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1458 
Review Article 

Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

CAMPYLOBACTERIOSIS: AN EMERGING ZOONOSIS, 
UNDERDIAGNOSED AND UNDERREPORTED BY PUBLIC HEALTH 

AGENCIES IN BRAZIL 
 

CAMPILOBACTERIOSE: UMA ZOONOSE EMERGENTE, 
SUBDIAGNOSTICADA E SUBNOTIFICADA PELOS ÓRGÃOS DE SAÚDE 

PÚBLICA NO BRASIL 
 

Eliane Pereira MENDONÇA1; Roberta Torres de MELO2; Renata Resende PRADO3; 
Guilherme Paz MONTEIRO4; Silvia Cassimiro BRASÃO5; Marcela Franco TIMOTEO6; 

 Daise Aparecida ROSSI7 
1. Veterinary Doctor, Master's degree in Veterinary Science, PhD student in Veterinary Science - UFU, Uberlândia, MG, Brazil. 

eliane_vet@yahoo.com.br; 2. Biologist, Master's degree in Veterinary Science, PhD student in Veterinary Science - UFU, Uberlândia, 
MG, Brazil; 3. Veterinary Doctor, Student of master degree in Veterinary Science - UFU, Uberlândia, MG, Brazil; 4. Biologist, Master's 

degree in Veterinary Science - UFU, Uberlândia, MG, Brazil; 5. Veterinary Doctor, Student of master degree in Veterinary Science - 
UFU, Uberlândia, MG, Brazil; 6. Veterinary Doctor, Student of master degree in Veterinary Science - UFU, Uberlândia, MG, Brazil; 7. 

Professor of the Faculty of Veterinary Medicine -UFU, Uberlândia, MG, Brazil. 
 

ABSTRACT: The infection by Campylobacter spp. constitutes a zoonosis of worldwide distribution, with 
serious repercussions for public health and a significant socio-economic impact. The Campylobacter species that most 
often are implicated in outbreaks of gastrointestinal disease are C. jejuni and C. coli. Both are recognized as the most 
important and with greater pathogenic potential from the viewpoint of food safety. This review aims to clarify and discuss, 
based on literature, the epidemiology of Campylobacter spp. and the main challenges in their control, to assist in better 
understanding of the risk posed to human health. Due to the difficulty of isolating and cultivating of Campylobacter spp., 
the high cost and not mandatory, laboratory diagnosis by traditional cultivation techniques is not widely used in Brazil, 
resulting in lack of accurate data on the occurrence of the disease in the country. This factor has been identified as 
responsible for underdiagnosing and underreporting of the disease, which means that data on contamination of animal 
products or outbreaks are not statements of actual national situation. The epidemiology of  Campylobacter spp. is 
considered complex presenting multiple determinants in the spread of this microorganism. Chickens are important 
reservoirs of Campylobacter sp. and the main target of control measures, however, other vehicles of transmission, such as 
raw cow milk, drinking water and other foods of animal origin must also be considered in the set of measures to be taken 
to control disease. The infection by Campylobacter spp. cause gastroenteritis in humans and occurred by oral contact with 
infected animals. In fact, are pets or production and food consumption, the most important pathways. The clinical 
manifestations of the disease can be from mild to severe symptoms, including watery diarrhea, sometimes with blood, 
abdominal pain, fever, headache and nausea. Sometimes the infection can get complications after the diarrhea stops and 
starts a progressive paralysis that can result in respiratory failure and severe neurological dysfunction and may even lead to 
death. The occurrence of campylobacteriosi’s outbreaks should be mandatory to the authorities of surveillance, to provide 
an investigation of common sources and transmission control through preventive measures , thereby minimizing the 
potential risks to human health. 

 
KEYWORDS: Campylobacter spp.. Control. Broiler. Epidemiology. Brazil. 

 
INTRODUTION 

 
The infection by Campylobacter spp. is a 

zoonosis of worldwide distribution, with serious 
implications for public health and a significant 
socio-economic impact (EFSA, 2009). The high 
incidence of campylobacteriosis has become the 
most commonly cause of gastrointestinal disease 
reported worldwide (RIDLEY et al., 2008). 
 The reservoir of these organisms is the 
intestinal tract of domestic animals, wild or 
production (KELLER et al., 2007). Campylobacter 
species involved in human gastroenteritis are 
classified as thermo-tolerant by grow in 

temperatures higher than 40 ºC, being the species C. 
jejuni, C. coli, C. lari and C. upsaliensis the most 
incriminated (NESBAKKEN et al., 2003). 
 C. jejuni is present in the intestinal tract of 
birds and mammals, including production and  pet 
animals, being the cause of enteritis in young 
animals, including cattle, poultry, pigs, cats and 
dogs (GOMES, 2012) besides being the most 
prevalent species in human infections (RIDLEY et 
al., 2008). 
 Human infections occurs mainly by 
ingestion of raw or poorly processed poultry, pork 
and beef, or even by drinking unpasteurized milk 
and water, in addition to direct contact with carrier 

Received: 27/08/14 
Accepted: 20/01/15 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

animals (FDA, 2012). From the Campylobacter 
species identified, the most implicated in outbreaks 
of gastrointestinal disease are C. jejuni and C. coli, 
being recognized as the most important and with 
greater pathogenic potential from the viewpoint of 
food safety (RIDLEY et al., 2008). C. upsaliensis is 
also considered an important cause of gastroenteritis 
in humans, but its true incidence is underestimated 
by conventional culture methods, because this 
species is inhibited by the antibiotics used in the 
culture medium for the isolation of other 
Campylobacter species (MURRAY et al., 2009). 
 The specie C. jejuni is the most common 
cause of gastroenteritis in the United States of 
America as C. coli accounts for 2 % to 5 % of cases. 
This last specie is the most common cause of 
gastroenteritis in developing countries (MURRAY et 
al., 2009). 
 Due to the difficulty of isolating and 
cultivating of Campylobacter sp., high cost and its 
monitoring not required by law in foods, the 
laboratory diagnosis is not widely used in Brazil. 
These facts have been identified as responsible for 
underdiagnoses and underreporting of the disease, 
which means that data about the contamination of 
animal products or outbreaks are not statements of 
the national situation. In contradiction to 
underreporting cases of campylobacteriosis in 
Brazil, in industrialized countries the cases of 
enteritis Campylobacter spp. are more frequent than 
those caused by Salmonella spp. (WHO, 2012). 
 In Brazil there is no specific legislation 
governing the analysis of Campylobacter spp., 
either by the Ministry of Agriculture, Livestock and 
Supply (Ministério da Agricultura, Pecuária e 
Abastecimento - MAPA) and the Ministry of Health 
(Ministério da Saúde) to expand the research in this 
area is needed to better analyze the occurrence of 
this pathogen in products of animal origin, as well 
as other foods that may be carriers of these agents 
and their potential risks to human health. 
 
DEVELOPMENT 
Epidemiology 
 The epidemiology of Campylobacter spp. is 
considered complex, and currently the actual 
incidence of infections by these organisms in Brazil 
is unknown, since the disease is not reported to 
official public health agencies. Some studies report 
that in developed countries, these bacteria cause 
gastroenteritis with a frequency of two to seven 
times greater than bacteria such as Escherichia coli 
O157:H7, Shigella spp. or even Salmonella spp. 
(ALLOS, 2001; WHO, 2012; EFSA, 2014). 
 The species C. jejuni and C. coli are 

recognized as the first agents of diarrhea in 
industrialized countries and second or third in 
developing ones, with transmission mainly 
associated with consumption of animal origin food 
(FERNÁNDEZ et al., 2005). The relevance of this 
fact is related to Campylobacter spp. presence in 
gastrointestinal tract of animals such as chickens 
and pigs, and their carcasses (JORGENSEN et al., 
2002). This correlation arises from Campylobacter 
sp. colonization of these asymptomatically animals, 
this is the most important origin of carcasses 
contamination (BUHR et al., 2002). 
 The origin of C. jejuni presence in eggs is 
discussed, and little is known about the 
transmission. Researches show that the bacterium is 
restricted to the outside of egg shell (JONES et al., 
2006; JONES; MUSGROVE, 2007). However, 
Campylobacter has been isolated in the internal 
contents of eggs that were negative on the outside 
(ADESIYUN et al., 2005). Thus, although studies 
shows that transmission is possible via 
transovarially (BUHR et al., 2002) this is not 
considered an important pathway in the spread of 
the pathogen and few studies show the passage of 
bacteria through the pores of the egg shell. 

Fonseca et al. (2006) investigated the 
presence of Campylobacter sp. in matrices that were 
cloacal swabs positive for Campylobacter spp. using 
traditional microbiological culture and PCR 
techniques. The bacteria was detected by PCR, but 
not by traditional cultivation. Subsequently, Fonseca 
et al. (2011) placed the eggs in contact with 
contaminated shavings found that the bacteria were 
able to enter through the shell pores. They also 
observed that inoculation of C. jejuni outer of the 
egg membrane leads to high early embryonic 
mortality. 

In a study conducted in Denmark meat 
samples were collected from slaughterhouses for 
Campylobacter spp. research, verifying that 47% of 
cattle, 46% of swine and 36% of chickens were 
contaminated by this pathogen. Another study 
conducted in the UK showed a prevalence of 32% 
for C. jejuni in feces samples collected from healthy 
dairy cows (YAN et al., 2005). 

According to the EFSA (2009), the 
transmission of campylobacteriosis varies agreed 
with country development degree. Thus, in 
developing countries, the routes of transmission are 
complex and multifactorial and campylobacteriosis 
in developed countries is considered mainly a food 
infection whose main source is the chicken meat 
(EFSA, 2005). Murphy et al. (2006) states that the 
rate of campylobacteriosis incidence in the United 
States in 2004 was 12.9 cases per 100,000 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

confirmed cases of food-borne bacterial diseases in 
humans, whereas in the UK the rate was 73/100.000 
in 2003 and in the countries of northern Europe was 
60 to 90/100.000. 
 C. jejuni can survive and even multiply 
within free-living amoebae, establishing 
endosymbiotic relationships (OLOFSSON et al., 
2013). This kind of symbiosis, between bacteria and 
protozoa, particularly Acanthamoeba castellanii, 
was also reported to Arcobacter butzleri, other 
species of family Campylobacteraceae 
(FERNÁNDEZ et al., 2012; MEDINA et al., 2014). 
 The fact that C. jejuni survives within free-
living amoebae, can have serious repercussions 
epidemiologically since these protozoa may act as 
reservoirs and / or vectors of bacteria that have the 
ability to survive as endosymbionts (KHAN, 2006). 
Furthermore, amoebas protect any microorganism 
that is inside of themselves, because they resist the 
action of disinfectants and adverse environmental 
conditions (KILVINGTON & PRICE, 1990). 

The possibility of companion animals, 
particularly dogs, could be a source of 
Campylobacter spp. which causes disease in 
humans has been investigated. Nowadays, there are 
epidemiological evidence of an association between 
Campylobacter spp. disease in dogs and in humans, 
however, are not clearly known the risk factors 
associated with this transmission (MSFFG, 2008). 
The frequency of Campylobacter species isolation 
that causes gastrointestinal diseases in Brazil is 9% 
in swine, 5% and 8% related to dogs and cats. In 
pigs, C. coli is the predominant specie. In dogs and 
cats, the highest rate of isolation is observed in 
individuals with less than six months old (AQUINO 
et al., 2002). 

 
Campylobacter in broiler carcasses 

The chickens are often colonized by C. 
jejuni (65 to 95%) and less frequently by C. coli, 
and rarely by other Campylobacter spp. The 
colonization of broiler chickens is age related. The 
majority of birds is negative for the organism until 
two weeks of age, and once occurred colonization 
by Campylobacter spp. transmission by coprophagy 
is extremely fast and can be 100% of chickens’ 
colonization over a 72 hours period (OIE, 2008). 

The prevalence of Campylobacter sp in 
chickens and their carcasses is quite high, equivalent 
to 41.1% and 45.9% (BOTTELDOORN et al., 
2008). A study carried out in Ireland, in 2008, 
showed that of 394 broiler cooled carcasses studied, 
98% were contaminated with C. jejuni (EFSA, 
2010). In some European Union member countries 
in 2007, the prevalence of fresh chicken meat was 

equivalent to 83%. In Iran, the prevalence was 63% 
and in Japan 45.8% (FAO, 2009). In Brazil, studies 
showed high prevalence of Campylobacter spp. 
Aquino et al. (2002) isolated C. jejuni and C. coli 
species in 60% of chicken carcasses samples 
analyzed and Kuana et al. (2008) in 99% of the 
studied carcasses. Franchin et al. (2007) evaluated 
335 carcasses samples, water and different points of 
the slaughter line equipment, and found positivity in 
71.3% of samples. Lower rates were found by Melo 
(2012), who isolated Campylobacter spp. in 22.38% 
of 420 chicken chilled and frozen carcasses, from 
three Brazilian states (Minas Gerais, Goiás, Distrito 
Federal). Of these, 55 (58.5%) were identify as C. 
jejuni, 19 (20.2%) as C. coli and 20 (21.3%) as 
Campylobacter spp. 

According to Berrang et al. (2001), when a 
broiler flock contaminated with Campylobacter sp. 
enters the processing plant, it is likely that a large 
amount of the agent is already attached, or 
transferred to the skin during feathers withdrawal. 
The authors suggested that the increase in 
Campylobacter sp. chicken breast skin occurs at the 
time of feathers removal due to the elimination of 
the bacteria by the cloaca, which is facilitated by 
electric stunning of poultry. Campylobacter sp. has 
high survivability in extreme conditions during the 
production process of chickens due to the ability of 
attachment in the feathers follicles and the deep 
crevices of the bird skin. These recesses provide 
ideal conditions for bacteria to adhere to and support 
the variations in processing conditions (JANG et al., 
2007). Therefore, it is able to survive in frozen meat 
(-20ºC) even after long periods, which makes this 
type of food a potential source of infection in case 
they are not properly cooked in the right 
temperature (70-75ºC for 5 minutes) before 
consumption (MELO, 2013). 

In Europe, the prevalence of Campylobacter 
sp. was 75.8% in broiler carcasses, which means 
that on average about eight out of 10 carcasses were 
contaminated. The most prevalent species  were C. 
jejuni and C. coli, with 51.0% and 35.5%, 
respectively. The proportion of negative samples 
quantitatively, in other words, below the threshold 
of 10 CFU/g, ranged from 3.8% to 98.6% among 
European countries, while the proportion of samples 
with very high counts above 10,000 CFU/g ranged 
from 0% to 31.9% (EFSA, 2010). According to 
Yang et al. (2001) the incidence on carcasses is 
mainly affected by the process conditions of 
scalding and chiller. 

The main locations in poultry colonization 
by Campylobacter spp., is the cecum, large intestine 
and cloaca (POTTURI-VENKATA et al., 2007). The 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

high metabolic temperature of birds (42º C) 
predisposes this species to be the main reservoir of 
Campylobacter spp. and assists in keeping this 
agent, since grow best in environments where 
temperatures around 42 °C (HORROCKS et al., 
2008). 

Stern and Ro Bach (2003) evaluated the 
presence of Campylobacter spp. in broiler carcasses 
in North Georgia, and compared the results obtained 
in 1995 and 2001, obtaining a lower bacterial count 
in the collections of 2001, which was attributed to 
the implementation of the Hazard Analysis System 
and Critical Control industry (HACCP ). They 
mentioned that among the factors that might have 
contributed to reducing contamination were the 
increasing of the volume of water used for housing 
(20L to 36L) and immersion in chiller containing 40 
to 50 ppm chlorine, procedures that were not 
performed in 1995. 

The contamination of slaughter carcasses 
depends on several variables, including the age of 
the birds, the level of contamination of flocks and 
the influence of factors related to the production, 
transportation and processing. The level of 
contamination in these products has implications on 
public health and is fundamental to the existence of 
a traceability live birds in chicken carcasses in 
derivatives and sub-products (KUANA et al., 2008). 
 
Campylobacter in swine carcasses 

The epidemiology of infections caused by 
Campylobacter spp. in swine is complex, with 
multiple determinants in the spread of this 
microorganism. Along the chain production is 
possible to observe the expansion of the problem, 
usually by the rapid transmission of the bacteria to 
uninfected animals after contact with positive, 
animals and environments (GABRIEL, 2009). 

Alter et al. (2005) could not isolate C. coli 
in swine after 24 hours of birth accommodated in 
the farm, but most animals (75%) were colonized in 
the first week of life. The authors concluded that the 
incidence of C. coli increased from zero (newborns) 
to 78% (animals of 24 weeks) after transporting the 
animals from farm to slaughterhouse. 

The occurrence and distribution of C. jejuni 
and C. coli was investigated by Jensen et al. (2006) 
in extensive swine farms in Denmark. The study 
showed high prevalence of Campylobacter spp. 
(100%) in swine extensive creations, predominantly 
C. coli. 

In Brazil, the prevalence of Campylobacter 
sp. in swine was evaluated in 120 feces samples and 
120 swine carcasses from four different 
slaughterhouses in the state of São Paulo. Fecal 

samples from 30 (25%) were positive for C. coli and 
two (1.6%) for C. jejuni. All samples from carcasses 
(120) were negative for Campylobacter sp. 
(CAMPOS, 2006). 

The effect of blast chilling (rapid cooling of 
the housing by contact with air at 21.9° C) on the 
occurrence of Campylobacter sp. was evaluated by 
Nesbakken et al. (2007) in swine carcasses. The 
bacteria was isolated in 56.7% (34/60 lamb 
carcasses) before chilling and in 1.7% of the 
samples after the procedure. A significant decrease 
of these microorganisms in swine carcasses after 
chilling blast, and the authors attributed this effect to 
the sensitivity of the bacteria to freezing and drying. 

The occurrence of Campylobacter sp. was 
investigated by Pearce et al. (2003) in a swine 
slaughterhouse. Thirty samples, representing 360 
pig carcasses were evaluated. Campylobacter sp. 
was detected in 33% of samples after bleeding, 0% 
after scrap machine, 7% immediately before 
chilling, and 0% after all night at chilling. The 
bacteria was recovered in 100% of samples 
collected in the rectum and 80% of individual 
samples of the colon. 

Prevalence and possible routes of 
Campylobacter spp. contamination in swine 
slaughterhouse were evaluated by Malakauskas et 
al. (2005) in Denmark. The study showed that 28/44 
(63.3%) samples collected at slaughter were 
contaminated by this bacteria, 23.4% of the isolates 
were identified as C. jejuni and 76.6% as C. coli. 
The results suggest that contamination was 
originated from the swine’s gastrointestinal tract and 
happened during all the slaughter process. 

Gabriel (2009) analyzed the presence of 
Campylobacter spp. in samples from swine 
finishing up the steps of slaughter from three 
batches (A, B and C), in the Triângulo Mineiro, 
Minas Gerais. Positivity in swine’s feces housed at 
the farm was 66.6%, 53.3% and 80% in swine from 
the feedlots A, B and C, respectively. In meat 
samples collected from swine carcasses during 
slaughter results of positivity were 51.1%, 31.1% 
and 48.8%, in flocks A, B and C, respectively. The 
same study also showed a higher rate of carcasses 
contamination after scalding step and scrap 
machine, with 57.7%, which is believed to be the 
largest possible contamination of carcasses due to 
the characteristics of the process and difficulty of 
cleaning the equipment. Despite reported decrease 
in the number of positive samples during the 
slaughtering process steps studied were not able to 
guarantee the food safety. 

Wilson et al. (2008) indicated for control of 
meat contamination by animal feces, equipment 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

sterilization and additional care when handling the 
animals with positivity. The authors believe that the 
primary route of Campylobacter spp. transmission 
to humans is the food chain and suggests that the 
incidence can be dramatically reduced by improved 
of biosafety in farms and preventing transmission 
via food. 

 
Campylobacter in cattle 

Cattle and sheep, as swines, are also often 
colonized by Campylobacter spp. and colonization 
is higher in young than in older animals. In the older 
animals, the microorganisms are occasionally 
detected in feces, probably due to low levels then 
the possible elimination or intermittent excretion. 
These animals are primarily colonized by C. jejuni, 
C. coli, C. fetus and C. hyointestinalis, unlike swine 
that are predominantly colonized by C. coli (OIE, 
2008). Several studies have reported that C. jejuni 
can cause enteritis in calves and bovine mastitis 
while C. fetus is responsible for abortion and 
infertility in cattle (STANLEY; JONES, 2003). C. 
fetus does not belong to the thermophilic species 
group. 

Inglis et al. (2003) analyzed 380 fecal 
samples from feedlot cattle in Canada and found 
that 49% had C. lanienae. In the same study, 37% of 
samples were positive for C. jejuni, 8% to C. 
hyointestinalis and 0.5% for C. coli. Fernández and 
Hitschfeld (2009) analyzed 300 samples of fecal 
swabs of cows in Chile and obtained 32.0% positive 
for Campylobacter sp., with 85 identified as C. 
jejuni and 11 C. coli. Bailey et al. (2003) studied 19 
flocks in Australia, and found that Campylobacter 
sp. prevalence varied from 0% to 24% for dairy 
cattle, and from 0% to 52% for cattle. 

In Brazil, there is low information about the 
relevance of beef for C. jejuni and C. coli 
transmission transmission to humans; studies are 
needed to determine the prevalence of these bacteria 
in bovine products, as well as determining control 
measures (FERNÁNDEZ; HITSCHFELD, 2009). In 
ground beef meat analyzed by Ferreira (2008), the 
presence of Campylobacter sp. was detected in 
32.5% (13/40) of samples. 

The higher prevalence of Campylobacter sp. 
in beef cattle is an epidemiological event that can be 
associated with the environment in which these 
animals are housed. While these animals are raised 
on pasture and in contact with a diverse 
environment, dairy cattle are kept in confinement 
and in better hygiene conditions (FERNÁNDEZ; 
HITSCHFELD, 2009). In this sense, there is need to 
perform further studies to elucidate the sources of 
environmental contamination of beef. Furthermore, 

the environment of processing plants for these 
animals and the assessment of the food of bovine 
origin are also important factors in the 
implementation of specific control measures to 
improve the safety of the final product 
(FERNÁNDEZ; HITSCHFELD, 2009). 

 
Campylobacter in dogs 

According to Hirsh (2003) approximately 
10% and 5% of asymptomatic dogs and cats are 
intestinal carriers of C. jejuni. These percentages 
may be higher in animals purchased in kennels. 
Prevalence of thermophilic Campylobacter species 
in samples of rectal swabs from dogs and cats varied 
with age group, with or without sign of 
gastroenteritis in two animal shelters in Ireland, 
showed that the isolation rate was higher in dogs 
and cats less than six months and significantly 
higher in dogs compared to cats (ACKE et al., 
2006). Tenkate and Stafflord (2001) stated that 
about 6% of cases of human campylobacteriosis 
were transmitted from pets. 

Knowing if living with pets increases the 
chances of human Campylobacter sp. infection is an 
epidemiological information that should be further 
investigated. This possibility warns of hygiene 
required in handling them and in order to avoid the 
promiscuity, mainly with children under five years, 
which is considered the highest risk group. 

Rodrigues (2011) examined 120 feces 
samples from pets animals (103 dogs and 17 cats) 
attended at the Veterinary Hospital of the Faculty of 
Veterinary Medicine of Universidade Federal de 
Uberlândia. Of these 22/120 (18.3%) were positive 
for Campylobacter spp. (20 dogs and two 
cats).There is an association between the presence 
of C. jejuni and diarrhea in animals. In addition to 
C. jejuni in asymptomatic animals, Rodrigues 
(2011) also identified C. coli. 

 
Campylobacter in humans 

Most cases of human campylobacteriosis 
are presented in isolated episodes, but outbreaks are 
also observed. Gastroentiritis infectious caused by 
Campylobacter spp. occurs  in humans by oral via, 
through consumption of contaminated food of 
animal origin or by contact with pets or production 
infected. It can also occur by consumption of other 
foods such as unpasteurized milk or contaminated 
water (Figure 1). How not to feed via transmission 
can still quote the direct transmission from 
individual to individual, but is not considered an 
important mode of transmission in industrialized 
countries (EFSA, 2005). 



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Figure 1. Leading transmission forms of Campylobacter spp. in animals and man. Figure adapted from Young 

et al. (2007).  
 

C. jejuni is responsible for 80-90% of 
infections in humans, while C. coli is observed in  
7% and C. lari, C. upsaliensis, and C. 
hyointestinalis only 1% of human cases 
(NESBAKKEN et al., 2003). 

According Malakauskas et al. (2005), in 
Denmark, the number of registered cases of 
campylobacteriosis increased by four times with 82 
infections per 100,000 inhabitants in 2002, with the 
same trend observed in other industrialized 
countries. Reiersen et al. (2002) reported that in 
Iceland, the incidence of Campylobacter sp. in 
humans reached epidemic proportions between June 
1998 and March 2000. Between 1990 and 1995, the 
incidence was 14.6 cases per 100,000 
individuals/year. Since 1996, cases began to 
increase reaching 157 cases per 100,000 individuals 
in 1999. During 2000 and 2001, there was a fall 
(87.1 and 75.4 cases per 100,000 individuals, 
respectively). 

In 2007, campylobacteriosis was the most 
frequently reported zoonotic disease in humans in 
the European Union with 200,507 confirmed cases 
and most states still points increase this number 
(EFSA, 2009). 

In Chile, Fernández et al. (2005) serotyped 
50 C. jejuni strains subsp. jejuni isolated from 
chicken carcasses and 50 isolated from children’s 
feces, finding 17 different serotypes and 6 identical. 
The number of different serotypes suggests that in 
Chile’s southern, not only the poultry meat is the 
vehicle of C. jejuni subsp. jejuni in humans, but 
other unidentified sources or reservoirs are 
involved. 

There is a resistance to infection by 
Campylobacter spp. in individuals with eating 

habits high risk who are exposed to the agent 
several times, as occurs in developing countries. In a 
study conducted in Egypt, that is an endemic 
country to campylobacteriosis, residents are 
repeatedly exposed, this resulted in high rates of 
diarrhea and large production of antibodies against 
multiple serotypes of Campylobacter sp. in patients, 
especially in children (WIERZBA et al., 2008). 

Rodrigues (2011) examined 160 feces 
samples from children attended at the Emergency 
Department of the Hospital of the Universidade 
Federal de Uberlândia,  finding that 6.87% (11/160) 
samples were positive for Campylobacter spp. In 
feces of children with diarrhea, C. jejuni and C. coli 
were identified and in non-diarrheal feces, were 
identified as Campylobacter spp. 

 
Pathogenesis and virulence 

The infective dose of Campylobacter sp. is 
low, it is estimated that the intake of less than 500 
cells can cause disease (IVANOVIC, 2012). The 
effort to define the role of specific virulence factors 
in diseases caused by Campylobacter sp. factors has 
been frustrated by the lack of an animal model to 
reproduce the disease. It is known that the primary 
mechanism of pathogenicity is the invasion of the 
intestinal mucosa which C. jejuni being the best 
studied species. Although adhesins, cytotoxic 
enzymes and enterotoxins have been detected in 
these species, its exact role in disease remains 
poorly defined, it became clear that the risk or 
severity of the disease to the host is influenced by 
the infecting dose and the immune status of the 
individual (MURRAY et al., 2009). 

Bacteria of this genus are actively moving 
by a single polar flagellum at one or both ends of 



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the cell. Variants of C. jejuni, properties with 
incomplete or no scourge can not colonize or require 
large amounts of inoculum, compared to mobile 
strains (complete flagellum), suggesting that the 
motility, has fundamental importance in 
colonization (GOMES, 2012). 

According Jawets et al. (1998), species of 
Campylobacter sp. have lipopolysaccharides (LPS) 
and flagella structures that act as adhesion and 
invasion being able to produce cytotoxins and 
enterotoxins. Diverse microorganisms can multiply 
in the small intestine epithelium and then, the 
bacteria invade and cause inflammation, resulting in 
the appearance of erythrocytes and leukocytes in the 
feces. Eventually, the bloodstream is invaded by the 
bacteria and develop an enteric fever notes. The 
localized tissue invasion associated with toxic 
activity appears to be responsible for enteritis. 

Having successfully fixation and 
internalization, Campylobacter spp. colonizes the 
epithelial cells by a number of mechanisms that 
include: invasion (RUSSEL et al., 1993), toxin 
production (WHITEHOUSE et al., 1998) and 
apoptosis (RUSSEL et al., 1993). In this 
environment, Campylobacter spp. can avoid the 
attack by phagocytes and enter the circulatory 
system in immunocompromised patients (WALLIS, 
1994). The attack may involve phagocytosis by 
macrophages, release of intermediate reactions and 
release of inflammatory cytokine (JONES et al., 
1999). 

The flaA, ciaB, cadF and pldA genes are 
classified as reference for the study of the 
mechanisms of Campylobacter sp. pathogenicity 
(ZHENG et al., 2006). These genes encode proteins 
involved in adhesion and invasiveness of C. jejuni 
and can therefore be considered as possible 
virulence factors in this species. The flaA gene 
encoding flagellin A, which is required for the 
adhesion and invasion of epithelial cells by C. jejuni 
(WASSENAAR et al., 1991), The ciaB gene 
encodes a protein involved in cell invasion 
(RIVERA AMILL et al., 2001), while cadF encodes 
a protein that interacts with fibronectin in the 
extracellular matrix of the host colonization 
participating cell surface (MONTEVILLE et al., 
2003). The pldA gene is related to cellular invasion 
and encodes a protein involved in the synthesis of 
outer membrane phospholipase (ZIPRIN et al., 
2001). 

Melo et al. (2013) analyzed virulence genes 
in C. jejuni strains isolated from poultry carcasses in 
Brazil showing that this species has great 
importance in the pathogenesis of human disease. 
This work showed that flaA, pldA, cadA, ciaB and 

cdtABC genes involved in adhesion, colonization, 
invasion of cells and toxin production process, were 
present in 74.5%, 63.6%, 67.3%, 67.3% and 65.5% 
of the strains,  respectively. 

Several studies have reported the presence 
of these genes in C. jejuni strains isolated from 
humans regardless of the source and the ability of 
adhesion and invasion in Caco-2 cells (ZHENG et 
al., 2006). 

Besides these, the extensional citolethal 
toxin has been linked to the pathogenesis of C. 
jejuni in human and animal infections (DATTA et 
al., 2003). This toxin affects the layer of epithelial 
cells, causing progressive distension and death in 
various cell lineages by the intracellular 
accumulation of cyclic adenosine mono-phosphate 
(cAMP) (MARTINEZ et al., 2006). 

As invasive bacteria, Campylobacter sp. can 
lead to septicemia. The treatment of patients with 
sepsis by Campylobacter sp. must be intense given 
that the prognosis is unfavorable. Related 
extraintestinal Campylobacter sp. infections like 
meningitis diseases are considered rare. Some post-
infection manifestations may occur, such as reactive 
arthritis, urticaria or erythema nodosum and 
Guillain-Barré Syndrome (GBS), which, is the most 
severe manifestation (ALVES, 2006). 

It has been recognized association between 
campylobacteriosis and GBS. The disease is usually 
of acute evolution, lasting hours or days, with 
rapidly progressive weakness, sometimes 
progressing to respiratory failure, but with good 
recovery. In more severe cases, respiratory failure 
may occur, leading to cardiac arrhythmias, sweating 
and hypertensive peaks, with a mortality rate 
between 4% and 10% of cases (CANAL; PÁEZ, 
2007). 

Godschalk et al. (2004) determined that 
specific bacterial genes, known as lipo-
oligosaccharides of C. jejuni (LOS) genes are 
required for the biosynthesis of ganglioside mimic 
structures of the nervous tissue and induction of 
anti-gangliosides antibodies. This molecular 
mimicry of C. jejuni (LOS) with gangliosides is 
considered an inducer of cross-reactive antibodies 
that lead to GBS. 

Gastroenteritis by C. jejuni 
characteristically produces histological lesions of 
the mucous surfaces of the jejunum, ileum and 
colon. The mucosa appears edematous, ulcerated 
and bloody, with abscesses in the crypts of epithelial 
glands and infiltration of the lamina by neutrophils, 
mononuclear cells and eosinophils. This 
inflammatory infiltrate is characteristic of invasion 
of microorganisms in the intestinal tissue 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

(MURRAY et al., 2009). 
The ability of invasion seems to be strain 

dependent and strains isolated from the environment 
are much less invasive in HeLa cells than strains 
isolated from humans or animals (EVEREST et al., 
1993). Melo et al. (2013) selected five strains 
classified as most virulent to verify its ability to 
alter the morphology of Caco-2 cells and observed a 
loss of cells confluence for all strains tested. This 
loss of cellular integrity, reflected by loss of the 
ability to transport fluids and electrolytes between 
cells, contributes to the clinical symptoms of 
campylobacteriosis in vivo. 

As already discussed, the main risk factor 
for human infection includes ingestion and handling 
of poultry, mainly chicken, raw or improperly 
processed, accounting for 50% to 70% of 
campylobacteriosi’s cases (SERNIENE; 
MALAKAUSKAS, 2008). Food contamination can 
occur in all of the food chain, directly or indirectly 
by cross-contamination, meaning a major risk to 
human health (ELLIS-IVERSEN et al., 2009). 
 
Clinical signs 

The clinical manifestations, when they 
occur, involve human and younger animals 
(FONSECA, 2006). Chickens and pigs are 
asymptomatic carriers of Campylobacter sp., but 
there may be clinical signs in lambs and sheep 
(abortion and metritis by C. jejuni), dogs and cats 
(diarrhea and frequent vomiting by C. jejuni and C. 
upsaliensis) (PARK, 2002). 

According to the World Health Organization 
(WHO, 2011) Campylobacter sp. in human is the 
leading cause of severe forms of diarrhea. The 
incubation period ranges from two to five days, 
reaching up to 10 days (ALVES, 2006; GARCÍA; 
CRAVIOTO, 2007). Before the onset of symptoms, 
usually 12-24 hours, it is usual that presents a period 
with fever, headache and general malaise. At the 
beginning of infection, fecal matter is aqueous, but 
insofar as the disease progresses, it becomes bloody. 
The presentation can vary from a lighter form of 
short-term to a more severe and prolonged 
framework (CANAL; PÁEZ, 2007). 

Infection rarely results in consequences that 
remain long-term in order to develop more serious 
diseases such as sepsis, abortion, meningitis, 
abscesses and complications such as GBS. GBS is 
an autoimmune disease that causes widespread 
flaccid paralysis annually and may affect up to four 
people for every 100,000 inhabitants. 
Approximately 60% to 70% of patients with GBS 
have any acute illness of one to three weeks before 
symptoms appear, the infection being the most 

common C. jejuni. This syndrome has a variant 
known as the Miller-Fisher syndrome, characterized 
by ataxia, areflexia and ophthalmoplegia (BRAZIL, 
2009). 

When C. jejuni invades the human body, the 
immune response activates the production of 
antibodies specific against to LOS. However, the 
cell membrane of human nerve cells contains 
compounds with exactly the same molecular 
structure that LOS. Thus, LOS structure mimics the 
structure of ganglioside, and antibodies produced in 
response to C. jejuni also react against nerve cell 
membrane. The result is nerve damage that occurs in 
characteristic paralysis of GBS (MURRAY, 2007). 

Another syndrome resulting from infection 
by C. jejuni is Reiter's syndrome or reactive 
arthritis. This syndrome is an autoimmune response 
that causes inflammation (arthritis) in various joints 
in response to infection by C. jejuni. It is more 
common in large weight-bearing joints such as the 
knees and lower back, but other joints may also be 
affected (MURRAY et al., 2007). 

The symptomatology presented by 
campylobacteriosis includes aqueous, moderate and 
self-limiting diarrhea, until dysentery with blood, 
mucus and white blood cells, and may be 
accompanied by headache and abdominal pain, 
fever, malaise, nausea and vomiting. 

The acute phase lasts for up to three days of 
diarrhea and abdominal pain may persist for up to 
three weeks. Recovery is rapid, usually a week. 
Antibiotic treatment is recommended only in severe 
casesnand when other underlaying clinical 
conditions exist. Rest and fluid therapy are shown to 
reverse the symptoms of this disease, which in most 
cases is self-limiting. 

Death as a result of campylobacteriosis is 
rare but can happen when there is widespread 
disease in immunocompromised individuals or in 
very young or elderly patients. Study reveals that the 
case fatality rate of infections by Campylobacter 
spp. is in the range of 0.05 cases per 1,000 
infections in humans (ALLOS, 2001). 
 
Treatment 

The antimicrobial agents of choice are 
erythromycin, clarithromycin or azithromycin, 
which are able to reduce and eliminate the 
microorganism in the feces. A clinical improvement 
is observed if treatment is started before the third 
day of the onset of symptoms (CAMPDERÁ et al., 
2007). 

Studies in children with diarrhea caused by 
C. jejuni, showed a rapid improvement using an 
early treatment with erythromycin. Clinical 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

experience and controlled studies demonstrated that 
treatment with antibiotics is prudent in patients with 
high fever, bloody stools and diarrhea with more 
than eight evacuations per day (GARCÍA; 
CRAVIOTO, 2007). 

Although no clinical efficacy trials have 
been conducted in animals, it was reported that 
erythromycin (which is the drug of choice in 
humans) in doses from 11.1 to 15.5 mg/kg, orally, 
three times daily for seven days, eliminated the 
infection in dogs and cats (HOLT, 1994). 

The resistance of Campylobacter to 
antimicrobials commonly used is a current issue that 
is under discussion both in the context of veterinary 
and human medicine. The occurrence of strains 
resistant to multiple antibiotics, including that of 
choice for treatment in humans limits the 
therapeutic options. 

According to the CDC (2013) the rates of 
antibiotic resistance in microorganisms isolated 
from humans, especially to fluoroquinolones, have 
risen sharply in the past 20 years, and these high 
rates of resistance are seen today in many regions of 
the world. For the treatment of campylobacteriosis, 
in adults, the drug of first choice are those belonging 
to the class of fluoroquinolones (CDC, 2013). When 
the resistance to this drug is proven, azithromycin 
(macrolide) is generally the next choice of 
treatment, although resistance to this class of 
antimicrobials has also already been reported (CDC, 
2013). 

Since campylobacteriosis is transmitted by 
consumption of food, the role of the indiscriminate 
use of these antibiotics in the different stages of the 
production chain of chickens can promote the 
spread of resistant strains. Various reports around 
the world associate Campylobacter sp. infections 
resistant to fluoroquinolones with the approval of 
the use of this antimicrobial in poultry production 
(SERICHANTALERGS et al., 2007). 

Rastall (2004) investigated alternative 
antibiotics sources for campylobacteriosis treatment 
and found that the use of a probiotic (Lactobacillus 
acidophilus) together with a prebiotic (fructo-
oligosaccharides, and lactosucrose) showed positive 
effects on the balance of intestinal microflora, an 
there was an improvement in recovery from 
infection and immune status. This balance of 
microflora occurs by competitive exclusion of 
pathogens after the use of probiotics (RINKINEN, 
2003). 

 
Control and Prevention 

The control of human Campylobacter sp. 
infections should begin with actions to reduce 

infection rates in animal reservoirs used for food 
production, and consequently, the danger of their 
presence in food of animal origin. During the 
slaughter, sanitary practices should be implemented 
to prevent cross-contamination, and proper 
sanitation of equipment, facilities and tools. 

At home and restaurants, enteric 
campylobacteriosis can be prevented by an 
appropriated preparation of food, particularly 
poultry preparation, avoiding consumption of 
unpasteurized dairy products and implementing 
measures to prevent contamination of water 
supplies. Moreover, one should prevent cross-
contamination during food preparation 
(GONÇALVES et al., 2012). 

Since Campylobacter spp. are sensitive to 
heat, the consumption of properly cooked poultry 
meat seems to be a good measure of control to 
prevent infection by the bacteria (ALLOS, 2001). 

The transmission of pet disease to man is a 
pathway for the spread of infection. Human cases 
are associated with diarrheic dogs and cats recently 
acquired. The veterinarian should advise the owner 
of the infected practicing appropriate hygiene 
measures as an animal: perform a thorough hand 
washing after contact with animals, promote the 
proper disposal of contaminated feces, cleaning in 
place where animals deposit their feces and separate 
infected animals babies and children until the 
cultures after treatment confirm that the infection 
has cleared (ETTINGER, 1992).  

 
CONCLUSIONS 

 
Outbreaks or human cases of 

campylobacteriosis require immediate notification 
to the authorities of local, regional or central 
surveillance, for which initiate the investigation of 
common sources and transmission control through 
preventive measures (banning contaminated 
products, among other educational measures). 

Special attention should be given to 
monitoring the contamination of chicken meat, to be 
involved in most cases of human 
campylobacteriosis. Despite the great Brazilian 
chicken meat production and the prominent position 
that the country occupies on the world stage, data on 
the Campylobacter sp. incidence in poultry in Brazil 
are still scarce, mainly due to the absence of 
national surveillance programs. 

It is important that the analysis of 
Campylobacter sp. in foods is established and 
regulated by the relevant authorities. Knowledge of 
the prevalence of these organisms in Brazil will 
allow checking the danger they pose to consumers. 



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Biosci. J., Uberlândia, v. 31, n. 5, p. 1458-1474, Sept./Oct. 2015 

Studies available to date indicate that the 
control measures to prevent human 
campylobacteriosis should be undertaken 

throughout the chain production of animal origin 
food, from  animals rearing to food preparation in 
homes. 

 
 
RESUMO: A infecção por Campylobacter spp. constitui em uma zoonose de distribuição mundial, com graves 

repercussões em saúde pública e com um impacto sócio-econômico significativo. Das espécies de Campylobacter sp., as 
que estão mais frequentemente implicadas nos surtos de doença gastrointestinal são C. jejuni e C. coli, sendo reconhecidas 
como as mais importantes e com maior potencial patogênico do ponto de vista da segurança alimentar. Esta revisão visa 
esclarecer e discutir, com base nos dados da literatura, a epidemiologia de Campylobacter sp. e os principais desafios no 
seu controle, para auxiliar no melhor entendimento do risco que representa para a saúde humana.  Devido à dificuldade de 
isolamento e cultivo de Campylobacter sp., ao alto custo da análise e da mesma não ser obrigatória, o diagnóstico 
laboratorial por meio de técnicas tradicionais de cultivo não é muito utilizado no Brasil, acarretando falta de dados 
precisos sobre a ocorrência da doença no país. Este fator tem sido identificado como responsável por subdiagnóstico e 
subnotificação da enfermidade, o que significa que dados sobre contaminação de produtos de origem animal ou surtos não 
são demonstrativos da real situação nacional. A epidemiologia das infecções por Campylobacter spp. é considerada 
complexa, apresentando múltiplos fatores determinantes na disseminação desse microrganismo. As aves são importantes 
reservatórios de Campylobacter sp. e o principal alvo de medidas de controle, porém, outros veículos de transmissão, 
como o leite cru, a água potável e outros alimentos de origem animal também precisam ser considerados no conjunto de 
medidas a serem adotadas para o controle da doença. A infecção por Campylobacter sp. causadoras de gastroenterite no 
homem acontece principalmente por via oral, mas pode ocorrer também pelo contato com animais de estimação ou de 
produção infectados. O quadro clínico da doença varia desde sintomas leves a graves, incluindo diarreia aquosa, algumas 
vezes com sangue, dor abdominal, febre, dor de cabeça e náuseas. Porém, pode haver complicações posteriores devido 
resposta auto-imune levando a paralisia progressiva que pode resultar em insuficiência respiratória e disfunção neurológica 
grave, podendo até mesmo levar a morte. A ocorrência de casos ou surtos de campilobacteriose devem ser notificados às 
autoridades de vigilância epidemiológica, para que se desencadeie a investigação das fontes comuns e o controle da 
transmissão por meio de medidas preventivas, minimizando assim os potenciais riscos para a saúde humana. 

 
PALAVRAS-CHAVE: Campylobacter spp.. Controle. Frango de Corte. Epidemiologia. Brasil 

 
 
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