of time, but it should not be
disagreeably strong when the fish are bought.
3.
Eyes: Bright, clear
and full. The eyes of fresh fish are bright and transparent; becomes cloudy and
often turn pink in stale fish. The eyes often protrude in fresh fishy but
become sunken with increasing staleness.
4. Gills: Bright
red. The colour gradually fades with age to a light pink, then grey and finally
brownish or greenish.
5.
Skin: Shiny,
with colour gradually not faded. Most fish are iridescent in appearance when
taken from water. Each species has its characteristic markings and colours
which fade with increasing staleness.
Fresh
fillets and steaks have the following characteristics
1. Flesh:
fresh-cut in appearance, the colour should resemble that of freshly dressed
fish. It should be firm and moist in texture, without traces of browning about
the edge and without dried-out look.
2. Odour:
Fresh and mild, not fishy, pungent or ammoniacal
3. Wrapping:
If the fillets or steak are wrapped, the wrapping should be of
moisture-vapour-proof material. There should be little or no air space between
the fish and the wrapping.
Why Fish Spoil
Certain
irreversible changes begin to take place immediately after fish dies. Within
some hours, the muscles gradually harden along the fish until it is quite
stiff. The fish can remain rigid for a number of hours or a few days depending
on various factors. Thereafter, the muscles then ‘soften’ or become pliable
again. The stiffening is called rigor mortis and is brought about by enzymes in
the muscle. It is important in relation to filleting operations. Enzymes also
cause complicated series of breakdowns of other tissue components, called
autolysis (or self digestion). Bacteria in addition, and ungutted fish
digestive juices, invade flesh to start the process of putrefaction. Lastly,
fats is broken down by oxygen and can give rise to rancidity.
Autolytic spoilage
Food
supply ceases and energy source depletes at death. The enzymes do not ‘die’;
they can continue to operate but, since energy is required to build larger
units, the function which the enzymes perform (post mortem – after death) is to
break (down) compounds into smaller units. This breakdown is called autolysis.
Autolysis can affect flavour, texture, and sometimes, the aesthetics/appearance
of flesh.
Flavour: The characteristic sweet, meaty flavour of
fresh fish is (at least in) partly due to a compound called inosinic acid; its
breakdown through autolysis results in loss of this flavour. Another
compound, hypoxanthine, which is produced from breakdown of
inosinic acid, contributes to the bitter flavours of spoiled fish. Autolysis
also contributes to bitter flavours by providing a supply of compounds which
the bacteria convert to unpleasant flavours (and odours).
Texture: The stiffening of fish (rigor mortis) and
the subsequent softening (of fish) are caused by autolysis. Rigor is
of great significant in fish processing particularly in freezing operations for
very fresh fish i.e. freezing at sea. In rigor the fish can stiffen into
distorted shapes and they can be difficult to load between freezer plates.
Forcibly straightening the fish can lead to serious textural damage in the
flesh when filleted. Fillets, cut before rigor and then frozen can contract
during storage giving a tough rubbery texture.
Appearance: Yellowish-brown discolorations which are
sometimes present in frozen flesh could be due to autolysis.
Bacterial spoilage
Bacteria
present on the surface and in the guts multiplies rapidly and invade the flesh,
when fish dies. In dead fish, bacteria can breakdown the muscle
itself and also will ‘feed’ on the smaller units produced by autolytic action.
The increase in numbers of bacteria result in heavy slime on the skin and
gills; an unpleasant ammoniacal, sour odour and eventual softening of flesh.
Frequently gut wall will burst.
The bacterial load
present on the fish when caught will continue to multiply (even if thoroughly
chilled in ice) until the fish is consumed. However, during handling they are
likely to pick up more bacteria, from washing in polluted water, careless
gutting, dirty containers (boxes), etc. However careful you are in handling the
fish, there will always be bacteria present but, with care, the members can be
controlled.
Flesh
from living fish is aseptic i.e. it is sterile. An aseptically removed flesh
maintained at O° C for up to 6 weeks has no obvious organoleptic changes.
Autolytic changes will, of course be occurring during this period.
Table1. Yield
from several species of fish (from considering a wide variety of data source)
Species
|
Dressed-fish
(%)
|
Liver
(%)
|
Viscera
Less Liver (%)
|
Other
trimmings(%)
|
Average
species Flounder
Ling
cod (the big head)
Sockeye
salmon
|
65
67
54
73
|
2
1
1
2
|
8
7
8
6
|
25
25
37
19
|
Source: Stansby M. E.
1976. Industrial Fishery Technology. Robert E Krieger Publishing
Co. Huntington, New York. 415pp.
Dressed
fish average 78% flesh, 21% bone and 6% skin.
Table
2. Proximate composition for edible portion fish in general
‘edible’ = skin and
bone-free fillet.
Statistics
calculat(%)
|
Moisture
(%)
|
Protein
(%)
|
Oil
(%)
|
Ash
(%)
|
Average
Range
Ratio
high to low
|
74.8
28-90
3.2
|
19
6.28
4.7
|
5
0.2
– 64
320
|
1.2
0.4-1.5
3.8
|
Oil
content vary (even within the same species) with Season of year, geographical
area, age, sex and size of fish. The primary causes of variation are degree of
energy expenditure and food intake.
It is more meaningful to
classify fish into categories because of the variation V12:
Fig.
3. Varying oil content of some species of fish
Category
|
Type
|
Oil
Content (%)
|
Protein
Content (%)
|
Prototype
|
A
B
C
D
E
|
Low
oil – high protein
Medium
oil – high protein
High
oil – low protein over
Low
oil – very high protein
Low
oil – low protein
|
Under
5
5-15
over
15
5
<5
|
15-20
15-20
<15
>20
<15
|
Cod
Sockeye
Siscowet
lake
Skipjack
Halibut
Clams,
oysters
|
Fig. 4. Types
of composition for some important species
Species
|
Primary
category
|
Secondary
Category
|
Anchovies
Bullhead
and catfish
Carp
Clam
Cod
Crab
Flounder
Mackerel
Menhaden
Mullet
Salmon
(Atlantic, chum pink, silver)
Salmon
(king)
Scallop
Shrimp
Tuna
(albacore, bluefin)
Tuna
(skipjack, yellowfin)
Whiting
Yellow
pike
|
B
A
A
E
A
A
A
B
B
A
B
B
A
A
D
D
A
A
|
C
-
B
-
-
-
-
C
C
-
A
C
-
D
B
-
-
-
|
Oxidation of fish
In
fatty fish, chemical changes involving oxygen from the air and fat of the fish
may produce rancid odour and flavours. This problem is of importance when
storing frozen fish for fairly long periods. Glazing before cold storage helps
to alleviate the problem.
Fish Handling
Effect of fishing
methods
Fishing method may
affect freshness. A normally live fish e.g. tuna, mackerel, may become excited
and die in frenzied state when seined. Similarly, certain types of gears e.g.
gill nets may kill the fish after and exhausting struggle. Such exhausting activity
before death results in rapid development of rigor mortis followed
by earlier signs of deterioration during icing. On the other hand, many salmon
are caught by surface hook and line, brought (to the boat) brought quickly up
and dispatched quickly with a blow on the head. These don’t deteriorate fast.
Halibut caught on a bottom hook and line usually come to the surface easily and
are quickly killed. Such ‘clean kills’ are significant in extending freshness
and quality. Refrigeration brine immersion and electric shocker to stun or kill
the fish immediately after harvest is used to control quality in modern
aquaculture operations.
Physical damage: Fishing gear and handling of the fish when the
gear are brought aboard often contribute to bruising or tearing of the flesh
during transfer of fish in and out of the boat with spear and spearhead, gaff
hooks, fish-pughs or forks are responsible for lots of unsightly and unsanitary
holes in some fish before processing. Quick bacterial spoilage follows in these
(pugh) marks. Rough weather on the trip back to port after fishing and
excessive ice pressure in the bins accelerate the deterioration and increases
the shrinkage of fish.
Condition: fish is usually in a better condition if
caught from tidal than still water (such fish are said to be doing more
‘exercise’).
Dressing: Actively feeding fish when caught requires
prompt dressing and icing or processing by or other methods to reduce greater
incidence of autolytic spoilage by digestive enzymes. Dressing involves removal
of gills, viscera and scales (where present) immediately after catching and
removal of bones in some cases. The gut cavity should be washed with clean
water (or clean sea water if at sea) before icing, 50ppm chlorine in sea water
(in Atlantic trawlers) is more effective than plain sea water in rinsing blood
and slime from the fish. Dressing is deemed impractical in some fisheries where
fish value and size are small gutting and washing of fish here however, been
(shown demonstrated to be very important.
Methods for preserving
fish to reduce spoilage
Biological
systems which operate bacterial and autolytic spoilage are only possible under
certain optimum conditions. Altering the conditions can therefore
provide ways of preventing or reducing spoilage. Since bacteria require water
and are sensitive to heat, salt concentration and pH, (there are) a number of
approaches can be used to prevent bacterial spoilage. Control of autolytic
action (in fishing industry) is by lowering temperature. The enzymes could also
be inactivated by other means e.g. irradiation with rays or by poisoning with
chemicals.
I Temperature control:
In cold water fish
enzymes and bacterial action are optimum at 5 - 10° C; and warm water fish
between 25-30° C. Lowering temperature prolongs storage life by reducing
bacterial and enzyme activities.
A. Lowering temp.
Chilling: Holding fish at above or just below freezing
point i.e. reducing temperature of fish from 25° C to 1-4° C in the tropics.
Ice is ideal for chilling. Fish should be chilled as soon as possible. Ice is
used for “short term” storage though in some species it may be as long as one
month.
It appears that
generally
1. Freshwater
fish have a longer shelf life on ice than marine species e.g.
Tilapia (Freshwater
fish) - 22-28
days
Mrigal carp (Freshwater fish)
- 35 days
Nile perch
(Freshwater
fish) - 20
days
Snapper (Brazil)
(tropical marine) - 11-16 days
Spanish mackerel
(tropical marine) - 18days
Bonga (tropical
marine) - 20
days
2. Tropical
species keep longer than temperature or coldwater species on ice e.g.
Cod (temperate
marine) - 12-15
days
Haddock
(temperate
marine) - 12-15days
Whitings
(temperate
marine) - 9-12
days
Trout
(temperate
freshwater) - 10
days
Channel
catfish (temperate
freshwater) 12 days
3. Non-fatty
fish keep longer than fatty fish species
Freezing – Long term storage i.e. for months, years
because
1. autolytic and bacterial action are almost
arrested.
Read for more
information
Eyo, J. E. and B. O
Mgbenka. 1997. Methods of fish preservation in rural communities and
beyond. Pages
16 – 62. In H. M. G. Ezenwaji, N. M. Inyang and B. O.
Mgbenka (eds.)
Proceedings
of the Anambra State Ministry of Agriculture, Awka and UNDP-sponsored
workshop
on Women in Fish Handling, Processing, Preservation, Storage and Marketing,
13
- 17 January, 1997.
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