INTRODUCTION
The third stage larvae (L3) of Anisakis simplex are prevalent in marine fish and cephalopods, and the most important etiologic agent of anisakidosis in humans. The marine fish and cephalopods act as a paratenic or transport host of A. simplex, so that the consumption of raw or insufficiently processed fish and cephalopods can cause anisakidosis.
The prevalence of
A. simplex larvae in fish and cephalopods has been known to be over 80%, although it varies upon fish species and location. Abollo et al. [
1] reported 100% prevalence in 5 species of fish, such as
Prionace glauca,
Belone belone,
Merluccius merluccius,
Lophius piscatorius, and
Scorpaena scrofa, although the overall mean intensity and abundance of
A. simplex L3 varied considerably among the investigated species. Costa et al. [
2] also found that the prevalence of L3 in
Aphanopus carbo,
Scomber japonicas, and
Trachurus picturatus ranged from 97.2% to 62.5% in Madeira, Portugal. The infection rate of
A. simplex in the fish and squids purchased in Bayuquan (Bohai Sea, China) was 63.4% and 14.8%, respectively [
3]. The infection rates of 8 of 19 fish species, however, were higher than 80% [
3]. After Chun et al. [
4] reported that anisakid infection was higher in fish from the southern sea than in those from the eastern sea, there were a few surveys on the prevalence of
A. simplex larvae in marine fish and cephalopods in Korea. Chai et al. [
5] collected an average of 35.6 anisakid larvae per yellow corvina (
Pseudosciaena manchurica), and almost all of them were found infected with
Anisakis type I (=
A. simplex) larvae. See eels (
Astroconger myriaster) and anchovies (
Engraulis japonicus) also showed 58.0% and 6.9% infection rates, respectively [
6-
8].
High prevalence of
A. simplex larvae in fish and cephalopods was realized by frequent occurrence of zoonotic problems due to these larvae [
9-
13]. Im et al. [
10] reported that 107 cases were diagnosed by gastrofiberscopy for 3 years in a local clinic at Cheju-do, Korea. They also demonstrated that important fish species from which the patients became infected were yellow corvina, sea eel, ling, cuttle fish, yellowtail, and others. It has also been reported that ingested larvae can cause allergic responses along with intestinal symptoms [
14,
15]. Moreover, the presence of anisakid larvae is not only applied as biological tags for marine fish, mammals, and invertebrate population studies, but also related to commercially important fish marketing because of the parasite removing costs [
1,
16].
Because of health consciousness, meat consumption in Korea drops remarkably while fish consumption is increasing year by year. This trend will bring about a rise of infectious diseases and is a tribute to parasite infection through marine fish consumption, especially A. simplex larvae. The infection status with A. simplex L3 will be a timely study subject to provide useful information for fish consumers under these circumstances.
The aim of the present work was to determine A. simplex larval infection status, including the infection rate, abundance, intensity, and seasonal variation according to the fish and cephalopod species and their size.
MATERIALS AND METHODS
Refrigerated fish and cephalopods were purchased on a monthly basis at Busan Cooperative Fish Market from August 2006 to July 2007. A total of 2,537 specimens, representing 40 species of fish and 3 species of cephalopods, were examined. The classification of fish and cephalopods was referred to web sites
http://portal.nfrdi.re.kr (National Fisheries Research & Development Institute, Korea) and
http://www.kunsan.ac.kr/fishes (College of Ocean Science and Technology, Kunsan University, Korea). The number of fish and cephalopods investigated in each month was represented in
Table 1.
Each sample of fish was weighed and measured. The whole body cavity and the viscera of each sample were carefully dissected and thoroughly examined for anisakids. Most larvae were examined directly under a light microscope, but some of anisakids were fixed in 70% ethanol and cleared in glycerin for identification of the species.
A. simplex L3 were identified based on the following morphological characters: (1) the shape and the presence of the boring tooth, (2) the shape of the tail and the presence of the mucron, and (3) the shape of the ventriculus [
5,
17]. The infection rate (IR=no. of fish positive/no. of fish examined ×100), abundance (A=total no. of larvae detected/no. of fish examined), and intensity of infection (I=total no. of larvae detected/no. of fish infected) were calculated according to Bush et al. [
18]. To study the correlation between size and infection intensity, we examined 4 specimens in each group of
S. japonicus and
G. macrocephalus, except for 3 specimens of 49-51 cm size group of
G. macrocephalus. We also analyzed seasonal variation of
A. simplex infection among 16 fish hosts secured more than 12 specimens per season. The studied species of fish and cephalopods were summarized in
Table 1. The Student's t-test was employed to determine the statistical significance.
DISCUSSION
We investigated the occurrence and infection dynamics of A. simplex L3 in 40 species of fish and 3 species of cephalopods. A total of 2,537 fish and cephalopods were purchased from the Busan Cooperative Fish Market. Busan Cooperative Fish market is a suitable place for investigation of marine fish infection since the market is the biggest in fish sales scale in Korea and sales over 3,200 ton fishes a day on commission.
The overall infection rate of
A. simplex L3 in marine fish and cephalopods was 34.3% and the mean infection intensity 17.1 larvae per fish. The infection rate, however, varied greatly depending on the species of fish, ranging from 0% to100%. This result was considered to mean that some species of fish show higher affinity to
A. simplex than others. Fish showing high infection rate exhibit features of flabby flesh and high fat contents. Frog fish (
Lophiomus setigerus) showed the highest infection rate as 100%. They have a very large head with a large mouth that catch a lot of fish at a time. The voracious appetite of the frog fish can be a reason of the high infection rate with
A. simplex larvae. Abollo et al. [
1] also reported 100% infection rate in
Lophius piscatorius in Galician waters, which is similar species to
L. setigerus. Fish species which show especially high infection level were Korean favorite fish, such as
T. lepturus,
S. niphonius,
G. macrocephalus,
Theragra chalcogramma,
P. azonus, and
S. japonicus. These fishes are almost served at table daily. Although the main habitat of the larva is the viscera, health risk is still present due to postmortem migration of larvae and salted fish viscera eating habit of Korean people.
Six fish species, such as P. crocea, C. semilaevis, K. punctatus, O. fasciatus, C. notate, and L. bleekeri, were not infected with A. simplex larvae. S. pachycephalus, E. burgeri, H. sajori, and L. tanakai fish also showed very low infection rates. These fish had several features in common, like a small size, hard flesh, and narrow cavity.
Drawing special attention is the infection status of the sea eel (
Astroconger myriaster), which was suspected as one of the most important fish host for human anisakidosis in Korea [
6,
19]. The present study showed that the infection rate and intensity of the sea eel was 76.5% and 16.2, respectively. These data suggest that the sea eel still could be an important fish host of anisakidosis in Korea. The infection rates of other Korean favorite raw fish species, such as
Sebastes inermis,
Engraulis japonicas, and
Pampus argenteus were also considerably high (42.5-75.6%). Another favorite raw fish,
Mugil cephalus, however, showed a comparatively low rate (8.9%).
Konosirus punctatus was infected with different species of nematodes except for
A. simplex. We also examined 3 species of cephalopods, including
Todarodes pacificus,
Sepia esculenta, and
L. bleekeri.
T. pacificus showed the highest infection rate, which is eaten raw most frequently.
Chun et al. [
4] investigated the infection rate of
Anisakis-like larvae from 17 species of marine fish from the Yellow Sea and the southern coast of Korea. All of the 313 examined samples were infected with
Anisakis-like larvae. Both prevalence and intensity of the Chun's report were low in
Trachurus japonicus,
Pseudostiaena manchurica,
Trichiurus lepturus and
Liparis tanakai compared to the present study. These differences seem to be caused by the size of fish examined. Our subject fish of
S. japonicus was bigger than those of Chun's (31-43 cm to 24-40 cm). The positive correlation between size and infection level was also found in
G. macrocephalus. There was no difference of infection rate in fish which do not show significant difference in length even after they are grown-up.
Ma et al. [
3] reported the infection status of
A. simplex larvae in marine fish and cephalopods from the Bohai Sea, China. When compared to the present study, infection rate and density of
Scomberomorus niphonius,
Sepia esculenta, and
Cynoglossus semilaevis was similar among each other. But the infection rate of
Lateolabrax japonicus was greatly different although the infection density was high in both reports. These differences can be attributed to many factors, such as collecting sites, fish size or numbers and detecting methods.
To investigate the seasonal variation of larval infection, we examined the 15 species of fish and 1species of cephalopods for a year by month. Ten species of fish showed abundance peak in February or April. But there was no tendency of seasonal variation in other species of fish. Abundance of some hosts was high all the year round, while the others showed very low infection rates throughout the year. Strømnes and Andersen [
20] used the term "spring rise" to describe the significant increase in the abundance of
A. simplex L3 during the springtime of March and April. Seasonal variations in infection levels are considered due to changes in the population of the infected euphausiids in the zooplankton according to increase of water temperature [
21]. Besides, additional supply of eggs and larvae in the study area due to seasonal migration of whales and migration of fish should have deliberated [
20]. The distinct abundance peak of
A. simplex L3 in April and February can be attributed the same factors. But it is not feasible to explain the seasonality of
A. simplex larval infection without considering other important factors such as physicochemical conditions, reproductive circumstances, social conditions, coactive circumstances or combination of these factors in aquatic environments, as Stavn [
22] pointed out.
Our results show that the infection rates of A. simplex L3 were still high in Korean favorite fish, including such raw fish species as sea eel. The current data also reveal information regarding A. simplex L3 infection of some fish in Korean waters, which have never been reported previously. The positive correlation between the host size and infection intensity was obvious in S. japonicus and G. macrocephalus. Some host species exhibited a seasonal pattern of abundance at February and April.
Our results clarified that eating of fish could still be the source of infection with A. simplex L3 of humans in Korea. A. simplex L3 are more likely to be infected during spring time in some species of fish. These results could be significant findings because these fish species are most widely served side dishes of Korean as well as high commercial value. These data of A. simplex L3 larva infection in marine fish and cephalopods will provide information for prevention of anisakidosis and regulation of marine fish distribution process and sales.