Microsoft Word - 20-Agra_37427_vet


1576 
Original Article 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

THE EFFECT OF TRANSPORT DENSITY AND GENDER ON SKIN 
TEMPERATURE AND CARCASS AND MEAT QUALITY IN PIGS 

 
EFEITO DA DENSIDADE DE TRANSPORTE E DE GÊNERO NA TEMPERATURA 

DA PELE E QUALIDADE DE CARCAÇA E CARNE EM SUÍNOS 
 

Thuanny Lúcia PEREIRA1; Anderson CORASSA1; Cláudia Marie KOMIYAMA1;  
Ana Paula Silva TON1; Ângelo POLIZEL NETO1; Cláudio Vieira de ARAÚJO1;  

Jessika Lucia STUANI1; Roque Murilo HONÓRIO1 
1. Programa de Pós-Graduação em Zootecnia da Universidade Federal de Mato Grosso, UFMT, Campus Universitário de Sinop, Sinop, 

MT, Brasil. anderson_corassa@ufmt.br 
 

ABSTRACT: Pre-slaughter handling of pigs established properly is very important, not only from the point of 
view of welfare, but also for the quality of meat. The aim of present research was to evaluate the effect of gender and 
density of pigs during their transport to the abattoir on the skin temperature and carcass and meat quality. Were used 192 
(115.54 ± 6.03 kg) finishing pigs to investigate the effects of gender (barrows and gilts) and transport densities for 
slaughter (236, 251, and 275 kg/m²) on the skin temperature and carcass and meat quality. Average skin temperature 
between genders and transport densities at any point of time during pre-slaughter did not differ. Skin temperatures before 
unloading had the highest average value relative to all other time points, followed by immediately after unloading and 
remaining the same for the next 2 h. Lowest skin temperature value was registered on pigs at the pre-slaughter time 
followed by farm and at loading times. Pigs transported with different densities did not show differences for the skin 
carcass lesions. Meat from pigs transported at 275 kg/m² presented higher frequency of red, soft, exudative (RSE) and 
lower of red, firm, non-exudative (RFN) classes as compared to those for other densities. Animals transported at 236 and 
251 kg/m² did not differ as the frequency of RSE and RFN meat. Skin temperature of pigs oscillate along the pre-slaughter 
times and the pre-slaughter transport of pigs at 236 and 251 kg/m² generates less frequency classes of faulty pork, although 
difference in the densities did not have any effect on the skin temperature and skin lesions. 

 
KEYWORDS: Carcass characteristics. Meat characteristics. pH. Pigs. Pre-slaughter. Skin lesions. 

 
 
INTRODUCTION 
 

Well established pre-slaughter handling of 
pigs is extremely important not only from the 
perspective of welfare, but also for meat quality. 
Among the factors that affect pigs during transport, 
the density in the livestock truck may have negative 
influences on the behavioral, endocrine function, 
blood constituents, and meat quality. 

A wide variation exists in the density to be 
used in the transport of pigs in the pre-slaughter 
phase. Low and high densities affect the occurrence 
of losses at slaughter; therefore, most guidelines 
suggest the use of an average density. Some of the 
densities used currently include 0.33 m²/animal by 
the United States (NATIONAL PORK BOARD, 
2008), 235 kg/m² or 0.42 m² per pig near 100 kg by 
the European Union (EC, 2005), and 250 kg/m² by 
Brazil (CORASSA et al., 2013); however, there are 
no firm agreement on the precise loading densities 
that should be reduced at warmer temperatures 
(SCHWARTZKOPF-GENSWEIN et al., 2012). 

Before the slaughter of pigs, intense 
changes are observed in the behavior of animals, 

suggestive of the stress considering they are warm-
blooded animals with impaired thermoregulatory 
system due to the presence of keratinized sweat 
glands and the elevated levels of adipose tissue 
metabolism; as a result, an ambient temperature be 
maintained for the well-being of the pigs is 
recommended (ARAÚJO, 2012).  

Despite significant pig production in Brazil, 
little is known about the losses caused in the pre-
slaughter management, especially in regions where 
the distances from farms to slaughterhouses are 
large and the temperatures are high (PEREIRA; 
CORASSA, 2014). This makes it important to fill in 
the gap created by the lack of specific studies 
related to density in the transport of pigs as well as 
their impact on animal welfare and meat quality 
projects. We hypothesized that different genders and 
densities to pre-slaughter transport could influence 
the welfare and carcass and meat quality of pigs. 
Therefore, we aimed to evaluate the effect of 
transport density and gender of pigs during pre-
slaughter transport on their skin temperature, 
carcass, and meat quality. 
 

Received: 31/01/17 
Accepted: 05/07/17 



1577 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

MATERIAL AND METHODS 
 

The study protocol was consistent with the 
ethical principles for animal experimentation 
adopted by the National Council for Animal 
Experimentation Control and was approved by the 
Ethics Committee on Animal Use of the 
Universidade Federal de Mato Grosso (protocol 
23108.700436/14-7).  

We studied the same pigs as described 
previously (Pereira et al., 2015). The experiment 
was conducted in Brazil (coordinates 11°52ʹ23ʹʹS, 
55°29ʹ54ʹʹW and 380 elevation), climate as Aw and 
B2wA’a’ (Köppen’s climate classification), and 
24.70ºC of average temperature, 1,974 mm of 
annual rainfall e 1,327 mm of annual potential 
evapotranspiration (SOUZA et al., 2013). 

A randomized design in a 3 × 2 factorial 
arrangement was employed (236, 251, 275 kg/m² 
densities x barrows, gilts genders), with 28 
replicates per treatment, considering each animal as 
one experimental unit. A total of 192 finishing pigs 
with high genetic potential received a diet of 5 

mg.kg-1 ractopamine until 115.54 ± 6.03 kg, fasting 
for 12 h, and transportation to a distance of 290 km, 
of which 14 km unpaved, between 8:27 am and 1:45 
pm. Distance was similar to normally used in the 
production chain (PEREIRA; CORASSA, 2014). 
Animals were distributed in three densities of 
transport (236, 251, or 275 kg/m²) and two genders 
(barrows and gilts). Densities were adjusted by 
altering the number of pigs transported in the 
compartments (7, 8, or 9 pigs per compartment for 
236, 251, or 275 kg/m², respectively). Only one 
density was used per shipment, with pigs distributed 
in the four compartments of the front part of the 
truck body, barrows were located in the upper right 
and lower left compartments, and gilts in the upper 
left and lower right compartments. Two transport 
events were performed for each pre-slaughter 
density. 

At the slaughterhouse, animals were 
accommodated in holding pens (0.77 m²/pig) using 
the same number of animals as for measurements 
(Table 1) and the same truck (two floors; 4-axle; 
30,000-kg capacity; 12 aluminum compartments).  

 
Table 1. Distribution of animals during transport, at holding pens and slaughter according the treatments 

Density (kg/m²) Gender 
During transport Holding pens and slaughter 

Compartment Trip Total Pen Total 

236 Barrows 7 14 28 7 28 

 Gilts 7 14 28 7 28 

251 Barrows 8 16 32 7 28 

 Gilts 8 16 32 7 28 

275 Barrows 9 18 36 7 28 

 Gilts 9 18 36 7 28 

Total    192  168 

 
Unloading in the abattoir was performed 

similarly for all treatments. After a rest period of 3 
hours, pigs had their skin moisturized by spraying 
water in the waiting and were electrically 
discharged with 340 V, 50 Hz, 1.0 A for 3 seconds 
with electrodes on their temples and heart.  

Skin temperature was recorded with a 
digital portable infrared thermometer (Benetch®, 
accuracy 1.5oC, fixed emissivity) placed on the loin 
region of each pig 7 times: at the farm (TF), 
immediately after loading (TL), immediately before 
(TbU) and after unloading (TaU), one (T1A) and 
two hours after unloading (T2A), and pre-slaughter 

(TPS). Skin temperatures taken at the last four times 
were recorded on the animals housing in the holding 
pens of abattoir. 

A total of 28 carcasses per treatment were 
randomly selected for evisceration and sawing, 
followed by transferring the same to a cold room 
maintained at 4ºC for further analysis. Slaughter line 
procedures were performed according to Brazilian 
Normative Instruction. Lesions on the skin were 
determined on the left-half carcass of the pigs in the 
cold chamber at 4ºC, at 24-h postmortem, by 
following the classification based on 1–5 visual 
score of Meat Livestock Commission (1985) as (1) 



1578 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

no lesion at (5) severely lesion. All scores were 
given by the same observer. 

Swine meat was classified based on the pH 
measured at 24-h postmortem (pH24) and L* values 
(VAN HEUGTEN, 2001) in four groups: pale, soft, 
exudative (PSE, pH24<5.5 and L*>50); red, soft, 
exudative (RSE, pH24<5.5 and L*<50); red, firm, 
non-exudative (RFN, pH24 5.5-6.1 and L*>50), or 
pale (pH24 5.5-6.1 and L*<50). 

The pH was measured using the AK86 
portable pH meter (CE RS232, Akso®). The tissue 
used to measure pH was selected from the 13th and 
14th intercostal spaces (Longissimus thoracis 
muscle, LT) from a depth of 3.5 cm. 

In addition, at 24-h postmortem, a sample of 
100 g of the 6th and 7th intercostal spaces was taken 
for the color analyses. Meat color parameters were 
analyzed according to the CIELAB system (CR400; 
DL65 Minolta colorimeter) by reading the light 
reflectance in three dimensions as lightness (L*, a*, 
and b*).  

Date of skin temperature were subjected to 
variance analysis procedures using the SAS 
software Statistical Analysis System User’s Guide 
(SAS Institute Inc., Cary, NC, USA) with densities 
and genders as main factors and fixed effects of the 
days with the means compared by Tukey’s test, 
while the lesion score and pork classification was 
performed by Kruskal–Wallis analysis. A 
probability value of P ≤ 0.05 was considered 
statistically significant. 

 
RESULTS AND DISCUSSION 
 

Interactions between transport density and 
gender were not observed for skin temperatures. No 
significant differences were found in the average 
values of skin temperature between genders and 
transport densities at any time point during pre-
slaughter (Table 2). However, a considerable effect 
of the time of pre-slaughter handling on the skin 
temperature of the pigs was observed (Figure 1). 

 
Table 2. Mean values of skin temperature (º C) of pigs recorded in different moments of pre-slaughter 

classified by gender and transport density 

1. Skin temperature recorded at farm (TF), immediately after loading (TL), immediately before (TbU) and after unloading (TaU), one 
(T1A) and two hours after  unloading (T2A) and pre-slaughter (TPS). 2. Pd: significance of density; Pg: significance of gender; Pd×g: 
significance of density × gender 
 

Comparison of the different times of pre-
slaughter revealed skin temperature of the animals 
at TbU had the highest average value (P ≤ 0.05) 
relative to at all other times. Then, skin temperature 
at TaU showed the second highest value (P ≤ 0.05), 
which in turn did not differ from the measurement 
taken at T2A. 

Skin temperature values measured at T1A 
was below TbU and TaU (P ≤ 0.05), but did not 
differ (P ≥ 0.05) from T2A. Skin temperature 
recorded at TF and at loading were lower than all 
others time points, but higher than at the pre-
slaughter time (P ≥ 0.05). The lowest skin 
temperature value was registered on pigs at the pre-
slaughter time. 

Temperature of the skin of pigs increased 
dramatically from TF and at the end of the loading 

in relation to the time of final journey (Figure 1). On 
the other hand, after the unloading of the animals, it 
was observed the temperature decreased until it 
reached its lowest value in the pre-slaughter time. 

Stressful situations such as transportation, 
less floor space, long distance movement during 
handling, and aggressive handling intensity 
(RITTER et al., 2009) may lead to increased body 
temperature in pigs.  

The high number of animals or high mass of 
animals per area could restrict the flow of air 
between them, reducing heat loss by convection, 
resulting in higher skin temperatures. However, the 
results of the present study showed no effects of the 
transport floor space on the skin temperature at any 
time point during pre-slaughter, which is consistent 
with the results of Ritter et al. (2009) for evaluating 

Skin temperature1 
(º C) 

Density (kg/m²) Gender Significance2 CV  
(%) 236 251 275 Barrow Gilts Pd Pg PdxPg 

Farm  31.59 32.79 31.33 31.80 32.00 0.82 0.36 0.91 4.77 
Loading 31.26 31.12 31.77 31.14 31.63 0.98 0.13 0.59 6.48 
Before Unloading 36.31 34.98 35.50 35.28 35.91 0.89 0.12 0.46 7.75 
After unloading – im. 33.20 32.00 33.60 32.91 32.95 0.13 0.82 0.10 3.41 
After unloading– 1 h 33.98 30.38 31.80 32.23 31.87 0.47 0.29 0.77 6.88 
After unloading– 2 h 34.12 32.18 31.23 32.76 32.26 0.67 0.08 0.27 6.25 
Pre-slaughter 29.17 26.29 26.79 27.46 27.37 0.47 0.68 0.18 6.64 



1579 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

the rectal temperature of pigs transported at 263 and 
333 kg/m². This may be related to the type of 
vehicle used in the conditions of this study, with 

livestock container that allow natural or passive 
ventilation, which enhanced when the vehicles were 
in motion. 

 
 

 
According to the time of recording: farm (TF, 32.00d), immediately after loading (TL, 31.50d), immediately before (TbU, 35.71a) a 
nd after unloading (TaU, 33.06b), one (T1A, 32.18cd) and two hours after unloading (T2A, 32.62bc) and pre-slaughter (TPS, 27.55e). 
Open circles for gilts and solid circles for barrows.  Dotted, dot-and-dash and solid lines for 236, 251 and 275 kg/m² of transport density, 
respectively. Different superscripts indicate significant differences by Tukey’s test (P<0.05). 
Figure 1. Mean values of skin temperature (ºC) of pigs recorded at different moments pre-slaughter classified 

by gender and transport density. 
 

Main determinants of the internal thermal 
microenvironment in the livestock container are the 
external climatic conditions, the ventilation regime, 
internal air flow patterns, and the total heat and 
moisture production of the animals (NORTON et 
al., 2013). In addition, the absence of the effect of 
density during transport on pig skin temperature 
may also be related to the brief period of time in 
which the animals were subjected to different 
densities in which there was no air movement. 

Possible differences in the skin temperature 
between barrows and gilts could be related to the 
gender–specific interactions. Skin temperature of 
pigs on the farm and during the loading activities 
showed no difference because the evaluations were 
performed in close time intervals, and the 
temperature only increased at the end of the pre-
slaughter period of transport. Similar to previous 
studies reported no difference between loading until 
570 min after departure from the farm increased at 
unloading (GOUMON et al., 2013).  

Similarly, Pilcher et al. (2011) observed the 
temperatures on the trailer were, on average, least 
during the loading period at the farm and greatest 
during the period of waiting at the plant; and Mota 
Rojas et al. (2006) registered elevated corporal 

temperatures on the arrival at the slaughterhouse, 
varying between 38.55 and 39.23°C. However, 
Sutherland et al. (2009) observed temperature was 
higher in the trailer during the first 30 min of 
transport as compared to that in the last 75 min of 
transport. Other factors such as livestock truck 
specifications and general conditions of transport of 
animals can be related to the inconsistency of the 
present data.  

The increase in the swine skin temperature 
at TbU compared to previously, at farm, and after 
loading, may be related to the microclimate 
temperature of that time. Thermal patterns on the 
skin are related to the skin blood perfusion 
(HAUVIK; MERCER, 2012), as a consequence of 
increased heat loss to the environment via heat 
dissipation. However, the pigs’ sweating capacity is 
limited and their gas exchange may be particularly 
impaired in high temperature situations. In response 
to heat stress, the sympathetic vasodilator system 
can increase the blood flow in the skin, which in 
turn increases the convective heat transfer from the 
core to the periphery (WESCHENFELDER et al., 
2013). For this reason, the skin temperature is 
considered as an indirect indicator of the variation in 
status thermic and performance and the metabolic 



1580 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

rate of pigs in response to heat stress, which 
influences the pig physiology and pork quality 
(RITTER et al., 2009). 

Skin temperature recorded immediately 
before unloading (TbU) considers that the vehicle is 
stationary and there is no air flow, as a result the 
temperature of the front compartments rises, which 
carries a microclimate inside the livestock container 
with thermal variations, and thereby influences the 
welfare of pigs (WESCHENFELDER et al., 2013). 
In this sense, Mcglone et al., (2014) found 
temperature of the swine skin surface from the 
vehicles increased linearly with the increasing 
outside air temperature. In addition, the air 
temperature inside and outside of the truck during 
the journey can influence the loss of quantities of 
heat and fluids due to panting and sweating, and it is 
possibly related with enthalpy, which is the heat 
energy of the air surrounding the animal, dictating 
the degree of heat loss inside the trailer 
(VILLARROEL et al., 2011). 

After unloading of the animals, a tendency 
of reduction of the skin temperature with time was 

observed, possibly due to the accommodation of the 
animals in stalls, whose density, water availability, 
and the spraying of water on pigs offsetted the 
higher temperature. Araújo (2012) noted the use of 
spray at the beginning and end of the 3-h rest period 
provided adequate rest to the pigs and allowed better 
environmental adaptation, thereby reducing the 
surface temperatures of the animals. 

In general, skin temperatures of pigs 
reported in this study were greater than those of pigs 
used by Araújo (2012), who reported an average of 
23.45–28.47°C at the surface temperature of the loin 
region. This difference can be attributed to the 
different climatic conditions of each study region in 
terms of higher body temperatures or higher 
ambient temperature. 

Pigs transported at different densities did 
not show differences in their skin carcass lesions 
(Figure 2). Barrows transported at 236 kg/m² 
showed a higher value of carcass lesion score than 
gilts (P ≤ 0.05); moreover, there was no effect of 
gender on others densities. 

 

 
According to gender: crosshatched bars for gilts and solid bars for barrows. 
Figure 2. Skin carcass lesions score on the left half-carcass of pigs after 24 h postmortem classified by gender 

and transport density 
 

A higher density at transport of pigs from 
the farm to the slaughterhouses may increase the 
risk of aggression and thereby skin damage; 
moreover, this was not observed in this study, which 
is consistent with the observation of a previous 
study (GUISE et al., 1998) in which the stocking 
density did not affect the meat quality nor caused 
skin damage. Similarly, Ritter et al. (2006) reported 
increasing floor space during transport equivalent 

from 256 to 208 kg/m² did not affect the incidence 
of non-ambulatory, injured pigs at the plant. 

In contrast, Barton Gade and Christensen 
(1998) evaluated stocking densities of 200–285 
kg/m² and observed that 238 kg/m² density resulted 
in more pigs with unacceptable skin damage in all 
areas of the carcass as compared to other stocking 
densities. Also, at 256 kg/m² density, higher 
frequency of pigs with unacceptable skin damage 



1581 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

(only in the shoulder) were noted, supporting the 
risk of skin damage increases when a space more 
than 285 kg/m² is provided during transport. The 
increase in skin lesions on pork carcass is related to 
the pig behavior during transport such as trampling 
and/or aggressive encounters; moreover, it varies 
with pigs as some are more aggressive than others, 
which in turn is related to their cortisol levels 
(WARRISS et al., 1998) 

Failure to observe the effect of density 
transport on lesions score may be related to other 
influencing factors. Skin lesions on the carcass is 
caused by handling on the farm, mixing, fasting, 
handling at loading and unloading, transport to the 
slaughterhouse, lairage and repercussions on animal 
welfare, meat quality, and economical value. The 
presence of marks on the carcass is often considered 
as a secondary problem may be solved by removal 
of the blemished part. However, the related effects 
on meat quality variation must be considered. 
Recently, Brandt and Dall Aaslyng (2015) reviewed 
that the main stages on the day of slaughter at which 
skin damage occurs in finishing pigs is in the pick-
up facilities, although this describes the sum of 
occurrences throughout the day of slaughter in terms 
of skin damage that has been assessed and 
documented. 

Carcass lesions scores recorded in the 
density of 236 kg/m² in barrows may be due to the 
greater agitation and restlessness as compared to 
gilts. The scores were similar to that of 
Vanheukelom et al. (2012), who reported 60% of 
gilts had a lesions score of 1 and 40% had a score of 
2 in the middle region of the carcass as compared to 
38.6 and 50% for barrows, respectively. Lesions 
score of 3 and 4 were not observed in gilts, while 
10% of males had a score of 3 and 1.4% had a score 
of 4. The difference in skin lesions in pork carcasses 
may be related to the level of aggression linked to 
their gender. It can be inferred aggression leads to 
skin damage, which indicates that, although 
aggression is a normal behavior in pigs, but it is still 
stressful. Thus, this type of lesion may also be 
related to the large amount of space in the vehicle 
and the tendency of animals to display more 
movements due to vibration, in addition to the 
greater impact in the compartments and the lack of 
stability among pigs. 

Interactions between transport density and 
gender were not observed for the frequency of pork 
meat classes studied as they were not influenced by 
gender (Table 3). 

 
Table 3. Classes frequency of pork quality from the muscle Longissimus thoracis according to gender and 

transport density 

1 PSE: pale, soft, exudative; RSE: red, soft, exudative; RFN: red, firm, non-exudative 
Different superscripts within the same row indicate significant differences by Kruskal-Wallis’s test (p<0.05) 

 
Meat from pigs transported at 275 kg/m² 

presented higher frequency of RSE and lower of 
RFN classes as compared to the other densities (P ≤ 
0.05). Animals transported at 236 and 251 kg/m² did 
not differ (P ≥ 0.05) in their frequencies of RSE and 
RFN meat. PSE and pale pork occurrence was not 
influenced (P ≥ 0.05) by the densities during the 
transport of pigs in the pre-slaughter management. 
Color, firmness, and water-retention capacity 
changes featuring meat outside the ideal pattern 
(RFN) showed considerable frequencies in this 
study, in the order of 50.0, 46.5, and 78.6% at 
densities of 236, 251, and 275kg/m² or 58.3 and 
58.4% in the barrow sand gilts, respectively. 

Highest density (275 kg/m²) showed the 
negative effect that excessive pig quantity may have 
on the occurrence of non-ideal pork in terms of low 
frequency of RFN and high frequency of RSE pork. 
The RSE pork can be considered as intermediate 
PSE, but with normal coloration and without 
reaching the high protein denaturation, evaluated 
from the pH24 in the carcass. This non-compliance 
as RSE could be reported due to muscle fiber 
composition as higher proportion of IIb fiber, 
characterized by fast glucolytic metabolism and 
explained by the low pH45 and high drip loss 
(WESCHENFELDER et al., 2013). 

 In general, at the excessive pig density (275 
kg/m²), the animals showed a pH45 that may 

Classes 
(%)1 

Density (kg/m²) Gender Significance2 CV  
(%) 236 251 275 Barrow Gilts Pd Pg PdxPg 

PSE 16.07 16.04 14.29 16.67 14.26 0.87 0.65 0.34 12.6 
RSE 8.93b 3.57b 58.92a 25.00 22.62 0.03 0.67 0.50 19.8 
RFN 50.00a 53.46a 21.43b 41.67 41.60 0.04 0.90 0.56 17.7 
Pale 25.00 26.93 5.36 16.66 21.52 0.09 0.15 0.22 19.2 



1582 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

characterize a situation of discomfort in the vehicle, 
thus having an effect on the meat quality. According 
to the characterization of this study, this effect is 
indirectly related to the number of animals in each 
box. Gajana et al. (2013) observed highest risks of 
PSE occurrences when the space allowance during 
transportation was increased by an equivalent of 250 
kg/m² and the lowest risks of occurrences at 285 
kg/m² allowance of during transportation. 

Therefore, the results seemed to indicate a 
low probability of production of non-compliance 
pork when the density is decreased from 275 to 251 
or 236 kg/m². However, no effect of density on 
pH24 was recorded by Warriss et al. (1998). 
Differences in the responses between studies may be 
related to the interaction density transport during the 
journey. Gajana et al. (2013) observed an increased 
incidence of PSE pork when the transportation time 
was increased and stocking density was reduced.  

High frequencies of non-compliance as 
PSE, RSE, and pale pork observed in this study in 
all densities and genders, featuring a production 
system with difficulties in mitigating the factors 
generated less than ideal products. PSE pork is 
indicative of a short-lived stress, interference of 
stress hormones, influence on the muscle 
metabolism, enhanced depletion of the muscle 
glycogen, and deposition of lactic acid in the 
muscles. In general, the high frequency of PSE pork 
may be related to the local conditions, especially 
climate. In Brazil, the incidence of PSE pork is still 
high, which can be attributed to the poor pre-
slaughter handling conditions and genetic 
component of the animals since the occurrence of 
halothane gene was high in pig herds (PARANHOS 
DA COSTA et al., 2012). Moreover, others 

researches report expressive PSE frequency of 24 at 
68% (GAJANA et al., 2013). 

In this study, the gender did not have any 
effect on the pork quality traits. Vanheukelom et al. 
(2012) observed the content of this myoglobin in 
meat tissues was independent of the sexual category, 
which is why there difference in color pattern was 
negligible. 

The recommended densities to ensure 
welfare of pigs continue to remain debatable to 
prevent the occurrence of skin lesions by handling, 
density or fights, and especially for obtaining good 
meat quality. The density should be adjusted based 
on the local transport conditions. 

 
CONCLUSIONS 
 

Transport density it’s an important factor 
that can affect meat quality, as was observed in this 
study, an excessive number of pigs at a density of 
275 kg/m² generates non-ideal pork, while animals 
transported at 236 or 251 kg/m² generates less 
carcass damage although no effect was observed on 
the skin temperature and skin lesions.  

Comparison at different moments of pre-
slaughter revealed a highest skin temperature on the 
animals immediately before unloading, this, under 
the environmental conditions of this experiment. 
Barrows and gilts showed the same frequency 
classes responses of pork quality and skin 
temperature on the pre-slaughter management. 
Further research is needed to evaluate all the factors 
that can influence skin temperature of pigs and the 
occurrence of skin lesions in Brazilian conditions, 
thus to reduce the frequency of promoted non-ideal 
pork at the pre-slaughter management. 

 
 

RESUMO: O manejo pré-abate estabelecido adequadamente é importante, não apenas do ponto de vista de bem-
estar, mas também para qualidade da carne. O objetivo com o presente estudo foi avaliar o efeito do gênero e da densidade 
de transporte de suínos para o abatedouro sobre a temperatura da pele, qualidade de carcaça e carne de suínos. Foram 
utilizados 192 (115,54 ± 6,03 kg) suínos em terminação para avaliar os efeitos de gênero (machos castrados e fêmeas) e 
densidades de transporte para abate (236, 251, e 275 kg / m²) sobre a temperatura da pele e qualidade de carcaça e carne de 
suínos. Os valores médios de temperatura da pele entre os gêneros e densidades de transporte não diferiram no pré-abate. 
A temperatura da pele dos animais antes do descarregamento foi maior, seguidos pelo momento imediatamente após a 
descarga e mantendo o mesmo para as próximas duas horas. O menor valor de temperatura da pele foi registrado em 
suínos no momento pré-abate seguido pelos momentos à granja e ao carregamento. Os suínos transportados com diferentes 
densidades não apresentaram diferenças para as lesões na carcaça. Carne de suínos transportados a 275 kg / m² 
apresentaram maior frequência de carne vermelha, flácida e exsudativa (RSE) e menores de carne vermelha, firme e não-
exsudativa (RFN) em comparação com outras densidades. Os animais transportados à 236 e 251 kg/m² não diferem quanto 
a frequência de carne RSE e RFN. A temperatura de pele de suínos oscila ao longo dos momentos pré-abate, e transporte 
de suínos pré-abate com 236 e 251 kg/m² geram menor frequência de classes anormais de carne, embora diferenças nas 
densidades não tiveram efeitos sobre a temperatura da pele e lesões de pele. 

 
PALAVRAS-CHAVE: Características de carcaça. Características de carne. pH. Suínos. Pré-abate. Lesões da 

pele.  



1583 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

REFERENCES 
 
ARAÚJO, A. P. Manejo pré-abate e bem-estar dos suínos em frigoríficos brasileiros. Dissertação de 
mestrado em medicina veterinária. 2009. 139f. Dissertação (Mestrado em Medicina Veterinária) -
Universidade Estadual Paulista “Júlio de Mesquita Filho” Campus Botucatu. Disponível em: 
https://repositorio.unesp.br/bitstream/handle/11449/94579/araujo_ap_me_botfmvz.pdf?sequence=1. Acesso 
em: 08 jan. 2016. 
 
BARTON GADE P.; CHRISTENSEN, L. Effect of different stocking densities during transport on welfare and 
meat quality in Danish slaughter pigs. Meat Science, Barking, v. 48, p. 237-247, 1998. 
https://doi.org/10.1016/S0309-1740(97)00098-3 
 
BRANDT, P.; DALL AASLYNG, M. Welfare measurements of finishing pigs on the day of slaughter: a 
review. Meat Science, Barking, v. 103C, p. 13-23, 2015. https://doi.org/10.1016/j.meatsci.2014.12.004 
 
CORASSA, A.; KOMIYAMA, C. M.; PEREIRA, T. L.; SILVA, R. S. Caracterização do manejo pré-abate de 
suínos na região de Sinop – MT. Revista Agrarian, Dourados, v. 6:22, p. 479-485, 2013. 
 
Council Regulation (EC).N.1/2005 (2005).On the protection of animals during transport and related operations 
and amending directives 64/432/EEC and 93/119/EC and Regulation (EC) No 1255/97. Official Journal Of The 
European Union L3:22/12/2004, Pp:0001–0044. Disponível em: http://eur-lex.europa.eu/legal-
content/EN/TXT/?uri=celex%3A32005R0001. Acesso em: 08 jan. 2016. 
 
GAJANA, C. S.; NKUKWANA, T. T.; MARUME, U.; MUCHENJE, V. Effects of transportation time, 
distance, stocking density, temperature and lairage time on incidences of pale soft exudative (PSE) and the 
physico-chemical characteristics of pork. Meat Science, Barking, v. 95, p. 520–525, 2013. 
https://doi.org/10.1016/j.meatsci.2013.05.028 
 
GOUMON, S.; BROWN, J. A.; FAUCITANO, L.; BERGERON, R.; WIDOWSKI, T. M.; CROWE, T.; 
CONNOR, M. L.; GONYOU, H. W. Effects of transport duration on maintenance behavior, heart rate and 
gastrointestinal tract temperature of market-weight pigs in 2 seasons. Journal of Animal Science, Champaign, 
v. 91, p. 4925–4935, 2013. https://doi.org/10.2527/jas.2012-6081 
 
GUISE H. J.; RICHES H. L.; HUNTER E. J.; JONES T. A.; WARRISS P. D.; KETTLEWELL, P. J. The effect 
of stocking density in transit on the carcass quality and welfare of slaughter pigs: Carcass measurements. Meat 
Science, Barking, v. 50, p. 439–446, 1998. https://doi.org/10.1016/S0309-1740(98)00056-4 
 
HAUVIK, L. E.; MERCER J. B. Thermographic mapping of the skin surface of the head in bald-headed male 
subjects. Journal of Thermal Biology, Amsterdam, v. 37, p. 510–516, 2012. 
https://doi.org/10.1016/j.jtherbio.2012.05.004 
 
McGLONE, J.; JOHNSON, A.; SAPKOTA, A.; KEPHART, R. Establishing bedding requirements during 
transport and monitoring skin temperature during cold and mild seasons after transporte for finishing pigs. 
Animals, Basel, v. 4, p. 241-253, 2014. https://doi.org/10.3390/ani4020241 
 
Meat and Livestock Commission. Concern at ringside damage in pigs. Meat and Marketing Technical Notes, p. 
14-16, 1985. 
 
MOTA-ROJAS, D.; BECERRIL-HERRERA, M.; LEMUS, C.; SANCHEZ, P.; GONZALEZ, M.; OLMOS, S. 
A.; RAMIREZ, R.;  ALONSO-SPILSBURY, M. Effects of mid-summer transport duration on pre- and post-
slaughter performance and pork quality in Mexico. Meat Science, Barking, v. 73, p. 404–412, 2006. 
https://doi.org/10.1016/j.meatsci.2005.11.012 
 
National Pork Board. Transport Quality Assurance Handbook. 2008. Disponível em: 
http://www.Pork.Org/Filelibrary/Tqa/Manual.Pdf. Acesso em: 20 Mai. 2013. 



1584 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

NORTON, T.; KETTLEWELL, P.; MITCHELL M. A. Computational analysis of a fully stocked dual-mode 
ventilated livestock vehicle during ferry transportation. Computers and Electronics in Agriculture, v. 93, p. 
217–228, 2013. https://doi.org/10.1016/j.compag.2013.02.005 
 
PARANHOS, C. M. J. R.; HUERTAS, J. R.; STELLA, M.; GALLO, C.; DALLA COSTA, O. A. Strategies to 
promote farm animal welfare in Latin America and their effects on carcass and meat quality traits. Meat 
Science, Barking, v. 92, p. 221–226, 2012. https://doi.org/10.1016/j.meatsci.2012.03.005 
 
PEREIRA, T. L.; CORASSA, A. Fluxo do transporte de suínos para abate no Estado de Mato Grosso. Revista 
Brasileira de Saúde e Produção Animal, Salvador, v. 15, p. 970–982, 2014. https://doi.org/10.1590/S1519-
99402014000400022 
 
PEREIRA, T. L.; CORASSA, A.; KOMIYAMA, C. M.; ARAÚJO, C. V.; KATAOKA, A. The effect of 
transport density and gender on stress indicators and carcass and meat quality in pigs. Spanish Journal of 
Agricultural Science, Madri, v. 13, p. 1-11, 2015. 
 
PILCHER, C. M.; ELLIS, M.; ROJO-GÓMEZ, A.; CURTIS, S. E.; WOLTER, B. F.; PETERSON, C. M.; 
PETERSON, B. A.; RITTER, M. J.; BRINKMANN, J. Effects of floor space during transport and journey time 
on indicators of stress and transport losses of market-weight pigs. Journal of Animal Science, Champaign, v. 
89, p. 3809–3818, 2011. https://doi.org/10.2527/jas.2010-3143 
 
RITTER, M. J.; ELLIS, M.; BRINKMANN, J.; DEDECKER, J. M.; KEFFABER, K. K.; KOCHER, M. E.; 
PETERSON, B. A.; SCHLIPF, J. M.; WOLTER, B. F. Effect of floor space during transport of market-weight 
pigs on the incidence of transport losses at the packing plant and the relationships between transport conditions 
and losses. Journal of Animal Science, Champaign, v. 84, p. 2856–2864, 2006. 
https://doi.org/10.2527/jas.2005-577 
 
RITTER, M. J.; ELLIS, M.; ANDERSON, D. B.; CURTIS, S. E.; KEFFABER, K. K.; KILLEFER, J.; 
MCKEITH, F. K.; MURPHY, C. M.; PETERSON, B. A. Effects of multiple concurrent stressors on rectal 
temperature, blood acid-base status, and longissimus muscle glycolytic potential in market weight pigs. 
Journal of Animal Science, Champaign, v. 87, p. 351–362, 2009. https://doi.org/10.2527/jas.2008-0874 
 
SCHWARTZKOP, F.; GENSWEIN, K. S.; FAUCITANO, L.; DADGAR, S.; SHAND, P.; GONZÁLEZ, L. 
A.; CROWE, T. G. Road transport of cattle, swine and poultry in North America and its impact on animal 
welfare, carcass and meat quality: A review. Meat Science, Barking, v. 92, p. 227-243, 2012; 
https://doi.org/10.1016/j.meatsci.2012.04.010 
 
SOUZA, A. P.; MOTA, L. L.; ZAMADEI, T.; MARTIM, C. C.; ALMEIDA, F. T.; PAULINO J. Classificação 
climática e balanço hídrico climatológico no Estado De Mato Grosso. Nativa, Sinop, v.01, p. 34-43, 2013. 
 
SUTHERLAND, M. A.; KREBS, N.; SMITH, J. S.; DAILEY, J. W.; CARROLL, J. A.; MCGLONE, J. J. The 
effect of three space allowances on the physiology and behavior of weaned pigs during transportation. 
Livestock Science, Amsterdam, v. 165, p. 13–18, 2009. https://doi.org/10.1016/j.livsci.2009.06.021 
 
VAN HEUGTEN, E. Understanding pork quality. Swine News, v.24, p.3, 2001. 
 
VANHEUKELOM, V.; BEIRENDONCK, S. V.; THIELEN, J. S.; DRIESSEN, B. Behavior, production results 
and meat quality of intact boars and gilts housed in unmixed groups: A comparative study. Applied Animal 
Behaviour Science, Amsterdam, v. 142, p. 154-159, 2012. https://doi.org/10.1016/j.applanim.2012.10.004 
 
VILLARROEL, M.; BARREIRO, P.; KETTLEWELL, P.; FARISH, M.; MITCHELL, M. Time derivatives in 
air temperature and enthalpy as non-invasive welfare indicators during long distance animal transport. 
Biosystems Engineering, Heidellberg, v. 110, p. 253–260, 2011. 
 



1585 
The effect of transport…       PEREIRA, T. L. et al 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1576-1585, Nov./Dec. 2017 

WARRISS, P. D.; BROWN, S. N.; KNOWLES, T. G.; EDWARDS, J. E.; KETTLEWELL, P. J.; GUISE, H. J. 
The effect of stocking density in transit on the carcass quality and welfare of slaughter pigs: 2. results from the 
analysis of blood and meat samples. Meat Science, Barking, v. 50, p. 447–456, 1998. 
https://doi.org/10.1016/S0309-1740(98)00057-6 
 
WESCHENFELDER, A. V.; TORREY, S.; DEVILLERS, N., CROWE, T.; BASSOLS, A.; SACO, Y.; 
PIÑEIRO, M.; SAUCIER, L.; FAUCITANO, L. Effects of trailer design on animal welfare parameters and 
carcass and meat quality of three Pietrain crosses being transported over a short distance. Livestock Science, 
Amsterdam, v. 157, p. 234-244, 2013. https://doi.org/10.1016/j.livsci.2013.07.004