冷冻食品保质期试验.pdf

Shelf Life Testing:食品伙伴个性空间i Ns [B,]0F
Procedures and Prediction Methods for Frozen
SzH4V
a~UTA0Foods
,_ K+s xi oh^P(d0Bin Fu
U5_.[)klS fk0Kellogg's Battle Creek MI
{m&RS'Z0E
oy0Theodore P. Labuza
Xu1\Yq {0Dept. of Food Science & Nutrition, University of Minnesota食品伙伴个性空间XQRi`9\8A u
1334 Eckles Ave., St. Paul, MN 55108
V7T2C)I/g3G8N3d02
7T i}&E;]FE019.1 Introduction食品伙伴个性空间n!M Y:K`4T
The shelf life of a food can be defined as the time period within which the food is safe
)|lj)K&]+b5MN0to consume and/or has an acceptable quality to consumers. Just like any other food,
(F}h6r
J*Jh#st0frozen foods deteriorate during storage by different modes or mechanisms, as食品伙伴个性空间5Y(I%G1d%S$}(Hl*~O
summarized in Table 1. Microbes usually are not a problem since they cannot grow at食品伙伴个性空间!}!Y1L6L"y-D[w9S
freezing temperatures unless subjected to extensive temperature abuse above the食品伙伴个性空间E
k#R?X_)N"_
freezing point. Enzymes are a big concern for frozen foods, which can cause flavor
rD$cs'?I*~"M.J iVN0change (lipoxygenase) in non-blanched fruits and vegetables and accelerated
;}R%p*y(Q1V[+r0deterioration reactions in meat and poultry (enzymes released from disrupted食品伙伴个性空间([9EAj/]J
J
membranes during precooking). Cell damage or protein and starch interactions during
%E)S/wjk
h0freezing cause drip and mushiness upon thawing. Discoloration could occur by nonenzymatic
QYA2qu1q8a0browning, bleaching, and freezer burn. Vitamin C loss is often a major
_#Ub'uZ7J Gj*}n0concern for frozen vegetables. Physical changes, such as package ice formation,
'Jv,["UNX0hcr0moisture loss, emulsion destabilization, recrystallization of sugars and ice of frozen食品伙伴个性空间.Q$E(a.xH v
desserts are often accelerated by fluctuating temperatures.
0}O~)u"c(N$RW0For any specific frozen product, which mode determines its shelf life, depends
(LM1SRmXL0on the product characteristics (raw materials, ingredients, formulation), pre-freezing食品伙伴个性空间q| j*J(G9]1I,V
treatment, freezing process, packaging film and processes, and of course storage食品伙伴个性空间kZ7bq.H@:P
conditions. All of the quality deterioration and potential hazards are usually食品伙伴个性空间hJ[8T:f0Q.Y
exaggerated or complicated by a fluctuating time-temperature environment (e.g.食品伙伴个性空间3J_:k:yYMy
freeze/thaw cycle) during storage. On the other hand, the shelf life of a frozen food食品伙伴个性空间 @0m\8_#o
can be extended through ingredient selection, process modification and change of食品伙伴个性空间$R/e;uk!J
package or storage conditions, as discussed in Section 3 of this book.食品伙伴个性空间]:M5T/DuMj%X
This chapter will focus on shelf life testing of frozen foods for product
C#w9rp5v8x3Y-c-{r0development and market practices. Shelf life testing consists basically of selecting the食品伙伴个性空间0B1o3M9NV _Z
quality characteristics which deteriorate most rapidly in time and the mathematical食品伙伴个性空间lm-D~/i\#K
modeling of the change. Table 19.1 can be used as a reference for the selection of食品伙伴个性空间r|z&`P1H8dOR
quality characteristics, which depends on the specific product and usually requires食品伙伴个性空间Z9@6a5W$C
professional judgment. Mathematical modeling of quality deterioration will be食品伙伴个性空间4b\5t{j3HFSnv
discussed next.
3Nu!D0ZQ]03食品伙伴个性空间7k"k]H#F4i ? pS}
Table 19.1 Deterioration modes of frozen foods食品伙伴个性空间+pY%b?w+d8Y.C'w]/`
Frozen Foods Deterioration Modes食品伙伴个性空间V1|D{5J
Frozen meats, poultry and seafood Rancidity食品伙伴个性空间-gD J$KBr#`e
Toughening (protein denaturation)
,O a;Flx1M-[b0Discoloration食品伙伴个性空间\7{ikmD ho4{J/E
Desiccation (freezer burn)
Mo9I1~4X-z0Frozen fruits and vegetables Loss of nutrients (vitamins)食品伙伴个性空间4xi)z@EC7\A
Loss of texture (temperature abuse)食品伙伴个性空间K6R;uj&Q
Loss of flavor (lipoxygenase, peroxidase)
@O"fKYh0Loss of tissue moisture (forming package ice)食品伙伴个性空间K'c s:W;g?$SZ_
Discoloration食品伙伴个性空间i[sl6a
Frozen concentrated juices Loss of nutrients (vitamins)
1i~_2~c5b6X [q(U0Loss of flavor食品伙伴个性空间/ZTm"sV&Bn@
Loss of cloudiness
e:SixE4G{0Discoloration食品伙伴个性空间.U
^1S8zHz-d"xOh"O
Yeast growth (upon temperature abuse)食品伙伴个性空间Y[9\z9wO
Frozen dairy products
G,xk(?\k6JS0(ice cream, yogurt, etc.)
}0A2]:lz de ~eP0Iciness (recrystallization of ice crystals)食品伙伴个性空间8B%X#U-y9s$f&Vb
Sandiness (lactose crystallization)食品伙伴个性空间|]0^/I+\ ?$O_'FY
Loss of flavor
ueDBK~$J,v|A0Disruption of emulsion system
V\]s@&u{0Frozen convenience foods Rancidity in meat portions食品伙伴个性空间)?3t5LWl
^Z
Weeping and curdling of sauces食品伙伴个性空间d]Q$| Q't6V
Loss of flavor

Vo7_6c"jo0Iz j0Discoloration食品伙伴个性空间 ns}2j/vghup
Package ice
[o? ?S0Frozen bakery products (raw dough,
riv4O{5wA:N"G5De Q0bread, croissants)
:G{6o5LP|c$if&v7Ku0Burst can (upon temperature abuse) (dough)食品伙伴个性空间K8Xu_;inhaE
Loss of fermentation capability (dough)食品伙伴个性空间T^:@aJr7q|
Staling (becoming leathery)
|Ba(Qcv0Loss of fresh aroma食品伙伴个性空间j`Y@a)v
19.2 Modeling of quality deterioration食品伙伴个性空间 @W)n8Zw"T4_
19.2.1 Basic equation
`Cy_
J"D$nu0A frozen food starts to degrade once it is produced (Figure 19.1). The rate and食品伙伴个性空间u|9^?-ix.i
the degree of degradation depends on both the composition and the environmental食品伙伴个性空间9y*aJ#E!b-Ze
conditions during storage and distribution. In general, the loss of food quality or shelf食品伙伴个性空间
}O}QFl8w
life is evaluated by measuring a characteristic quality index, "A". The change of quality食品伙伴个性空间0J8rTH XY+I2Hz
index A with time (dA/dt) can usually be represented by the following kinetic equation:食品伙伴个性空间^u.U-w*QD$Bx
- dA/dt = k An (19.1)食品伙伴个性空间3?)h.\MaL$h}+?V}5~
where k is called a rate constant depending on temperature, product and packaging
iw:of8x'RE0characteristics; n is a power factor called reaction order which defines whether the rate
E*dj{&yL04食品伙伴个性空间\O%Ls4{^
of change is dependent on the amount of A present. If environmental factors are held
3{Z S&?6A'GL0constant, n also determines the shape of deterioration curve.食品伙伴个性空间'A.qL;`w2j-}
Ao食品伙伴个性空间kPt C l+s3S+@
A a食品伙伴个性空间F%ADBF"cs
b
-S%j8ZOh)Dafi5H(e0c
`(`2u/I%U
RE'W,V0t
-Ru4u;GD0d食品伙伴个性空间 rF8?9D3B"LX
e
PQ8EGx:C"mMq c0Figure 19.1 Quality deterioration curves: a) linear; b) exponential;
E,mBO iK/]0Q7X0c) hyperbolic; d) quadratic; e) complex.食品伙伴个性空间SoWG z:U"G
19.2.2 Zero and first order kinetics
{\ g&ZM8H6l
KW0Equation 19.1 can also be written as:食品伙伴个性空间^!L$T*P"B#tq-K:I!S
f(A) = k t (19.2)食品伙伴个性空间#e3@/nyCb
where f(A) is the quality function, k and t are the same as above. The form of f(A)
y QsFu0depends on the value of n. When n is equal to zero it is called zero order reaction
Yb!j;g9K/^ I0kinetics, which implies that the rate of loss of quality is constant under constant食品伙伴个性空间U$]X}^'f M_kg
environmental conditions (curve (a) in Fig. 19.1). If n is equal to one it is called first
oYY9\
GP
j:T0order reaction kinetics, which results in an exponential decrease in rate of loss as
:i2Xm@5B9y3QJ0quality decreases (curve (b) in Fig. 19.1, which becomes a straight line if plotted on a
%y.ir!?,WT0semi-log plot). These quality functions can be expressed as follows:食品伙伴个性空间 ~ qp.Yj2cB
B
f(A) = Ao - A = kzt zero order (19.3a)食品伙伴个性空间+\~g*l;z0b]dU
f(A) = ln Ao - ln A = kft first order (19.3b)食品伙伴个性空间V\6`G.c.F6_
5食品伙伴个性空间{4R9}${!v'C
where Ao is the initial quality value. If Ae corresponds to the quality value at the end of食品伙伴个性空间yi/u:u.ai
shelf life, the shelf life (q) of the food is inversely proportional to the rate食品伙伴个性空间A8R
FU:IR
constant:食品伙伴个性空间(sAc_Sl
{e#f
q = (Ao - Ae) / kz zero order (19.4a)食品伙伴个性空间*LQ X8y1Ae%c3O4t)w
q = ln (Ao/Ae) / kf first order (19.4b)
!Y[o*P4b#}0It should be noted that most chemical reactions leading to quality loss in frozen食品伙伴个性空间Z*}4E {[
food systems are much more complex. However, the reaction kinetics can be
4[gY%k8b$m0simplified into either pseudo-zero order or pseudo-first order kinetics. In the case of食品伙伴个性空间/}:G9dcUQ%B%{Rk
complex reaction kinetics with respect to reactants, an intermediate or a final product食品伙伴个性空间8LM;Uo"lN
(e.g. peroxides or hexanal in lipid oxidation ) could be used as a quality index. There
*P6hA4~q)~0are few cases where neither zero nor first order kinetics apply. Curve (c) in Fig. 19.1
-Ye.};B.nu6F5a0shows the degradation curve for a 2nd order reaction (with single reactant), which also
9C)j*g"]7wM0shows a straight on a semi-log paper. A fractional order should be used to describe食品伙伴个性空间Ci|3?7k9Sqz
R
the curve (d) in Fig. 19.1.
5c%Oo(u]2JR;zr0Sometimes, there is an induction period or lag time before the quality食品伙伴个性空间@d.f5^P[c]
deterioration begins (e.g. browning pigment formation in the Maillard reaction or a
pFH.Br \SF$t0microbial growth lag phase, as shown in curve (e) in Fig. 19.1. The length of the lag
:H.J/lL$xVSk h0depends on many factors, but temperature is a predominant factor. Given this,
yv ciuR#jp0modeling of both the induction or lag period and deterioration phase are necessary for
!iI-J[#R(^0accurate prediction of quality loss or shelf life remaining. An example of such work has
q*N yIFk.Dz Jo0been demonstrated by Fu et al. (1991) for the growth of bacteria in milk.食品伙伴个性空间n)w!U#K:e6}sSNm~
In certain circumstances (e.g. A represents a sensory hedonic score), a nonkinetic

V P_
i{U#Y0approach, e.g. a statistical data fitting technique can also be used to describe
}_0cqT:N;?C ma_0the deterioration curves. Varsanyi and Somogyi (1983) found that the change in
i@:aeT8bI0quality characteristics as a function of time could be approximately described with
+ifI`#V|Dpq8R0linear, quadratic and hyperbolic functions and that storage temperature and packing食品伙伴个性空间B6RL/m^c%z
conditions affected the shape of the deterioration curves. However, the parameters食品伙伴个性空间IL yR Q;G3r]T:f
determined by data fitting are difficult to use for prediction under variable storage食品伙伴个性空间D @+]kx1QS
conditions except for the linear curve.
kRl3d7f~[?8h019.2.3 Temperature dependence of deterioration rate
F-G\'_i G4m4b:U019.2.3.1 Arrhenius kinetics食品伙伴个性空间)xKhZ|y,Z'F
Once a frozen product is made and packaged and starts its journey from the

}8\j$^if&u0`v8{0manufacturer's plant to warehouse, distribution center, retail store and finally食品伙伴个性空间3KZlpUR-Ju
6
/^ngge/C0consumer's freezer, the rate of quality loss is primarily temperature dependent
c|/GP.q3wS0(Zaritzky, 1982). The Arrhenius relationship is often used to describe the temperature食品伙伴个性空间 O1hOpz
dependence of deterioration rate where for either zero or first order:食品伙伴个性空间
QZ(HD+VF&s
k = ko exp (-Ea/RT) (19.5a)食品伙伴个性空间{Uc)CN
or ln k = ln ko - Ea/(RT) (19.5b)
r
t&n)Vy {"qU!L0where ko is a pre-exponential factor; Ea is an activation energy in cal/mol; R is the gas食品伙伴个性空间#PB5i6m(a3G-}
constant in cal/mol K and equal to 1.986; T is an absolute temperature in K (273 + °C).
.A3_)G2@0U&q/e?U0Thus, a plot of the rate constant on semi-log paper as a function of reciprocal absolute食品伙伴个性空间#WN T#NEy9G1mi z
temperature (1/T) gives a straight line as shown as Fig. 19.2. The activation energy is
v8KeHW0determined from the slope of the line (divided by the gas constant R). A steeper slope食品伙伴个性空间H$FM4x AU$caN
}
means the reaction is more temperature sensitive, i.e., a small change in T produces
E
~-y$J0m3f^
`0are large change in rate.
-YO2bp)M0Figure 19.2 Arrhenius plot
%b4SY C%N0ln k
0h]9@v/^01/T
7a4n t$]*utIVj0slope = -Ea/R
W8f0G0\#{GmA0Thus, by studying a deterioration process and measuring the rate of loss at two
{$k)WI oxU(\0or three temperatures (higher than storage temperature), one could then extrapolate
*s[/t6Q |!Ik0on an Arrhenius plot with a straight line to predict the deterioration rate at the desired
#@Q,XZ:{ OFmhg0storage temperature. This is the basis for accelerated shelf life testing (ASLT), which
"nBD7F:}\F0]1y0will be discussed later. One should note however that in some cases a straight line食品伙伴个性空间y9WX'x-fl#fO$uGi
will not ensue for a variety of reasons, especially if a phase change occurs (Labuza食品伙伴个性空间 | w"oA*HUH9J
7
k2P%PcW,d4G0and Riboh, 1982). Thus for frozen foods, extrapolation from temperatures above 0¥C
pq`^/_j
d0are meaningless for shelf life prediction.
4N1Z}&G8rt;Y019.2.3.2 WLF kinetics食品伙伴个性空间+wzw_X9zU5I
Besides the Arrhenius equation, another popular equation at least in the more recent
,vx v(H8?'u,nh~g0food literature, is the Williams Landau Ferry (WLF) model (Williams et al., 1955). Its食品伙伴个性空间,h[ iL0C~
A2}
original form was based on the variation of the viscosity in the temperature range
n0~6fi @3s0above Tg as addressed in Chapter 3. When the rate constant at Tg' is substituted for Tg食品伙伴个性空间.V'@n*iEjL
(Tg' is the Tg of a maximally freeze-concentrated system), the WLF model can be
0Vx+S Eh8@xMl0written as follows:
os0vw6M!w0log (kT/kg) = C1(T-Tg')/[(C2+(T-Tg')] (19.6a)
Cn }(D\.lEt0or [log (kT/kg)]-1 = (C2/C1)/(T-Tg') + 1/C1 (19.6b)
x,h9|8s,[0where C1 and C2 are constants. Thus a plot of [log (kT/kg)]-1 vs. (T-Tg)-1 will be a
^$AM@:E1|4pLOX0straight line with the slope equal to C2/C1 and the intercept equal to 1/C1. As can be食品伙伴个性空间|.Nt*idW
seen this is a two parameter temperature dependent model as is the Arrhenius
d bnDru0equation.
8r:y"l)n}7be0Frozen foods stored below Tg' are stable to ice recrystallization and other食品伙伴个性空间o*L2Ik)I
physical changes. Levine and Slade (1988) postulated that stability is related to the食品伙伴个性空间*@*q4N/bb3a
temperature difference between storage temperature and Tg'. This cryostabilization of食品伙伴个性空间"n2S2~DQB]
foods assumes stability below Tg' and rapid decrease of stability above Tg' according食品伙伴个性空间Ro P XC MX mi#D.C
to the WLF relationship, exhibiting an increase in reaction rate, much higher than
%bip6@8D0expected from the Arrhenius kinetics. However, this may not be true since the rate of食品伙伴个性空间3~2Zpk;W'K
chemical reactions can be expected to be influenced by temperature increase in a食品伙伴个性空间2t*x8Y*j7z'_.K.QEO"V
complex way: (i) an increase of the rate constant, resulting from both the viscosity
;cd3S$t3_Co lv0decrease and the increased molecular mobility (Fennema 1996); (ii) a decrease of the食品伙伴个性空间tyE3CT-|MU
reaction rate as a consequence of the increasing dilution of the reactants Roos et al.食品伙伴个性空间$r2l&D'z
N-o2].A,o
(1996). For these reasons, it seems that the WLF model over predicts the temperature食品伙伴个性空间g5Z0xVJ
{`4l2P A
effect of rate constant (Simatos et al., 1989). As noted by Nelson and Labuza (1994),食品伙伴个性空间3vN!g
P)^v/na7a
because of the small temperature range over which foods are stored, e.g., about D30°C
c Z&Cl5W0for dry foods and D20°C for frozen foods, both the Arrhenius and the WLF model give
}%w"e7seD r0good correlations as long as one does not use the universal coefficients suggested by
?H.h"Y8o&j0E0Slade and Levine (1991). In fact as shown by Nelson and Labuza (1994), their use of
"V@a/W#MtS0the Lim and Reid (1991) data for enzymatic activity in the frozen state as shown in 19.3
%Q+B!P@Q/l8B*H0is not proof that the Arrhenius relationship does not apply, WLF was assumed because
;hM3B&sL~0the rate was negligible below -10°C which was the measured Tg. But as seen in
0RMsZF7^08
csT dvZ"x0Figure 19.3b if the data is plotted as Arrhenius plot an r2 of 0.999 ensues. The食品伙伴个性空间9^2|[)BU@Vz'ji
challenge in applying the WLF model for stability or shelf life prediction is that (1) Tg is
r{&q#RRaJy5A5B0not known; (2) Tg is difficult to determine; and (3) the universal coefficients of Levine
E5Ek"L;t
D%_0and Slade (1986) are not applicable.食品伙伴个性空间*F }A)J0t3PM
0 50 100 150 200 250
'e*_5~,S'U1w^(K00食品伙伴个性空间3e g'OL!NKN
1食品伙伴个性空间9]8H
^/h.I4F
2食品伙伴个性空间*S;R'Np9_F
3
+L CngW3w04
?%YS!~~ c2T05食品伙伴个性空间F(st%?(rQVaF
-3.5食品伙伴个性空间
n&cF!o.`-K3^ V`9TnY
-5.5
P1^)\t OSa u0-8.5
5OFq,P8rP0-13
`c8J+\ZcC/S1Y0-19食品伙伴个性空间p9Le3[ wvR&I
Time (hours)
4s$QE
`p"tL0Relative absorbance食品伙伴个性空间Qj}Q&]
bM.A5k:Q
Temperature (°C)食品伙伴个性空间:l;v%OX*q
hg
0.0037 0.0038 0.0039食品伙伴个性空间 z!\F-g
Ofmk)?B
-4
,?-QXY}v0-3
4B&icN.pM5_0-2
5b
TT!RY0-1食品伙伴个性空间a#R0H/N*Ak-]
0食品伙伴个性空间/W!l%q^0L~R
1/T (K-1)
a"K]0f,A4~0ln(k)
1xtpQp0y = 79.497 - 2.1621E+4x R2 = 0.999
)]?'P"b3K/P.~;Xz0Figure 19.3 Hydrolysis of maltodextrin in the frozen state (Lim and Reid; 1991)
upN?rnpB0a. Rate as a function of temperature (Note Tg is -10 ¡C)
9Tuf%}btAk0b. Arrhenius plot食品伙伴个性空间"f9V+u,A$[ryJ9Z
19.2.3.4 Shelf life model食品伙伴个性空间FC+?nP'`X0c
Most published data related to quality deterioration do not give rates or rate constants
M-lz_@0but rather are in the form of an overall shelf life (end-point analysis) as a function of
.QUtjv0K5R0storage temperature. Since the temperature range used is usually quite narrow, the
E
Jhs'nchz0following exponential relationship exists between shelf life and storage temperature:
(uNZm\SB^2i0q = exp(-bT+c) (19.7a)食品伙伴个性空间/t+E/o U)l
or ln q = -bT+c (19.7b)
:A*^D$ioP0where q is shelf life at temperature T in °C, b is the slope of the semilog plot of q vs T
W5w
HcB0and c is the intercept or reference temperature as shown as Fig. 19.4. Practically, this食品伙伴个性空间 Y'q|nb1RGaoJq
is used frequently for shelf life determination and prediction due to its simplicity and食品伙伴个性空间 j e*ES8dj7Q
straightforwardness.食品伙伴个性空间 \NYfVd2l
9
h
SJ1V*aPEV0Figure 19.4 Shelf life plot食品伙伴个性空间&O+t0].XK[[Pw
ln q食品伙伴个性空间!},N"tHL3qV_)fr
T食品伙伴个性空间5H
z(OO(Ezc q|V
19.2.3.4 Q10 or q10
O?gJ^\Y0The Q10 approach is also often used for estimation of the temperature acceleration of
YnoC7p~]h7L0shelf life, which is defined as :食品伙伴个性空间/AU3t_C%P oi3bZ
Q10 = rate @ T1+10 °C / rate @ T1 (19.8a)
o E_eX3@0Q10 = shelf life @T1 / shelf life @T1+10 °C (19.8b)
k5e9jY5z0Q10 = (q10)1.8 (19.8c)
X(e'E&J I/E#BR9u0where T1 is temperature in °C. If the temperature unit is in °F, then the term q10 is
S.d&BFLp1f)?}/N0used, which in fact is more often used than Q10 in the frozen food literature.

gE0WEw^hBR0The magnitude of Q10 depends on the food system, the temperature and the
edG8}4v$t0absolute range. Q10 values from 2 up to 20 have been found for frozen foods (Labuza,食品伙伴个性空间9`6S uF+|y3Tfa$\R3s
1982) Labuza and Schmidl, 1985. Q10 can be shown to be related to the Arrhenius
ph7p'x
K%@0equation and the shelf life model through the following expression:食品伙伴个性空间k;v g)gSFVHP.M
Q10 = exp [10 Ea/(R T (T+10)] (19.9a)
Yi/VNaP\S'G!Y!|#h&b0Q10 = exp (10 b) (19.9b)
2a,ufD9TpA7^0Thus Q10 is not constant but depends on Ea and the absolute temperature T.
Z9C&Y'y0W EU0Some data gleaned from July (1989) and Labuza (1982) is shown in Table 19.2.食品伙伴个性空间?8c&MM"{7?
10食品伙伴个性空间y%n|g9y3?m
Table 19.2食品伙伴个性空间w0OK
[I!]
Estimate of the Q食品伙伴个性空间(JF&H3xbU!m%H
10食品伙伴个性空间g!h ~l"_
for shelf life of selected frozen foods食品伙伴个性空间#\1R{-N0]
Days of HQL
{5j+o*J3fPB0I te m - 10°C - 20°C Q 1 0食品伙伴个性空间L,hv$`4ZRe!IV
pork sausage 20 120 4食品伙伴个性空间Xb+N9|"Xs
pork 50 400 8食品伙伴个性空间n\^,r,K%L [9w D
beef 60 200 3.3食品伙伴个性空间v5Kz;]#A)^?
ground hamburger 250 800 3.2食品伙伴个性空间!{vV'bU&a7W9R0v%g;q
fried hamburger 35 250 7
kw)e)n:o5My-Rk0raw poultry 200 700 3.5
oA:x+x9Vg8yJt-n0fried poultry 25 700 3.2
,Ic;A;^Q0fatty fish 7 60 9食品伙伴个性空间"XwV!h*i[
19.2.3.5 Other models食品伙伴个性空间 al*@h+q
The following models have also been proposed to describe the temperature食品伙伴个性空间\%| Z!C CZ
dependence of the rate constant (Kwolek and Bookwalter, 1971) for frozen systems:
`{N9[b2Ww0kT = a + b T (19.10a)食品伙伴个性空间N7E(`+E w W7JTz/V
kT = a Tb (19.10b)食品伙伴个性空间x0hk9m6J-U0E)@
kT = a / (b - T) (19.10c)
Q^C7G9k+?0where a, and b are constants. In most cases, Equation 19.10c fits data better.食品伙伴个性空间 j4Q%U/Ry6Qm
However, all these have very limited practical application.
n{|3b5Of4Y}019.2.4 Time-temperature tolerance食品伙伴个性空间3Mw@re$^5T)N
Frozen foods are often exposed to a variable temperature environment, e.g. during
]8h#ZGG$pR~
d0distribution or due to freezing/defrosting cycle in retail or home freezers. In general, the
ki"w(cjMcqQ0value of the quality function, f(A), at time t under changing environmental conditions食品伙伴个性空间VB*YD?YQ5f
can be estimated from:食品伙伴个性空间LqSm6N
f(A) = ò k[T(t)] dt (19.11)
EB3q*n(R'r~*J0where T(t) is the temperature as a function of time. The form of f(A) depends on the食品伙伴个性空间na!]yB1w
reaction order as discussed previously. If an effective temperature, Teff, is defined as
&o4Cl{P n7O#Y V011食品伙伴个性空间'TkdJ+ml
that constant temperature exposure which causes the same quality change as the
zCk"y"I2z[xmrp0variable temperature condition, as proposed by Schwimmer et al. (1955), then
3i2P3iR(C0f(A) = keff t (19.12)
`N EbI0The rate constant at that defined temperature is termed the effective rate constant, i.e.食品伙伴个性空间O4i
A:?1kj
keff. To estimate the quality change under variable temperature conditions, one
(QYb j`0needs to either solve for f(A) numerically or know the value of Teff or keff that食品伙伴个性空间9x*w;L5I3C|f,[
corresponds to the variable conditions.食品伙伴个性空间:V9sxx\*z
The numerical approach for a randomly variable temperature history is
(mh+pK&h5\-E)J0essentially the same as the Time/Temperature/Tolerance (TTT) approach initiated by
6lm5^\"? sv x0Van Arsdel et al. (1969) and derived empirically in the 1960's for the prediction of shelf
(^(I#Qz%r3vK0life of frozen foods (July, 1984). It is assumed that the temperature history of the
_4P+wXg/q.N.{4H9u0product is known. Thus the fraction of shelf life consumed, fcon, was calculated as the食品伙伴个性空间bP5?\ Gyp7e
sum of the times at each temperature interval, ti, divided by the shelf life at that食品伙伴个性空间&yB2F,GZ
temperature, qi:食品伙伴个性空间3v2k4s;`V
mN3d,M1J%?
fcon = S (ti / qi) (19.13)食品伙伴个性空间lE`1K/~+^S!A
Thus the remaining shelf life at a reference temperature is equivalent to (1-fcon)*q.食品伙伴个性空间;o9x}!e9Z~\u y
Equation 19.13 assumes that the rule of additivity is valid for frozen foods (July,食品伙伴个性空间"ASv]sQ
1984), which means that the loss of remaining storage life or quality can be calculated
v:TAIr"d&g*P0from knowledge of the prior time-temperature episodes the product has been exposed食品伙伴个性空间K5G$D:C!?
to. This also implies that the prior sequence of the time-temperature episodes is of no
jCLgy@0importance except to calculate the amount of quality remaining up to that time, i.e.食品伙伴个性空间%W [VW2T+vK x3H6^
there is no history effect. If the rule of additivity is valid with reasonable accuracy, the食品伙伴个性空间#r
O6x[I%?
use of time-temperature integrators (TTI) should provide reliable results with respect to
,J'b?#TA1]8X y0prediction of shelf life remaining, which will be discussed later.
DE7}QE)DN0However, there are some cases where the total effect of various temperature
f8`7U-sZ-M]-xl0experiences may not be independent of the order in which they occur or of the nature食品伙伴个性空间Odf RcQME1vD?
of temperature history. For example, widely fluctuating temperatures may cause
BD+?9x u _0freezer burn or in-package desiccation, which is not additive (July, 1984). Where the食品伙伴个性空间Vum4N'l
colloidal nature of a product is affected, the effect of time-temperature history may not食品伙伴个性空间h-xC$j8Z!?
be additive either, especially with a freeze/thaw cycles. This is also true when growth食品伙伴个性空间+}1s;Z*AC:PB$D]
of microorganisms occurs (Fu et al., 1991). Certain chemical reactions, enzymatic as
$rr,b*Y!K ?&d1]-q#k,}0well as nonenzymatic, could even proceed more rapidly at temperatures below食品伙伴个性空间gbx.g([,m
b7u,q
12
{ A'Tbst0freezing. This is called a negative effect of temperature (Singh and Wang, 1977),
v%c4\#x6t6i0which could be caused by one or more of the following factors: (1) a freeze
JG']$dq~'^0concentration effect; (2) the catalytic effect of ice crystals; (3) a greater mobility of
6D)Gnjs/vG
um0protons in ice than in water; (4) a change in pH, up or down with freezing; (5) a
%bNP,@(qg&\;D0favorable orientation of reactants in the partially frozen state; (6) a salting in or out of
*lJ&igXP0proteins; (7) decrease in dielectric constant; and (8) the development of antioxidants at
ZTJl!t1O"P3GEO?0higher temperatures. As has been shown by Fennema (1975), the freeze食品伙伴个性空间C/_]
Xv'E;F]
concentration effect can cause rates of chemical reactions to increase dramatically just食品伙伴个性空间6i`b*dR
e@ ?
below the freezing point (Figure 19.5), e.g. ascorbic acid loss at -3°C can be faster食品伙伴个性空间*j x y@!{^4v{9g9Q
than at higher temperatures this one should not use data in the -4°C to 0°C range or
vB)Wn0c0Oc-oJC0above as part of an accelerated shelf life test to predict rates at lower temperatures.食品伙伴个性空间%A6u;z(Lt]$G
Fennema (1975), showed that the time to 50% loss of vitamin C in broccoli was 44
Q `D1US!I t;cr0days at -5°C, 120 days at -2°C and 162 days at +2°C. This concentration effect is食品伙伴个性空间bh[+GBh
evident in the shelf life plot of frozen strawberries as shown in Fig. 19.6 using the data
k,a4Q7i5vkq#G&p;S0of Guadagni (1968). If the data collected only at 25 and 30°F (-3.9°C and -1.1°C) are食品伙伴个性空间"whOk(LO!x'cXaT
used, the predicted shelf life at 0°F (-17.8°C) is over 27 years, if data are collected at
u0H$b"],m3? R,qu0only 20 and 25°F (-6.7 and 3.9°C), the shelf life predicted at 0°F is 40 days while data食品伙伴个性空间g`:q5usft BD
below 20¥F extrapolated to the true expected shelf life is about 280 days.食品伙伴个性空间,tI1o-K/wA*v1t
Figure 19.5 Rate of chemical reaction as a function of temperature食品伙伴个性空间AYeQ4V9Y
above and below the freezing point of a food.食品伙伴个性空间KqEp'P1p
13食品伙伴个性空间L#V(D{!Y
Figure 19.6. Shelf life plot of frozen strawberries showing the
"euG#F8X ~_9Stb0influence of the freeze concentration effect just below the freezing
b+}O/jZ1|!Z_0point on prediction of shelf life at 0¡F . Data from Guadagni (1968).食品伙伴个性空间.L\ZsE3X.@|9z7u#f
Each line represents a regression through a different selected set of食品伙伴个性空间JOp L)X3oB
temperatures.
3a%o?u)O#Yq*g0The response ratio of the food to changes in environmental temperature (RT) is
#Pz_2Y zIOu0dependent on the fluctuating temperature conditions as well as the heat transfer
~C2@7Kt0]b"C0properties of the food as well as the package (Cairnes and Gordon, 1976; Dagerskog,食品伙伴个性空间:Qh&_PU4N|hv
1974). In the analysis of food shelf life, an inherent assumption is made that the food食品伙伴个性空间e.s2w z(S.rg
is responding instantaneously to the environmental temperature changes, i.e., RT = 1.食品伙伴个性空间 V~3lR$v$Me
This may be acceptable if a surface deterioration process is the deterministic factor for食品伙伴个性空间L1pPlE IY;Vm p#s
shelf life, e.g. mold growth in some foods. Freeze-defrost cycles generally can be
7a
a8~2]Zd0considered as sinusoidal oscillations. The amplitude of the effect is reduced inside the
w P u0B,V;T|2w Qg0package by some factor thus RT. < 1. It can be expected that the shorter the period of
1T[*? r@FA|0the ambient variation the smaller the RT, and hence the smaller the amplitude of the
OC~$UI0]O0cyclic temperature variation in the package. Zuritz and Sastry (1986) also studied the
6`[ {a.GPfR3]0effect of packaging materials on temperature fluctuations for frozen ice cream and
7M&Lb"q8G0found that packaging materials coupled with a layer of stagnant air were effective
kK`q*s0barriers against thermal fluctuations.
9F!gUbp019.2.5 Hazard function食品伙伴个性空间\B ]&?5Z,z
14
6W"Er;Z.^2YI0After the product is produced, it may fail at any point in time in accordance with its life
tdb:\.qOsWQyA0distribution (Nelson, 1972). The hazard function h(t) of a distribution is defined for t ³ 0食品伙伴个性空间"p#{b#DUy
by:
s;o'r B6Y0h(t) = f(t)/[1-F(t)] (19.14)
K:bidjAL/c d,u0where f(t) is a probability density function and F(t) is a cumulative distribution function.
u"JPy'A&Y0The h(t) is the conditional probability of failure at time t, given that failure has not
^qUb"S/ZH0occurred before ..
b+_{ {/b9t2@0The behavīor of a hazard function for studying the shelf life of food products can
(]w%YZp}0be easily understood by examining the "bathtub" shaped curve in Fig. 19.7. Note that
*[ M
Rb$v8h0at time to, a frozen food product begins its journey to many distribution outlets for食品伙伴个性空间&wa I-Z d6|U*~,dP
consumption. During the time between to and t1, early failures may occur owing to a食品伙伴个性空间/[%S+L"u ?,v3go,r'\ Y
failure in the process itself, faulty packaging, extreme initial product abuse, and many食品伙伴个性空间9Ji"_8U]5_*aGq9Qe
other environmental stresses to which the product is subjected. Early failure should not
ftf{
[f1`)j0be taken as a true failure relative to the shelf life of the product unless it represents the食品伙伴个性空间yA2Y%T(iY0Uj
normal condition. From t1 to t2 one can expect, barring chance major temperature
*^ ucM(dV5@(F1blc0fluctuations, no failures. This interval represents the true period of the product's食品伙伴个性空间.I~x/T)`
stability. The failure rate is almost constant and small during this time. The hazard or食品伙伴个性空间nf
[#RM;Z3U/^
failure rate increases from time t2 to the termination point t3, owing to the true
E#Rk/V[+_`6_0deteriorative changes occurring within the product. The concept of hazard function is食品伙伴个性空间k1W`EAE*C
important in the analysis and interpretation of the failure times of a product.食品伙伴个性空间M6u$c7_f|Zv#C+Pg{A
Time食品伙伴个性空间)ri:lN} r-v?
to t1 t2 t3
C_D,Pbd0Early食品伙伴个性空间Hk&v!er)V7H
failure食品伙伴个性空间'J s6PlX
Period of product stability
-P O4I%}
pK@0Failure due to
)al2j |(ti5C0product食品伙伴个性空间;P F$hxH1~&oF#^8\G
deterioration
7d'M({,W7c_Mt"xy0Figure 19.7 Failure rate as a function of time

}4s;m
`6x015食品伙伴个性空间8| O9t@JSLr
A fundamental assumption underlying statistical analysis of shelf life testing is食品伙伴个性空间1d$@BekT
that the shelf life distribution of a food product belongs to a family of probability食品伙伴个性空间1h%a-]lwAr
distributions and that observations are statistically independent. Parameters of a shelf
/o+i#M.|oy0life distribution are estimated by use of shelf life testing experimental data. Once the
0_Q3w"`5Bv1?0parameters of a shelf life model have been estimated, it can be used to predict the食品伙伴个性空间,L
ZC|NeM
probabilities of various events, such as future failures (Nelson, 1972). Five statistical
tE%a'{m+UYr0models, normal, log normal, exponential, Weibull and extreme-value distributions
kJ5jq {2V0b3HT0were tested for a few food products (Gacula and Kubala, 1975; Labuza and Schmidl,
0iwx!b;W6Q#Z-i01988) and it was found that the Weibull distribution fits best, which will be食品伙伴个性空间^U9nG7Cb+UV
demonstrated later.
ZR6E8lc019.3 Shelf life testing — overall aspects食品伙伴个性空间!y&Vn U'wW.JDF
19.3.1 Purpose食品伙伴个性空间 WmSE(La
In the development of any new food product including reformulating, change of
!e.QT+FN0packaging or storage/distribution condition (to penetrate into a new market), one

ll$W#~C&J f1Y6z0important aspect is the knowledge of shelf life. The shelf life of a food product is vital to
T/KtW$Pi0its success in the marketplace. This life must at least exceed the minimum distribution食品伙伴个性空间f3bD+Y#I:c
time required from the processor to the consumer. Shelf life testing can assess食品伙伴个性空间*@n6c9H$MRn
problems that the product has in the development stage, following a "fail small fail食品伙伴个性空间rH~(m#PPH
?a}|9L6}
early" philosophy, thereby eliminating large disasters later. Marketing/brand managers
UIa?X5qV9d0also need reliable shelf life data to position the products and to establish the brand.
N+Fo(z2So \0Periodic determination of shelf life help to provide assurance that the product remains食品伙伴个性空间A(a.?1aC/a
consistent over time with respect to quality.
7wxT8k(R8N
~_9B M0Different shelf life testing strategies are necessary at different stages, as
Tmvt!M0illustrated in Fig. 19.8. If the objective is to identify whether pathogens and spoilage
A/YgW"I0microbes will grow in the case of temperature abuse, then a challenge study is
y:s2{'sZ|Ew0necessary. If the objective is to quickly estimate the approximate shelf life of the食品伙伴个性空间A;j IaHVpe5S3t
product then an ASLT can be used, as long as the proper temperature range is
tjH e5Yb6c0chosen. A confirmatory shelf life test may be conducted at the last stage with
#dP@)t:e%X0simulated distribution chain conditions, although in today’s R & D environment, this
} EzY8RM0may be skipped.
})R|m@FDo016食品伙伴个性空间+B&Jx{p0A"a
Product concept
n@%z)af0Pc0Prototype development
(?&n"O&dG1uQ-h0Pilot line testing食品伙伴个性空间`'c h[$o^m,E
Scale-up line trial
4f1a0YO+s/J/?\gr0Full line production食品伙伴个性空间3XEd0^*[f]+Y4`}
Marketplace食品伙伴个性空间U pM]!F/?;K8{`-k
General stability information食品伙伴个性空间5B'e$|$x m
dB
i
Challenge Study
g9|Y3} ?nUi4xo0Accelerated shelf life testing食品伙伴个性空间0Ppby
P:K
Confirmatory storage study
G3|+h-LI0On-going shelf life monitoring
~v6q#vE(rI:IF3S7}0Figure 19.8 Shelf life testing strategy at different product development stages
PH;D ?-z;l X(Wrl019.3.2 Shelf life criteria
f\^;H6Rj
KXe0The criterion for the end of shelf life may be variable depending on the definition of食品伙伴个性空间Dy9PjR%BJ
product quality grade, so the shelf life of a product may also be variable. The shelf life食品伙伴个性空间!r
T'rD4yl
G(c1C
of most perishable and semiperishable foods is almost solely based on sensory
o,g'Q$Y$lep q]i0quality. For example, fresh meat degrades mainly by bacterial activity and rapid食品伙伴个性空间'U(r9x9_[$z
chemical oxidations that cause an off-flavor development and loss of color. This is
l-IHin"aJ0readily recognizable by consumers. In contrast, many longer shelf-life foods including食品伙伴个性空间*E W JFP2p7b
most frozen foods degrade mainly by slow chemical reactions such as loss of
KNul0f
l3P;t&H4rd#Q0nutritional value. For example, the vitamin C content of some frozen fruits and
n,u H5|o&O-A&R0vegetables, may fall below the required standard as listed on the label before sensory食品伙伴个性空间h5\7I}8lR1L i'x%U
quality becomes inadequate.
Z&aA^}{,ZZ8}0The criteria for shelf life may also vary depending on the sensitivity of the
{+k!XM ]sj0consumer. For consumers, taste, odor, and appearance are the most obvious criteria;食品伙伴个性空间+L+X6U1Bquuz
in academia and in the industry, sensory evaluation correlated with instrumental食品伙伴个性空间k} Q:L,xz
measurements of a given quality index (e.g., vitamin C level) are usually conducted. In
{k4AA y1[*c3F0general, the criteria level corresponding to the end of shelf life of a product depends
)[2Av&[l+y3u017
.EZ3b Nm v^Ok,[0on: (i) any legal requirement, e.g. zero tolerance for botulinum toxin; (ii) consumer
@+s:ue+]6io0preferences or marketing requirements; and (iii) cost. In essence, the end of shelf life
P xMh2K0depends on the percentage of consumers a company is willing to displease. If 100%食品伙伴个性空间"O&KYJ(d}^
acceptance is required then high cost ingredients and absolute control of distribution
&bFv1`9rcU7OehW0up to point of consumption is necessary, otherwise there will always be some people
S
GQ%HB~/x$N0who will get foods beyond shelf life. The aim is to keep this as small as possible.食品伙伴个性空间"~"`O p&wjUr
19.3.2.1 Just noticeable difference (JND)食品伙伴个性空间b3Nu'|*tv+XB
Sensory (organoleptic) examination of foods was a general procedure used by the
Kz#Ew~y@k0human race to evaluate wholesomeness of foods long before the discovery of食品伙伴个性空间wLSO8rT/Xf$s&y
microorganisms. Sensory evaluation of foods by scientific methods can be used to
5^-Lm
Y7I{)P0v;m0evaluate such attributes as taste, odor, body, texture, color and appearance. Changes食品伙伴个性空间?0V H7IhE$X%yz
in these attributes may be brought out by microbial or non-microbial actions, usually食品伙伴个性空间)d`?pD&GpY
the latter for frozen foods.
~%R6fs)W0The methods used to evaluate sensory shelf life data include difference testing
q8sHHMH0and hedonic scoring. Difference testing can involve paired comparisons, duo-trio食品伙伴个性空间4pL7L*q;@{&Ps
tests, or triangle tests. The paired comparison procedure determines the time when a
}(K6MIQ8l0measurable difference in quality occurs between two test samples at a certain level of食品伙伴个性空间0U3k{h5k L~i q~4R
probability. When applied to frozen foods, this method is often referred to as the Just食品伙伴个性空间M`,|z*J/r
Noticeable Difference (JND) test or High Quality Life (HQL) test (July, 1984), which is食品伙伴个性空间d*r:d7xK+H0T
usually based on flavor changes. Duo-trio testing compares two unknowns to an食品伙伴个性空间;V?9b
Rc
unabused control sample and asks the question of whether either of the unknowns are
$j%Ju)im)x0the same as or different from the identified control. Triangle testing determines the one
fh'r X
ML0different product among three test samples presented randomly to a set of judges (at
!_z1QN a8P0least 10). Probability plots are used to predict shelf life at a given probability level.食品伙伴个性空间#` A:~&r/p\ryf
The difference method can result in finding a difference when none really exists (Type
V-{7Ec1Q0\0I error), or not finding one when indeed there is a true difference (Type II error).食品伙伴个性空间 T/F#xeXF'~%aG~
Labuza and Schmidl (1988) have discussed this topic more thoroughly in relationship食品伙伴个性空间)o-D*{6b,[[
to shelf life testing, which is not commonly found in sensory textbooks. Table 19.3食品伙伴个性空间a!]R ?Xr
shows some data from Guadagni (1968) for HQL of frozen foods.食品伙伴个性空间%yw7~y'@)\
18
mr3xs)m k$A0Table 19.3
R]Z.^3T T"\yqBf0Days of High Quality Life for fruits and vegetable (from Guadagni 1968)
/t u4]oTBfd3o.V0P roduct T yp e 0 °F 1 0°F 2 0°F食品伙伴个性空间fh"O(GATN-pw
apples pie filling 360 250 60食品伙伴个性空间we4SFG!}sz
blueberries pie filling 175 77 18食品伙伴个性空间C:Y4P5u1L7q(@
cherries pie filling 490 260 60
#UBC6\0V7h
?4wR%e2{0peaches retail syrup 360 45 6食品伙伴个性空间-s e S }ZK
blackberries bulk, no sugar 630 280 50
Lk;^3xHg)XmB0raspberriesbulk, no sugar 720 315 70食品伙伴个性空间9J!n6l!Z M%Gw
retail, syrup 720 110 18
Tj1x,^:[
xau0strawberries bulk, sugar 630 90 18食品伙伴个性空间
D.?U,kjK
retail 360 60 10
'@:K3n,H f)|1C'f0green beans retail 296 94 30
$r/d;O8O%[*Q l G0cauliflower retail 291 61 13
OF[ i{$xU0peas retail 305 90 27食品伙伴个性空间}0T;a`};~T#mbz
spinach retail 187 57 23食品伙伴个性空间2U?sUf&zZ8P@.}
corn retail 720 360食品伙伴个性空间4u;F\w0cMr"@!T
corn on cob retail 275 150
9`D?'~ g!P
sj019.3.2.2 Hedonic scoring
;X ^S2Z$wqw0Hedonic scoring — which indicates acceptance on a numerical scale, e.g. a 1-9 point食品伙伴个性空间WC/i&Le@r
scale labeled from "dislike extremely" to "like extremely", is typically used for shelf-life
6G l"t X_e3d/m0evaluation. The test can be designed to not only evaluate the overall acceptance of the食品伙伴个性空间 HGyb
yzW%_3~#a
product, but that of specific characteristics such as flavor, texture, appearance,食品伙伴个性空间(\ frTg?"}
aftertaste, etc. Trained panels can also use this technique on a line scale, which can食品伙伴个性空间-dGl(ze
be converted to numerical equivalents.食品伙伴个性空间:i!S.i ]D8p8b
If the hedonic method is used to evaluate shelf life, one can simply use the
gE h5~3R.N5iw0score as quality index A and plot the score vs. storage time, run a linear regression,
A.g%| Ho"J S0and choose the end of shelf life as the time when the progressed value drops below a
;m(d]n X-^6f-?U
m0pre-set level (Waltzeko and Labuza, 1976; Gacula, 1975). The shelf life determined in
TC Ko [2n)z c(a0this way is called the practical shelf life (PSL) for frozen foods (July, 1984), and is
Y@EYV!CK0d0e*q9?:K(\0longer than the HQL or JND. The use of hedonic rating scales may be of limited use in
9cf0s/BW~GM0shelf life testing, yet it is probably the most used method. Many food companies use a
^0sn!{g3LZV O0loss in hedonic score equal to D=0.5 for HQL and D=1.5 for PSL as the end of shelf life
Q:c _LX0Q'Nt}019
?*w:xyh0(Labuza, 1982). Objective measurements and professional judgment are often
VG5w%N6k`,|0required to determine the end point. Data in Table 19.4 from an report published by食品伙伴个性空间9AqYR
}oYo
the former Refrigerated and Frozen Foods Institute (1973) Unfortunately there were no食品伙伴个性空间F"N*J%GH Iy
methods given, but the data suggests that the PSL is about 2 to 3 times longer than the
uQtUeBH0HQL value. This in itself suggests that the HQL methods can be used to shorten shelf
bX Q;Eb
XD0life testing times.食品伙伴个性空间P1j7?2k.g;L0A
Table 19.4食品伙伴个性空间
QP,G.jW
Relationship between practical shelf life (PSL)
dY6aO$],f!}"t0and High Quality Life for frozen foods.食品伙伴个性空间eQ8h0py
F rozen Food P SL/HQL Rati o
jZ8ok'W&iL4h#E0lean meat 1.9 - 2
J-s}C'c%C%c
t0p0fatty meat 2.0-2.4食品伙伴个性空间&lY/o/tAR B
lean fish 1.9-2.2食品伙伴个性空间&yTdZ!S2{l
fatty fish 2.4-2.7食品伙伴个性空间"? m/MjB-A
precooked foods 2.8-3.0
L|)O6\s+j0fruit 2.8-3.1
D-MYbW7Vb0vegetables 3.1-3.5
%G @e2l/M#c019.3.2.3 Instrumental analysis食品伙伴个性空间#N7@6W@YdE8y\4_I
Chemical or instrumental analysis, such as moisture, nutrient loss, free-fatty acids or
{ na9Lf\H%S&c*nnem0color measurement that closely correlate to sensory attributes, can supplement食品伙伴个性空间|qL)U uo0[
sensory techniques. They are usually less expensive and less time-consuming than
!{i!K'd;F WK0sensory approaches. A correlation between a physical or chemical test can increase食品伙伴个性空间/z l/N:oF+w"`d
the confidence level of the sensory results. For example, the following constituents or食品伙伴个性空间3N(~imW"lG
properties can be considered for monitoring chemical changes of pizza quality during
nR#C#phLf0frozen storage: total free fatty acids, specific volatile free fatty acids by HPLC,食品伙伴个性空间9{"G
XJ iJ
peroxides, oxidative volatiles (e.g., hexanal) by GC, spice volatiles by GC, lysine, color食品伙伴个性空间1a u:o/},p{
(decrease in red color or increase in brown), in addition to sensory evaluation of taste
%cfw[1V~z)P!\,n0and flavor (Labuza, 1986). Most sensory experts agree that analytical methods should食品伙伴个性空间6L&[$R'O ab5kI
complement the sensory tests. Vice versa, the endpoint determined by objective食品伙伴个性空间g!vf[Bg-Ri/n
measurements should be confirmed by sensory techniques as well.食品伙伴个性空间/Jku P"m
20
'gI7`cg1MwW019.3.2.4 Weibull Hazard analysis食品伙伴个性空间/U](vU.[/FcWH
The Weibull Hazard procedure requires one to first make an estimation of the time to
'Ace8`0}8gL0the end of shelf life. This becomes the initial estimated time limit for the study. The time食品伙伴个性空间3?;]E"L&HX$n7v@bt
limit is then divided into several segments at which points panelists grade the product.
w~c*b!Vo:f.g y0Additional panelists are added at a constant number for each subsequent time period
8GVm$U?5f]n J0to maximize the number of testers near the end of the test. The panelist is asked to食品伙伴个性空间E6Ui-g&o4_4vNQ/q
grade the food as good (acceptable) or bad (unacceptable), i.e. no ranking on a食品伙伴个性空间 R2G`?U f$yh
hedonic score. When the product is identified as unacceptable by 50% of the
3LXz@#A1MX0panelists, the number of testers for the next period is increased by the number of failed
xLSL[X0samples plus the constant number. The interval between sample times is also食品伙伴个性空间,yjT5M~/~1H*Lzq
shortened as the end of shelf life gets closer. The test ends when no more samples or食品伙伴个性空间0?2j`i6Yb FG4R
panelists are available. The scores are ranked and the cumulative hazard calculated.
8uOb#v Z4oq0The critical probability of failure Pc, can then be calculated from the following equation:
[H(GZlO0Y(o0Pc = 100 (1 - exp(-å(H/100))) (19.15)
!V6yxb#Qle+v0where H is the hazard value equal to 100/Rank. Choosing Pc = 50%, corresponds to食品伙伴个性空间XR6o!X+J;?
an accumulated hazard value of 69.3%.
mN}L?:rTM9P0The relationship between the logarithm of storage time (log t) and the logarithm食品伙伴个性空间d,hap fs%Y-p&M3S
of hazard value (log H) is linear:
kX$U^&u5C fG:f
T0log t = (1/b) log H + log a (19.16)食品伙伴个性空间&w*dX[RxG
where b is the shape parameter and a is the scale parameter. The shelf life can then
w cE
p G7I9bC0be determined based on the desired probability level allowed for product failure. The
z(O`*XM&P0lower this probability, the shorter the shelf life. This plot then allows one to make a
$M.j|Q |u'Yiz0management decision with respect to the probability of displeasing a certain fraction of
EO
D"J5`dDM,p$G0consumers. It is hoped that the distribution time is such that greater than 99 percent of食品伙伴个性空间1w!x9f` {@
the product is consumed before the end of shelf life based on displeasing less than
r"q6s)R6? U0X% of consumers where X is the economic value. An detailed example was given by
c"qS? M6?+[:iv0Labuza and Schmidl (1988). It should be noted that this process can also be used for食品伙伴个性空间7DP*Qj"\!M+p]6i
simple analytical tests such as plate counts or vitamin C. In these cases the number of
T#X"_8Lo5L!@3m%Ev0panelists are replaced with the number of samples tested. Some criterion such as 20%食品伙伴个性空间$rym]6mPK
vitamin C loss is used as the negative response. Figure 19.9 shows an example of
^n6s$lE#o0Weibull plot for a frozen food based on assumed data. A shelf life of 16 months is
Uu"?1i&v9D7M6{021
`U"v:y)d0found at Pc = 50% from the graph. From this graph then, if 95% of the food were
jQ;{m5p4WX0distributed and consumed in 3 weeks, only 1% of the consumers would be displeased食品伙伴个性空间'u@Gc&Yt'L%F
.01 .1 1 10 100 1000食品伙伴个性空间"~ y+^ AG+y|t
1食品伙伴个性空间x$S
}\7w(j!?
10食品伙伴个性空间%K\;}3Jz&_Lc3y?
100
hB6@1En3tDAS0Cumulative hazard (%)
w5fW|m*I1fA0Shelf life (wk)
*C4f$e RW;`.wQ-I0Probability (%)食品伙伴个性空间fQ%C4Zbji}
0.01 0.1 1 10 50 99.99食品伙伴个性空间(Oq,uHf
Figure 19.9 An example of Weibull plot for a frozen food.食品伙伴个性空间:qW)FL&N2`JV&X
A shelf life of 16 wk was determined at Pc = 50%.食品伙伴个性空间c} K^i0\ _*zG'y
(or 0.95% of the product is out of compliance). If the rest were held and consumed at
@nnw5e,?g~010.5 weeks, 50% of those eating it would have out of quality food or another 0.5 x 5%
1l:I@Dd2[dbE0= 2.5% of product. Thus in this distribution model about 3.5% of the product is
&E.a*F$Om{0unacceptable. To improve on this, the product must either move faster or one must食品伙伴个性空间*b)]q0W8w
distribute it at a lower temperature. Wittinger and Smith (1986) used this approach to食品伙伴个性空间@ b!Lx MKQ2[
determine sensory shelf life of ice cream based on iciness and found a shelf life of 5
]q(B k0T0Y4q4Gi0weeks at 0°F (-15.5) which fits the general data for iciness in ice cream as shown in食品伙伴个性空间5XrD'yTs2Sw
Figure 19.10 (Labuza, 1982). It should be noted that this gives a Q10 of about 12.食品伙伴个性空间R#u M+s?/BN
22
8h"Z h7oCm7oX0.1食品伙伴个性空间0[ug9?+z"}9W.Ei
1食品伙伴个性空间6j%L#K,S`$X6o
10食品伙伴个性空间,gk WC$P
100食品伙伴个性空间,e%o'b
LW |X0v
Temperature °C食品伙伴个性空间5`
^ {bJB,gc L0]
1
#dY%Q&v|010食品伙伴个性空间
fkY_k M,?S
@6T
100食品伙伴个性空间.^(`;]!{pLV_
-30 -20 -10 0
Oof%rpPV7?00.1食品伙伴个性空间;{ |@'Cz*hQ,_'_o w
weeks食品伙伴个性空间6OzI4I$U Tw7S
Figure 19.10 Shelf life plot for ice cream based on icyness食品伙伴个性空间7B|,ImmK'P$p
y
perception from data of Labuza (1992)食品伙伴个性空间)y0U2[%?#t:Gs
19.3.3 General procedures
AgStD2D{2?0Shelf life testing experiments are designed to measure the average shelf-life of a食品伙伴个性空间t7gGS5_l
product under given conditions. General procedures for shelf life testing of foods were食品伙伴个性空间7y#S&D/\l6^\s
proposed by Labuza and Schmidl (1985), which include:
B5dD)FKl$D0Step 1: Develop testing protocol — The protocol should consist of: i) specific
0J uX0\:N?NU%c0objective; ii) detailed test design in terms of product, package, and storage condition;
-S,k`-S-m0iii) execution procedures in terms of time, space and resource availability; iv) cost
?]Qt'{0estimation.食品伙伴个性空间S6RPW,Cz*q0fgJ3V
Step 2: Identify key quality indicator — Any previous shelf life data and kinetic食品伙伴个性空间
O5@Xe'AzN
parameters of food deterioration available in the literature (Labuza, 1982; Man and
\#YIUm#gg_nfn0Jones, 1994) or the distribution turnover time of a similar or a competitive product in食品伙伴个性空间y+D$A8V/i:]U:~ `{
the market place, if any, would be very helpful in this preliminary identification or in
:},d%o H7X8?{[0determining the shelf life requirement.食品伙伴个性空间m,z8~m}4Q(K8ag1L
Step 3: Estimate product sample and control needs — The number of samples
l
sCJ4yk/s0and controls required should be based on the detailed experimental design. If
t L4[)W"Q|4T
S\0sufficient product is available, extra samples should be placed into each storage食品伙伴个性空间x&n iK DG[1K
23食品伙伴个性空间~!E%Wa'[
condition. Now and then it may be necessary to recheck a sample, especially if a value
R(r;d(y)\]7t)L0is not in line with other data. It would be disastrous to be out of sample before failure食品伙伴个性空间P(W7~bJV8`
has occurred or the predetermined termination of the test is reached. Extra controls食品伙伴个性空间j;~6UV:Q
should also be prepared and stored. When the samples are placed into storage食品伙伴个性空间r/]3Oc%V LP6o
rooms, they should be positioned so that the complete package is exposed to the
.o@G*WM0external atmosphere, unless otherwise specified. The specific location of the test食品伙伴个性空间4LQ1kZmf@*l\
sample should be recorded. Temperature controllers should be checked for accuracy,
#s+J4h/`V _0periodically. In addition, removal of all unused samples from the storage room to make食品伙伴个性空间 E&BM,|RR
space for future studies is a must.
:l$O3R r/b;{{}? D0There are various thoughts when it comes to using a control product. Some
uY H;k@W}6T0sensory experts prefer an actual physical control; others are satisfied to just use the食品伙伴个性空间wI8J a3Xo
numbers obtained in the zero time evaluation. There are three alternatives when using
S7\Djl_r]0a physical example as a control: (i) making the control from scratch each time using食品伙伴个性空间/U\VN0b[tu
the same ingredients, procedures, etc.; (ii) deep-freezing the control (e.g. pizza held at食品伙伴个性空间.nr%A%~7vV#XT
-70 °C) and accepting that it might have changed slightly, but minimally compared to食品伙伴个性空间ZTJJM&_x
the product in shelf life; (iii) using a fresh batch of product which may not be identical.食品伙伴个性空间(l)]|i a Th6a5h
Step 4: Select proper package materials and package size — This is largely食品伙伴个性空间/X5NtHa)?e)t%_
dependent on shelf life requirements, packaging costs and availability, and consumer食品伙伴个性空间dbMuq)zf
information. Factors such as vacuum packaging, nitrogen flushing, or use of
Dn2xb {/^0antioxidants are often considered in combination with packaging materials.
il3ZE a:t]4e0Step 5: Choose storage conditions — Storage conditions are chosen based食品伙伴个性空间R^RY8^:K!Tx:OQ2@
on the type of shelf life testing. For example, the intended commercial食品伙伴个性空间l m^]9I g7E
storage/distribution temperature range should be used in confirmatory shelf life testing.食品伙伴个性空间V?ucCb
Elevated temperatures are often used in accelerated shelf life testing to obtain data for
4u.B^u,v2M0prediction of shelf life at lower temperature or for prediction of shelf life under variable
f#|U
SM4Vg;bo[0time-temperature distributions. Humidity control and/or monitoring is less important for
M ]tG"Y0frozen foods as compared to other foods (e.g., snacks, cakes, pies, and pastries).
oOuT.a!f0Light in the room should be properly controlled depending on the package.食品伙伴个性空间/QZ_x'B*b5QIjd0Xs
Step 6: Estimate sampling frequency and duration of testing — The sampling
6T/`B,v6RnX5~0frequency is generally an estimation based upon experience from prior studies with
&|t2TRH2Wy0similar foods. However, once one knows an interval at one temperature, then the食品伙伴个性空间.kmknZYu y
intervals at other temperatures can be estimated using a Q10 value i.e., if the Q10 is 3
K+~ l }1i|+T"G0then for a 10°C lower temperature the sampling times can be 3 times longer. If the食品伙伴个性空间&I?+T&Lv3K
interval between sampling is too long, the risk of under- or over-estimating shelf life食品伙伴个性空间;e8y!iq/k
increases. The more analyses that are completed, the more accurate will be the shelf
5PbIqhu0life determination.食品伙伴个性空间N mj,M!E*^t9l5`b
24食品伙伴个性空间zn m$s&osm
The question as to when one should end the experiment must be based on
#N;Q SQ_$K&Y"]0some pre-set criteria for failure. One criterion could be the minimum shelf life
Y:D4e%S+F&|'V\L0requirement driven by product category, distribution chain, and the benchmark's食品伙伴个性空间xL0@$mqXy4y
product stability. If there is an accompanying sensory test, the end time can be based食品伙伴个性空间2cujE9t_-DU7G
on some organoleptic inferior quality criteria from which one then can get a microbial
mlb8_!l+l0MO0or chemical index limit. For frozen products, several weeks to months are usually
+j$?f,J1VFZL2|e0needed. If the shelf life can be estimated with any accuracy, the test intervals can be食品伙伴个性空间N@Wj2X s*|
lengthened and clustered around the expected failure period. Most of the experts only食品伙伴个性空间d7g7Nx?(h ]3jz
require about six evaluations to provide reliable results.食品伙伴个性空间&j
OT%\y:aZ]
Step 7: Schedule for execution — Before scheduling the starting date for a shelf食品伙伴个性空间D"k7F.L9F.r1f$A
life test, one must check for the availability of ingredients, packaging materials, and
![6he/_ {7P0storage space, and the time and resource available in the pilot plant or in the食品伙伴个性空间F[W`-m:Wb1_f
processing plant to prepare the samples. One should also check for the time and
H NmL9{p,|"W,@[0resources available in the microbial lab, the analytical lab and/or the sensory support
vh:C;EW}7e0staff throughout the test period. A copy of the test request and schedule should be
S
e0\A*o-y,Pp2M0sent in advance to those who will be doing the work. The courtesy of providing those食品伙伴个性空间;}/ANi1RN4lg HO}
involved with this advance information always pays dividends. Holidays should be食品伙伴个性空间e\(@ ^!j;T;R
marked on the scheduling calendar, since scheduling too many evaluations near食品伙伴个性空间#W lP&s
{
major holidays or Friday afternoon is not recommended. However, once scheduled,
Q/THkI0sample observations on weekends and holidays should not be skipped over, since
;T+A:@Ly0important data points could be missed.食品伙伴个性空间`1Ge4\dPa;W:Q
Step 8: Take sample and evaluate quality — Samples should be taken and
g2`nC"L0evaluated following pre-determined schedules. Sampling plans should be
$I? I `n9}6\m0administratively and economically feasible, taking into account the heterogeneity of
._$~m*['n*`1x7S&vb0the food. Maxcy and Wallen (1983) pointed out the problem of heterogeneity of食品伙伴个性空间I,~3OpY nb
samples in shelf life prediction. Multiple subsamples (³ 3) should be done for nonhomogenous食品伙伴个性空间y:fqt[S;J
samples. A single package is usually used as an experimental unit.食品伙伴个性空间q vmmI&E:a-X%[
Replication of 3 or 4 units are desired for each measurement. For frozen foods, a
7U#i*Dy\J T0thawing process is often involved in the sampling procedure. Proper thawing or
R*Z_ o#\*Y0microwave heating is critical to the product quality. All samples should be thawed or食品伙伴个性空间)Z4K9y`v{;@
microwaved in the same way to minimize any biases.
VD.u8vm!Qll0The intended analyses should be based on the specific mode of deterioration,
wq+`.iA,RMEM0which was discussed earlier. Whatever the choice, the tests should be reasonable and
^ q.M:O:h0logical. The key is to make sure that one is measuring the right thing. If the wrong食品伙伴个性空间6m*E L_ |?
quality factor is measured, the test starts out a failure. Unfortunately, in many cases this食品伙伴个性空间Hd*q@|H
cannot be established initially, so sensory evaluation is a must in almost all shelf life
Wjo/^d8x,j$WH025
m_&BO\X}0tests. Key sensory evaluation techniques for frozen foods have been discussed
:m0Wn:v3WX6ec"S(B2k0before.食品伙伴个性空间:nF$d+wO;~#`:c O
At the time of each pull, one unit of the sample should be evaluated (informally
'_"W)iVrt0by a minimum of 2-3 people) for changes in flavor and texture. This should be done in食品伙伴个性空间}]+DG:ie V\-z,h
addition to the final tasting prior to a consumer sensory test. This is necessary since it
2W"I"G9?Q:sf0helps the developer know approximately how the product is doing during the progress
h}|'GrCZw0of the shelf-life, helping to avoid any surprises in the results. Control samples may食品伙伴个性空间|qV7r?s1RbQ
need to be prepared fresh.
`EW*W8w?0Step 9: Analyze data — Shelf life is the predicted day at which the stored
*`2?iDbuI0product (test pull) is X% less than the control at day zero (Reference). The data should
,f,Uk?2Q'p La0be plotted and regressed to determine that point using the proper model (zero or first).食品伙伴个性空间Ud#v/s3f n
All too often the data are not analyzed until the experiment is over and then the
,n;D4Z-N6iG0scientist finds that nothing can be concluded because of lack of points or a poor fit or食品伙伴个性空间,S hA2eV m
some surprises. Statistical curve fitting should be consistent with the chosen model
-H4\2R
x+f"R0based on a theoretical mechanism. The amount of change and number of data points食品伙伴个性空间-dpMO;]"W?
are related to the coefficient of variation (CV) of the test. A weighting factor may be
&r|lRZF\0used in estimating the rate constant and its statistical limits. When the data for an
)VC8P2uB\j2x6Z0attribute does not fit the regression model well (adjusted R2 of < 0.8), scientific食品伙伴个性空间0a/w A^b5F,A)g&iVd
judgment should be used to decide whether the data are applicable.食品伙伴个性空间&Fk#Jh*w
When in doubt, a rerun on retention samples might help understand or clarify食品伙伴个性空间h*mT%u ke&b/\u$G
the results. Error analysis could be performed before experiments are run by first食品伙伴个性空间8Eb*b'N+Jo"a/G
finding inherent errors in time, temperature, and quality index measurements, then
UML6D2uZ0calculating an expected standard deviation for the plot being used to determine a rate食品伙伴个性空间Hd8e'K%A2A7vE\
constant. If the experimental data have a standard deviation much higher than the食品伙伴个性空间1y,?L"sH
i{_"mu
expected value, either the functional form of the rate expression is incorrect or the data食品伙伴个性空间'YE&r8|e P|
contain errors from unanticipated sources.食品伙伴个性空间'K+S(Vf4n{
Step 10: Prepare shelf life report — Depending on the type of shelf life
q&}5rW-p"v$Hx0determination, the results should either throw light on the technical viability of the食品伙伴个性空间^:Z!g
k$Fopw z
product or provide answers to the questions about the maximum safe shelf life as well食品伙伴个性空间6Ue5dfGQA9[
as the maximum quality shelf life of the product. Before a shelf life is finally set, factors食品伙伴个性空间3nlJBCc
in the scale-up of shelf life data will need to be taken into consideration. Based on食品伙伴个性空间z8B&s6r,s0s
results from ASLT, the provisional shelf life will be set for the product. There is no食品伙伴个性空间]$\^n3G2W&d*NQ
government regulation which defines the product end point except for that related to食品伙伴个性空间1G3z+yBKb5?0tkv
nutrient levels (vitamin C and vitamin A) in 21 CFR 101.9(g)(1)(ii) which states that for
%r[}!l ?'P!|,@0the vitamins listed, the analysis level cannot be below 80% of the label value if it is a
B[;Kmo`a#C
_6_0natural food with no added nutrients or cannot be below 100% (21 CFR 101.9(g)(1)(i))食品伙伴个性空间5rT.d\I1liB+S
26食品伙伴个性空间Q1D hh$\;bQ7mm
if the product has any added vitamin or nutrient whether or not it is the nutrient under
~4h0T7d h(v)O0test. Thus one must base the label value on some predicted initial variability and
t/d"~znb w0some predicted loss during distribution and storage. The FDA usually takes samples at食品伙伴个性空间$I&@L+m8hg L+KS#B
the supermarket level (where they can purchase them) for compliance testing, not from食品伙伴个性空间$T%thzH e:FU kT
the end of the process line so distribution losses must be factored in.食品伙伴个性空间D'n`zN R`R$Z
The end point of shelf life is thus dependent on your corporate objectives and
U7o+yu9y-Yn.B
B0how much risk the company is willing to take with the brand. No shelf life test is
(o8Us2m-D+m&Y"}0completed until a termination summary has been written. All termination summaries
t(CEu:q o0should include the objective of the test, product descrīption, package descrīption,食品伙伴个性空间%ADN)d_"n L#T
conditions and length of storage, methods of evaluation, results (in the form of graphs,食品伙伴个性空间7N:|-a/[#l-U
shelf life plots and Q10 values) and conclusions. Termination summaries should
s_8s q,W0become a permanent record in the company library for future reference and preferably食品伙伴个性空间3Q$vzvu0b&M^H&K E-@
indexed well on a computer data base for later retrieval when needed. The final shelf食品伙伴个性空间+a$oj HS
life should also be set to give a clear margin of safety. In any case, the shelf life of a
KWdQZOD0new product, particularly of the high risk category, should be set based on data that
\.x/I Yo;D)U0relate to the worst case manufacturing and storage scenario. The shelf life can then食品伙伴个性空间-V5Q+{(i2Y*` }6b;Q
be reviewed and if necessary re-set in the light of further experience in manufacturing食品伙伴个性空间0g$_ e0{"lG!toZ`
and control after the product has been launched.食品伙伴个性空间(mTDQ8deQ
Step 11: Implementation — One should get top management’s approval of the
"k!]-e7R]+N0test results so that they can be implemented. Management must believe and support
r6j5k7r;wWf,}?f F%i*`V0those test results. It is important for production, sales, distribution, purchasing and
#J%n(X&??0quality control to work together to be sure that the production is properly handled from食品伙伴个性空间$J2~] m#tCu;X
the time of manufacture until this product is consumed.
N'\Mjj!W019.4 Challenge study食品伙伴个性空间7JBZ#Ox tY5q*b#^
19.4.1 Basis食品伙伴个性空间cK4iu1fI!o8g
Freezing reduces the microbial population of foods but considerable numbers usually食品伙伴个性空间Taon5l
ta-d&g
survive even prolonged frozen storage. A challenge study is often used in the食品伙伴个性空间d!~|0j_1K]
laboratory to study the factors and factor interactions as they affect the shelf life of the食品伙伴个性空间&}{1U7v6[g9S
product. Such simulated experiments enable the researcher to better control the study.食品伙伴个性空间5ZH k*C ^h,p
A challenge study is necessary for frozen foods for two reasons: (i) to predict microbial
3alzL6Xq g0growth and potential risk of the product upon temperature abuse in a distribution
Z7k!Es[j*ZiY0chain; and (ii) to assess the relative stability and the relative risk of different formula,食品伙伴个性空间vI|e"TY
different processes or different packaging materials, which is a must in new product
/[)q_lQu ~.JQ(J'i0development. A challenge study may also be considered as a preliminary shelf life
/f'M;N k,Z,EfL7F3j0determination in terms of microbiological safety. It is often used in the early stage of食品伙伴个性空间*y$emS.zz
27
!Q9DFT#Er2s1z0development since if microbial safety is a concern at this stage, then reformulating can食品伙伴个性空间-SBBY7H1q
be done quickly.食品伙伴个性空间.Ci5G(rp-P
19.4.2 Microbial abuse procedures食品伙伴个性空间#@qx)EB*A%I
Step 1: Identify barriers — A composition/ingredient analysis should be done to
8S `)@nI9tf0identify any barrier(s) against spoilage microbes and pathogens in case of
!Z/AV\(~2J qC0temperature abuse.

d7CDA8M#A$yO0Step 2: Choose types of organisms/strains and inoculation level — One食品伙伴个性空间}}TV'V
principle is to use an organism or a strain that has been isolated previously from the食品伙伴个性空间t/}v8tR'Q&},y6a
product or similar foods which is responsible for spoilage or risk. The more isolates in食品伙伴个性空间+H.Ex-_$g Cde,yI
the study, the greater is the confidence in the accuracy of the shelf life assessment. An食品伙伴个性空间~9T#liK
inoculation level must also be determined, which is generally much higher than the
5Sz@(YQ'~IwA0normal contamination level in a product. If the average contamination level for a食品伙伴个性空间1k5o ]+sLPO
particular product is known, then the inoculation level should be as close to that level食品伙伴个性空间2SWi6vbT7e;V9Z&|
as possible. Sometimes several inoculation levels are used.
N R0sh6e0Step 3: Determine temperature abuse conditions — After inoculation, products
{7_Mg KP$F^ B-u0should be packaged using the desired commercial packaging conditions, and食品伙伴个性空间EW|Z'pf
subjected to temperature abuse. Factorial design and response surface methodology食品伙伴个性空间m U\p/?n
are often used in designing a challenge study. A typical temperature abuse condition
&uV!s!^tM?dB{0used by some food companies is provided in Table 19.5. It starts out with five sets of
;`6j.WDwW0test packages placed at -18 °C to begin the cycle. At the end of the first 24 hr, one set
kI$t.?&}6Y!^6v@W:n0of packages is removed and tested for microbiological indicators to establish a zerotime食品伙伴个性空间/qZ"e,bR| A
level. All the other packages are kept at -18 °C for the next 20 hr, then removed食品伙伴个性空间@6q
K?%GL
and abused by placing them at 38 °C for 4 hr. Another set of packages is then食品伙伴个性空间g};P ])|zrq^V
removed for microbiological testing, and the cycle is repeated for the remaining食品伙伴个性空间j&EQZ2n{
packages, i.e. they are all returned to -18 °C for at least 20 hr, then abused at 38 °C
]+D3r9u @R0for 4 hr. This procedure is repeated so that one set goes through at least four freezethaw食品伙伴个性空间7E!e tj!h/z)Y p$\
cycles. If there is no significant increase in spoilage organisms or pathogenic食品伙伴个性空间d8lqI5U-MU1N_+T
organisms after the fourth cycle, the food is deemed safe microbiologically.食品伙伴个性空间*U4`"U9|y&s}yynt
28食品伙伴个性空间XQ*IM'F'g0Rc-q9n
Table 19.5 A typical temperature abuse test sequence for microbial challenge食品伙伴个性空间\%xo7MNM
studies食品伙伴个性空间&iaAai `2u#hO
a
Day Abuse temperature cycle Number of package sets食品伙伴个性空间P,M)?7Jr&O8Cb8Z
remaining食品伙伴个性空间V1}s3F0H'X
1 24 hr at -18 °C 5
vgY%cy-a:T:N3~ Ol02 20 hr at -18 °C
"jC^9{6qu$l0}04 hr at 38 °C
/n1U*|p;j7j04
+A
Ig|(aeiF~03 20 hr at -18 °C
Yc%c0_+B04 hr at 38 °C食品伙伴个性空间%v O:T@ s
3食品伙伴个性空间W0o:seb)W(^3MN+y*{
4 20 hr at -18 °C
.i!`$OmY@S2M|04 hr at 38 °C
xb&z:[:k-s$B[02
[%L5wF1F#L05 20 hr at -18 °C食品伙伴个性空间^1k:Oh4Nvn
4 hr at 38 °C
M*M*V,[9t)g `h+G t01
_+|x Z7m}Q7s0Source: Labuza and Schmidl (1985)食品伙伴个性空间;q u^3H`
V M_
Step 4: Do microbial survival analysis — This is to find out if there are any食品伙伴个性空间"K)]s*sv
microbial growth upon temperature abuse or if the inoculated microbes survived the食品伙伴个性空间6t9caJ:N1{o~j3n.E
process. Appropriate detection and enumeration techniques should be used.食品伙伴个性空间-wQ+SQ X ]2nN
19.4.3 Applicability
|@t.g8Ce3U0The use of inoculated pack studies conducted by independent laboratories allows a食品伙伴个性空间 vK*F)|
YH u
food processor to assess the relative risks that can occur under conditions of食品伙伴个性空间g?k9N$u,jc*M
temperature abuse of the food product in question. Taking frozen pizza as an食品伙伴个性空间v`3R7f4CeL
example, both the cheese and sausage, if naturally fermented, will have high total
|2wg } d)i0counts of bacteria. Since the product is usually partially pre-baked and then frozen, the食品伙伴个性空间!W2?c*C4^a^onZS
numbers of vegetative microorganisms will decrease until thawing occurs.
'j(A9LL1QE:N0Unfortunately, pathogens such as Staphylococcus aureus will not be totally
Z.WD8D-V vw;No0inactivated by these treatments. If the product is abused during distribution so食品伙伴个性空间b F#|G9[K.m8E
severally that the temperature near the surface reaches about 7 °C, pathogens may食品伙伴个性空间 z/_/B-Do-|{
grow. A challenge study with Staphylococcus aureus will verify the microbial safety
_ft1ym W0of the product.
#D[g*P8V0It should be noted that inoculated pack studies with pathogens should not be
D"i.Z`4g!?v0conducted in food industry laboratories that are located close to the food processing
V+oVQ%]?!_5Fv0facilities because of the possible transfer of pathogens to food products. No sensory食品伙伴个性空间`|/X!Ac'~Z
29
} sti1z
} QXY0panel can be applied to evaluate the inoculated samples other than visual食品伙伴个性空间7gM)?6B+q~W
observation.食品伙伴个性空间 f{"s*E5jk
19.5 Accelerated shelf life testing食品伙伴个性空间!KA;Uo&CxJ
19.5.1 Basis食品伙伴个性空间(UN?vyDA
During product development, preliminary shelf life knowledge is often needed in
&NO b]OG [z0addition to microbiological safety. Shelf life testing experiments at this stage are often
1Eud:x#e-o R E0accelerated to evaluate the effects of various formulation and processing parameters
%Dw"rSf;R8p X:P0on shelf life stability of the product being developed periodically since one can not
J0P,w}9f1jM*V'c0afford the relatively long shelf life period for a frozen food stored under normal freezing
x7^$LJ1xg0conditions. In addition, temperature fluctuations may occur in distribution and retail
c;NCqss0holding for frozen storage. Thus kinetic studies at several temperatures within that
B]GfkG6_*c2O0range are necessary to predict its shelf life. Accelerated shelf life testing conducted at食品伙伴个性空间tx4pG:dg%k6l-MZ5MP
elevated isothermal temperatures and/or with freeze/thaw cycles for frozen products
Y*n Ii"ob0have been used extensively for several decades by industry and government
T)d\ B5K6Q0agencies (Labuza and Schmidl, 1985). The Arrhenius relation and the Q10 approach
C2Y#]%w%[ y;p0are used to extrapolate the results to the expected lower storage temperature.
4b(k#XPh-k7`q+YK0Acceleration factors other than temperature have also been studied for some other食品伙伴个性空间0z6E*],dB-}
deterioration modes, such as moisture gain or loss and lipid oxidation (Labuza, 1984),
4`.P,~:}:f!Kl5H0but rarely done for frozen foods.食品伙伴个性空间
O1AqUw i]/H
19.5.2 Unique procedures食品伙伴个性空间c*tp9^/B-H+u:R
Step 1: Clarify test objectives — In general there are two occasions where
{,Shn4AI1TB0ASLT applies: i) estimate approximate shelf life quickly during development stage; ii)食品伙伴个性空间 X4O]`*D7V/{
collect kinetic parameters for actual shelf life prediction as in the marketplace, which is
R{8Y$l3U? G0conducted generally near the launch phase.
x Xs;OT8Q%r0Step 2: Select accelerating temperature conditions — Suggested isothermal
Jt2[2aI&S&Ia"^!F0accelerating conditions for frozen foods are -15, -10, and -5 °C with a control stored at食品伙伴个性空间W?L4UN~
< -40 °C (Labuza and Schmidl, 1985). The inherent assumption is that the食品伙伴个性空间%I[Ma5jo
deterioration mechanism is the same across the temperature range although as noted
+QZ!a'|*G2}jb*g0earlier, there is concern about how close to freezing one can go.食品伙伴个性空间O*|@ RnoU{
Moisture migration from the food into the surrounding air with resulting
4yRN_p
K0desiccation of the food and ice crystal formation in the package is a major mode of食品伙伴个性空间WvZmvK;F%h
deterioration of frozen foods under fluctuation temperature conditions. Cycling
,I5U8w7zN#IH0temperature storage is used to test for this, i.e. from 0 °F or 10 °F up to 20 °F with one
,H;^-fD2d4Zk'O[F3d0day at each temperature and then repeated several times. A freeze-thaw cycling study食品伙伴个性空间 j'o!J#m%twG+J
is also needed to determine its effect on sensory quality. Usually, the high temperature
#h}z!Ml iW030
:wC-IA]#R/XJy*q0can be much lower than that used in a microbial challenge study unless microbial食品伙伴个性空间FNzd8ycs5^
survival is still a concern. Typically, cycling temperature/time can be three to five 24食品伙伴个性空间F5KK4w tz
hour cycles between -18 °C and -7 °C, or between - 18 °C and 7 °C, depending on食品伙伴个性空间~?)iV2x
the product.
&|U+O2~ Hi-ecU0Step 3: Estimate testing time and sampling frequency— Testing times are食品伙伴个性空间E$A MmA!U6h
dependent on a desired shelf life at target storage conditions. For example, given that食品伙伴个性空间tEGa#Jh^0sj
a shelf life of 12 months at -18 °C is desired, a shelf life plot can be constructed. Figure
B7q-SMQ%C%_&_,`%b6V019.11 indicates the test time at -4 °C that equates to 12 months at -18 °C for various
)A6G GljS9h0Q10 values. Sampling times at -4 °C should thus be 1 wk, 2 wk, 1 month, 3 months, and
3XCnGG04.5 -5 months. Most published results suggest that Q10 values for vitamin C loss and食品伙伴个性空间 xR3SJ Z(b,cp
quality loss in frozen vegetables range from 2 to 20 and that the shelf life of vegetables
P9[(cC[ T\0is only 6-8 months at -18 °C (Labuza, 1982). Considering these Q10 values, a product
`[Om @c.bu0that does not retain good quality for 4.5 months at -4 °C may not retain good quality for
7US0od1qL
PNwyn012 months at -18 °C. This also suggests the sampling frequency shown in Table 19.6.食品伙伴个性空间g2L:f&B$~~,U
All simple tests should be conducted at each sampling time, while sensory testing
U T7{] Q2|n0should be concentrated mainly toward the end of the test sequence with a few near the
8cl1UbB'ZoG}.Z'a(o0beginning.食品伙伴个性空间 yMWDT#B5H.b
0 5 10 15 20 25 30
0r7b8k P
e)v$Ym0.1
j&fX v'W'bJ01食品伙伴个性空间P(ry?n Mm/l
10
t1R8nA'Q5^ |0R|2|ebY0100食品伙伴个性空间pwtO\O-xX
T (°F)食品伙伴个性空间n{}t6?*GC
Shelf life 12 mo at 0
6t$o/m C$h0ASLT at 25 °F
XIQ
fok04.5 mo食品伙伴个性空间 e9Z},L#j M\.L
1.2 mo食品伙伴个性空间;~-P/iDf
14 days食品伙伴个性空间4a
i oQ#q[.P;_1x8CG
6 days食品伙伴个性空间7t|/hLn/g\2Y,GF
Q10=2食品伙伴个性空间)`;Q6u8y:Z'M D
Q10=5食品伙伴个性空间 }&G.g?k
Q10=10
(I"nkf rS0Q10=20食品伙伴个性空间``,{rt3U;@A
Figure 19.11 Shelf life testing times at 25 °F equivalent to 12 mo at 0 °F食品伙伴个性空间#GT0tQ#ew5uS"B oR
for various Q10 values.

~*A%V7r:C3id6d0Table 19.6 Sampling frequency for frozen pizza ASLT食品伙伴个性空间7k0nq4Os&z5Zy
31
)|`j)U8RM?Z!a\0Temperature (°C) Sampling times (wk)食品伙伴个性空间u1A8B#FO&H;[
- 4 1, 2*, 3, 4, 5, 8, 12, 14, 16*, 20*
aS.n%yQ'WGSb0- 7 2, 4*, 10, 15*, 20*食品伙伴个性空间q7Z4@2MN
- 10 4*, 10, 15*, 20*
*[{w*P5u H0* Sensory test times Source: Labuza (1986)
`;}X;h\jK.V0Step 4: Determine end point — Figure 19.12 shows a comparison of times to食品伙伴个性空间,z~~ X4_y&S&@Z4v)l5N
various levels for the loss of vitamin C in frozen spinach as a function of temperature
$EUE)QlM|0(Kramer, 1974). The dotted line represents the 80/80 rule, i.e., from a legal standpoint,
Cv.Y;A7Z5l} Q0for natural products, 80% of the tested sample must have no more than a loss of 20%
Ho-J*c)P"S0(i.e. 80% of the label value). Consumer sensory testing will not always give such a食品伙伴个性空间8LH@R&A.C&Ip
clear shelf-life result since different shelf life times can result using different quality食品伙伴个性空间pN+ezM
attributes. Often professional judgment has to be made to decide what factor to use as
U4P*Z8?`0the base for the end of shelf-life of the product. When shelf life is unacceptably short,

x*O*QCj I5i;L7|0adjustments should be made to the food, its environment, packaging, process and
5i'N(H4~B+uNH0hygienic conditions, until a suitable extension of shelf life can be achieved. For some食品伙伴个性空间DEX6Mo8^ s"d
products, the test results may demonstrate that the target shelf life is not attainable. At食品伙伴个性空间Z9S*vu@,pN:[S
this point, the question of whether to launch the new product with a shorter shelf life or食品伙伴个性空间h!Viw/?9D
to abandon the entire project becomes a marketing decision.
A9`&O*yIQv5x S0-20 -10 0 1 0食品伙伴个性空间Wxh$~~zyBRD8g
1食品伙伴个性空间%a+dl0H9F|H!z
10
hLu N6? x0100食品伙伴个性空间
VLxEg&j
Storage Temperature (°F)
#m3K#s d$W0Shelf life (mo)
r
E S;UQ4al0Figure 19.12
Wd6\ d(zr0Shelf life of frozen spinach as a function of vitamin loss level
x F4Ap7B_#~+B5A050% loss食品伙伴个性空间muene8pz1sK4F
25% loss
`4n\+MS8E7RQA010% loss
5F"`R4d!D-yi0Quality (80/80 rule)食品伙伴个性空间KHU B(vH3_
~
32
I \ g6yZ"V0Step 5: Estimate kinetic parameters — From each test storage condition,
8l4qMZ"P#q0estimation of k or q is needed to make the appropriate shelf life plot. From this one can食品伙伴个性空间z'lMr{%^
mxTHf/~
then estimate the potential shelf life and confidence interval for the storage condition.食品伙伴个性空间;@~n(y2C.XO
Then parameters for the Arrhenius relation and the shelf life plot are determined by
x1xdvIt8vy0r0linear regression, which are used for shelf life prediction.
/TE1mnb*O2T0Step 6: Extrapolate to normal freezing storage condition — The most useful食品伙伴个性空间Zb D4W4|\l-O{
shelf life information is obtained for product kept at its intended storage temperature,食品伙伴个性空间6q8~_"K/J k.u
which is about -18°C for retail frozen products and -23°C for distribution of frozen
H"AD\xh+I P _pJ0foods. Figure 19.13 demonstrates how the shelf life plot is used for extrapolation. It is食品伙伴个性空间S R~?0t.~Tu
always a good practice to compare a model's prediction against actual experimental食品伙伴个性空间)[8h!n+OJzdQ(t1a
results because of the potential for errors from using the higher temperature data as
^Kd+rVq9^4R']0noted earlier besides the other errors suggested by Labuza and Riboh (1982). In
EEg-_5\0addition, the existence of a glass transition at a temperature between the test
rRN R%T(F[8TXA0temperature and the prediction temperature would lead to error as shown by Nelson
2mQW8H
sk%s;r{0and Labuza (1994). In the case of frozen foods, most likely the error would be an
,whAat0under prediction of the shelf life.食品伙伴个性空间u)N0k9rM/z
ln Q食品伙伴个性空间r&Tl VA"|
T食品伙伴个性空间$C?4}P2Yex
T1食品伙伴个性空间 kVq&O j-v
T2食品伙伴个性空间Y1L(UGxe&@
T3食品伙伴个性空间O#opI:}*e-JIO2HU
Ts (commercial storage temperature)
@-p:^ts0] yl0Figure 19.13 Extrapolation from ASLT食品伙伴个性空间 M0AM o{}:kXa
Step 7: Predict quality loss for a fluctuating time-temperature distribution — The食品伙伴个性空间h.c^geAD
prediction is based on two assumptions: (1) that there is no history effect from the食品伙伴个性空间l5vf'c*D7I-M
time-temperature variation and (2) that the key deterioration mode does not change as
#G sG Uz3dc'u,k0a function of temperature. The frozen spinach data shown in Figure 19.12 is used in食品伙伴个性空间!y;z ?;lI&?TcD
the following example in Table 19.7 for a time-temperature distribution. The line
5p4sMg8A3h033
r elAM`:[e s3R0equivalent to 20% loss is set as the end of shelf life limit i.e., if Ao = 36 mg/100 g then A
.C"Q L#\\[L.Hp |4b0at the end of shelf life is 0.8 x 36 or 28.8 mg or 7.2 mg of vitamin C can be lost. For食品伙伴个性空间8I_\M&m$^Rw2\
each temperature of exposure, the time on the 80/80 line is the time for 20% loss, thus
#Q W9Zc|H,]y0at -10°F, the 20% loss (equivalent to 100% shelf life) time is 16.5 months. Thus for 6
(Ycc]%y!x0months storage at -10°F, there is 6/16.5 or 36.3% of the shelf life lost and the amount食品伙伴个性空间NXq me+`TR1OG
left is 36 - 6.36 x 7.2 = 33.4 mg.
wo&}(s^^ M0Table 19.7 Estimation of quality remaining of frozen spinach after exposed to a
?'hE$]Vn8J0variable time-temperature history with Ao = 36 mg/100g spinach.
T;L9G$Uu0Temperature
BF*t ~.l5k0(°F)
u^z_/N0Time t
?k#q/fn#u|Z0(months)
;z lj&N8ym"tP+V0q shelf life食品伙伴个性空间)CPrb OF r
(months)
l]Czx/R
wt gxd0fcon
,]}o2@)E pW0(t/q )食品伙伴个性空间iL?#oSC
Sfcon Aremaining食品伙伴个性空间9e(J,ht ^8k+D;{
(mg/100g)
J[%o4\iqHH7Cv
G0-10 6 16.5 0.363 0.363 33.4
3X*ypQU]1X!N5O9Df0+3 1 4.5 0.256 0.619 31.5
)?^7Q-H }4c)[0+12 0.25 1.6 0.156 0.775 30.4
,bvhe#|g8uY-Ee0Since as noted 80% of Ao is equal to 28.8 mg/100g at end of shelf life, this product is
dXBL#k2VL wr@ `0still acceptable at the end of the set of three different time/temperature exposures. In
-S9`b\6ylg.O;y0fact, the shelf life left @ 5 °F = (1-0.775) x 3.3 = 0.74 months = 22 days.
5W~1i2Ip019.5.3 Applicability食品伙伴个性空间8A5u5A-qS9V
Because of relatively long shelf life for frozen foods and the unique feature of freezing,食品伙伴个性空间R}
ZOS#My
the degree of temperature elevation is largely limited. Prediction of actual shelf life
,h-mR w$Rp5[
g!P F0from ASLT may be severely limited except in very simple food systems. Frozen foods食品伙伴个性空间Y(aI}S/hs
such as frozen pizzas, may present problems with moisture migration. The moisture食品伙伴个性空间,[J%s%`f/[1j
may diffuse from the pizza sauce which has a higher aw into the crust containing a食品伙伴个性空间? I;ch+l/\ Wg
lower aw, creating a pizza crust that is limp and soggy. Product development scientists食品伙伴个性空间V"tdsJ\lx
should only use the results as a guideline and must use as many storage conditions
&U9p"g.F Q*UB*ND0as possible to minimize prediction errors.
6^K[r]r034食品伙伴个性空间F%e.A:N xl
ASLT is just a quick method, which can not replace the normal storage tests食品伙伴个性空间4mjl3H(z/e"l6l
discussed next. Once it is verified that the extrapolation may be wrong, i.e., too large

p5w^II5yJ0an error, then a careful look should be taken at the deterioration mode, the experiment食品伙伴个性空间
o*x2wQVY1O9j
design and procedure, the data collected and the model developed. If the食品伙伴个性空间EZF"Njj{3^(v \
extrapolation under predicts the true shelf life, then it becomes an economic concern, it
jCP'PF*Wni
Em/bl0is over predicted, then reformulating may be necessary. If the shelf life prediction食品伙伴个性空间3Cr%G+S/dd+]'a.V,X
indicates that the product meets the stability expectation, then the product has a
4ye|m
}P{0chance of performing satisfactorily in the marketplace.
wg:L-cIG*e${019.6 Confirmatory storage study食品伙伴个性空间?`_d Z`
19.6.1 Basis食品伙伴个性空间 d}
e7\^5?^.\}_
The difference in potential shelf life should be considered when scaling up from
D1W
X5ZP+n5QX r0experimental test batches to pilot plant and then to full scale production. Experience食品伙伴个性空间o3C1h{7_G\!Q
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much use for large-scale production (Graf and Saguy, 1991). Scale-up not only affects
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