Anisakidae parasites in frozen fish fillets intended for human consumption

Betancourth, Patricia; Gómez, Jairo; Fernández-Silva, Jorge A.; González, Juliana; Betancourth, Patricia; Gómez, Jairo; Fernández-Silva, Jorge A.; González, Juliana

doi:10.7705/biomedica.6533

Services on Demand

Journal

Article

Indicators

Cited by SciELO
Access statistics

Biomédica

Print version ISSN 0120-4157On-line version ISSN 2590-7379

Biomed. vol.42 no.4 Bogotá Oct./Dec. 2022 Epub Dec 01, 2022

https://doi.org/10.7705/biomedica.6533

Original article

Anisakidae parasites in frozen fish fillets intended for human consumption

Parásitos anisákidos en filetes de pescado congelado destinados a consumo humano

Patricia Betancourth¹^*

Jairo Gómez²

Jorge A. Fernández-Silva¹

Juliana González¹

^¹Grupo Centauro, Escuela de Medicina Veterinaria, Facultad de Ciencias Agrarias, Universidad de Antioquia, Medellín, Colombia

^² Corporación Colombiana de Investigación, AGROSAVIA, Bogotá, D.C., Colombia

Abstract

Introduction:

Anisakiasis is a human parasitic disease caused by the consumption of raw fish or shellfish containing larvae of the Anisakidae family. It is currently considered an emerging disease of public health interest.

Objective:

To identify the presence of larvae of the Anisakidae family in samples of frozen raw fish fillets intended for human consumption in markets in Medellín and its metropolitan area in Antioquia, Colombia.

Materials and methods:

A cross-sectional study was carried out, in which larvae of the Anisakidae family were detected and identified in frozen raw fish fillets from three representative markets in Medellín and its metropolitan area. A total of 384 ready for consumption fillets were analyzed (197 sawfish, 137 salmon, 37 tuna, and 13 hake), using the pressing and ultraviolet light method. Taxonomic keys were used to identify the collected parasites and to establish its genus. Conventional PCR and Sanger sequencing was performed to determine the species.

Results:

Four larvae were found in 4 of the 384 (1.04%) fillets (CI_95% 1.04 ± 1.01%). The species of fish in which the larvae were found was sawfish (Scomberomorus spp.) and the genus and species of the larvae was established as Anisakis pegreffii.

Conclusions:

According to the study, the presence of Anisakis parasites in frozen raw fish fillets in the influence area is evident.

Keywords: Anisakiasis; parasite; zoonoses; fishes; foodborne diseases

Resumen

Introducción.

La anisakiasis es una infección producida por parásitos de la familia Anisakidae, transmitida a los humanos por el consumo de pescado o mariscos crudos. En la actualidad, se considera una enfermedad emergente de interés en salud pública.

Objetivo.

Identificar la presencia de larvas de la familia Anisakidae en muestras de filetes de pescado crudo congelado destinados a consumo humano, en mercados de Medellín y su área metropolitana en Antioquia (Colombia).

Materiales y métodos.

Se realizó un estudio transversal, en el cual se buscó la presencia de larvas de la familia Anisakidae en filetes de pescado crudo congelado de tres mercados representativos de Medellín y su área metropolitana. Se analizaron 384 filetes listos para el consumo (197 sierras, 137 salmones, 37 atunes y 13 merluzas). Cada filete fue analizado mediante el método de prensado y luz ultravioleta. Los parásitos recolectados se identificaron a partir de claves taxonómicas para establecer el género, así como PCR convencional y posterior secuenciación Sanger, para determinar la especie.

Resultados.

Se encontraron 4 larvas en 4 de los 384 filetes (1,04 %) (IC_95% 1,04 ± 1,01 %). Las larvas encontradas fueron identificadas como Anisakis pegreffi y el tipo de pescado en el cual se encontraron fue la sierra (Scomberomorus spp.)

Conclusiones.

De acuerdo con el estudio realizado, se evidencia la presencia de parásitos anisákidos en filetes de pescado crudo congelado en el área de influencia.

Palabras clave: anisakiasis; parásito; zoonosis; peces; enfermedades transmitidas por los alimentos

Anisakidosis is an emerging ichthyozoonotic parasitic disease with a worldwide distribution caused by nematodes of the Anisakidae family. This parasitosis is transmitted by the consumption of raw or undercooked fish preparations ¹^,². The main genera and species of the Anisakidae family of public health significance are Anisakis simplex, Pseudoterranova decipiens, and Contracaecum osculatum³. Due to the acute and non-specific symptoms that it produces, such as abdominal pain, vomiting or diarrhea, the disease can be classified as nonspecific given that it can be confused with other diseases ⁴. Depending on the species of Anisakidae worms, the infection may present with particular characteristics.

In the case of A. simplex, it is common to find allergic reactions that can manifest with urticaria and respiratory distress ⁵, while gastrointestinal symptoms are mainly observed if the disease is caused by P. decipiens and C. osculatum³^,⁶.

The consumption of raw fish in different preparations has been considered a cause of parasitosis in several cultures around the world. However, in countries like Colombia, where this type of consumption is not culturally common, the disease is currently increasing, probably due to the gastronomic influence of countries that include raw fish in their preparations. These changes are triggering the presence of infections by Anisakis spp. in the country ⁷^,⁸.

There is one report of anisakiasis in humans in Colombia, as notified by the Instituto Nacional de Salud in 2019 ². However, there are different research approaches that have demonstrated the presence of these parasites in this country ³. In addition, there is no epidemiological surveillance system directed to the diagnosis and control of anisakiasis ², making it difficult to find and follow the number of cases that may occur ⁹^,¹⁰. An early identification of this type of parasitosis is important, since the infection with some species of the Anisakis genus can trigger a type I hypersensitivity reaction, anaphylactic shock, and respiratory distress ¹¹.

In Colombia, in the Pacific Coast and limits with Ecuador, previous studies have reported the presence of anisakids in many of the species studied using taxonomic and molecular diagnosis, ¹²^,¹³. Due that the consumption of raw fish dishes is unavoidable, the risk of acquiring the infection increases, considering that the presence of these parasites has been reported in the country. Therefore, its circulation will depend on several factors; the most important are fish conservation at -20 °C for seven days and its preparation (cooked at 63 °C) ¹⁴. The lack of knowledge of the population about the prevention of the disease, conditions the presentation of cases in Colombia. Therefore, this study aimed to identify the presence of larvae of the Anisakidae family in samples of frozen raw fish fillets intended for human consumption in markets in Medellín and its metropolitan area in Antioquia, Colombia.

Materials and methods

Methodological design

In this cross-sectional study, 384 samples of frozen raw fish fillets were obtained from three main markets located in Medellín and its metropolitan area (Plaza Minorista José María Villa, Central Mayorista de Antioquia, Placita de Flórez). According to the Departamento Administrativo Nacional de Estadística (DANE), these places are the most visited by fish consumers and the main food suppliers in Antioquia, the collected samples are representative of this population ¹⁶.

The sample size was calculated to estimate a single proportion with an expected proportion in the population of 50% (due to unknown of the frequency of parasites of the Anisakidae worms in frozen fish in the studied area). Confidence intervals of 95% and estimated errors of 5% were also calculated ¹⁵.

The fish species included in the study were defined according to the proportion of tons landed in Antioquia, according to the Autoridad Nacional de Acuicultura y Pesca (AUNAP). In this way, sawfish (Scomberomorus spp.) represented 52% (n=197), salmon (Salmo salar) by 35% (n=137), tuna (Thunnus tuna) by 10% (n=37), and hake (Merluccius merluccius) by 3% (n=13). Subsequently, the number of collected samples for each market was also established: 61% (n=235) of the samples should be obtained from the Plaza Minorista José María Villa, 26% (n=97) from the Central Mayorista de Antioquia, and 13% (n=52) from the Placita de Flórez. The total number of frozen fillets by species and store to be sampled was obtained from the information about the species landed and the number of stores within each market. It is worth mentioning that the selection of the stores was done randomly. Once this was defined, the total number of fillets to be purchased in each market was divided in such a way that the same number of fillets was obtained for each one of them.

Samples

Fillets of approximately 200 g of each type of frozen fish were collected. No gutted fresh fish, dry fish or in any other preparation was included in the study. The fish species were chosen because they are frequently used in raw or partially sealed preparations, and for their marketing potential, according to data reported by the Sistema del Servicio Estadístico Pesquero (SEPEC) for the department in 2017.

Identification Anisakidae worms

After being purchased, the frozen raw fish fillets were transported immediately at 4 °C to the Laboratorio de Parasitología Especial of the Facultad de Ciencias Agrarias, Universidad de Antioquia in Medellín. The samples underwent a process of progressive thawing at room temperature. Subsequently, the fillets were placed in transparent 14 × 20 cm plastic bags and pressed into 1-2 mm thick layers using a hydraulic pressing device. Once the thin layer of the fillet was obtained, it was first inspected with white light and later, under a UV light source (366 nm), according to the recommended method for frozen samples ¹⁷.

Identification of Anisakidae larvae genus

Once the larvae were identified, they were extracted with dissection forceps and preserved in 70% ethanol ¹⁸ for subsequent taxonomic identification, which was carried out using thermoionic scanning electron microscopy (JEOL-JSM 6490LV, JEOL, Japan) in the laboratory of the Centro de Microscopía Avanzada in the Sede de Investigación Universitaria (SIU) of the Universidad de Antioquia, in Medellín (Colombia). The taxonomic identification was carried out considering the taxonomic keys for the genus as previously proposed ¹⁸^,¹⁹.

Identification of Anisakidae larvae species

To determine the species of the found larvae, DNA extraction was carried out using a combination of an in-house extraction method (Proteinase K and B-mercaptoethanol), and (MoBio LaboratoriesInc., CA, USA). The amount of extracted DNA was quantified using the Nanodrop 2000 Spectrophotometer^™ (Thermo Fisher Scientific, USA), obtaining concentrations between 244 ng/µl, and quality ratios of 260/280 and 260/230 of 1,8 to 2. The pair of primers 211B (5′-TTTTCTGGTTATATGGATTGATTTCA-3') and 210 (5'-CACCAACTCTTAAAATTATC-3'), expecting an amplified fragment of around 500 bp, and NC2 (5'-TTAGTTTCTTTTCCTCCGCT-3'), expecting an amplicon size of aproximately 900-1000 bp), were used to carry out the endpoint polymerase chain reaction (PCR) Amplified products were visualized in 2% agarose gels.

Sequencing

Considering the size of the expected DNA fragments, the first PCR product (amplified with the 221B/210 primers) was only sequenced in one direction and the second fragment (targeted with NC5/NC2 primers) was sequenced in both directions. To carry out the Sanger sequencing process, a purification of 5 µl of the amplified PCR products was initially cleaned up with an exonuclease 1 plus alkaline phosphatase (ExoSAP, Thermo Fisher Scientific), which allows the removal of phosphate groups from dNTPs and primers’ single strings. The cyclic sequence reaction (amplification and labeling with fluoro-labeled dNTPs) was performed using the Bigdye Terminator Cycle Sequencing kit^™ (Applied Biosystems, Thermo Fisher Scientific, Massachusetts, USA), employing the first fluor of each of the primers of the previously amplified regions as templates.

Finally, the sequence purification was carried out with the BigDye XTerminator Purification kit^™ (Applied Biosystems, Thermo Fisher Scientific, Foster City, USA). The cleaned products were run on the ABI 3500 Genetic Analyzer^™ (Applied Biosystems, Foster City, USA), through the Data Collection software 3 and visualized on the Sequencing Analysis program, version 5.4 (Applied Biosystems, Thermo Fisher Scientific, USA), which allowed the evaluation of the raw data (raw view), the quality value (assigned base probability), and the resulting electropherogram.

Exploration of associations between variables

A semi-structured interview was conducted to the fish sellers at each selected store to obtain information about the place of origin, market, as well as type of fish (table 1). The information was documented in a data capture form, and furtherly used to explore associations between the presence of Anisakis spp. and the other variables of interest (table 2).

Table 1 Analyzed variables obtained from the semi-structured interview

Variable	Description	Categories	Variable type*	Question made to fish sellers during the semi-structured interview
Place of origin	Geographic place from where the analyzed fish fillet came from according to seller information.	National (Buenaventura Bahía Solano, Santa Marta) Imported (Ecuador, Chile)	Qualitative Nominal	What is the origin of the fish you are currently selling?
Market	Place of commercialization in Medellín and the metropolitan area	Plaza Minorista José María Villa Central Mayorista de Antioquia Placita de Flórez	Qualitative Nominal	n. a.
Type of fish	Common and scientific name of fish sampled	Sierra (Sawfish) Salmon (Salmo salar) Tuna (Thunnus) Hake (Merluccus merlusus)	Qualitative	Is the fish you currently sell gutted and/or fresh?
Type of fish	Common and scientific name of fish sampled		Nominal	Is the fish you currently sell gutted and/or fresh?

* Nominal scale for all variables

n. a.: not applicable

Table 2 Distribution of Anisakis spp. in frozen raw fish fillets samples (N=384), collected in three markets in Medellin and its metropolitan area (Antioquia, Colombia).

Variable	Category	Diagnosis of anisakids		Total (%)	Association		CI_95%
Variable	Category	Pos (%)⁵	Neg (%)		X ² = 0.05	Fisher´s
Place of origin	National¹	4 (1.73)	231 (98.29)	235 (61.19)	0.107		1.73 ± 1.30
Place of origin	Imported²	0	149 (100)	149 (38.81)
Market	Plaza Minorista	4 (1.73)	230 (98.29)	234 (60.93)	0.109		1.73 ± 1.30
	José María Villa		150 (100)	150 (39.07)
	Other³	0	150 (100)	150 (39.07)
Type of fish	Sawfish	4 (2.03)	193 (97.96)	197 (51.30)	0.050	0.068	2.03 ± 1.40	Other⁴	0	187 (100)	187	(48.70)

¹Buenaventura, Bahía Solano, Santa Marta

²Ecuador, Chile

³Central Mayorista de Antioquia, Placita de Flórez

⁴Salmo salar (salmon), Thunnus tuna (tuna), Merluccus merlusus (hake).

⁵Positivity to parasites of the genus Anisakis spp., according to the visualization technique of larvae by means of the pressing method and ultraviolet light.

The purchase of the fillets was made in such a way that the seller was unaware of the purpose of the study, choosing the product for sale without any influence from the researchers.

Statistical analysis

The collected data was recorded in an Excel 2010 sheet (Microsoft, Redmond, USA). The study variables were presence of the larvae (presence, absence), place of origin (national, imported), market (Plaza Minorista José María Villa, Central Mayorista de Antioquia, Placita de Flórez), and type of fish (sawfish, salmon, tuna, hake). The results were analyzed by means of descriptive statistics, using frequency tables and percentages. Bivariate analyses were performed using the c² test to explore the association between the presence of Anisakidae larvae and the other study variables. This association was confirmed using Fisher’s exact test. In both cases, a p value <0.05 was established as statistically significant. Statistical analyses were performed using Stata 16.0^™ (StataCorp, College Station, TX, USA) ²⁰.

Ethical aspects

The present study was proposed and carried out under an expedited endorsement from the Comité Ético de Experimentación Animal (CEEA), Universidad de Antioquia (Minutes N°. 123, April 2^nd, 2019).

Results

Frequency of Anisakidae larvae and possible associations with other study variables

Four out of 384 samples analyzed contained Anisakidae larvae, with a frequency of 1.04% (CI_95%: 1.04 ± 1.01%) (table 2). Positive samples were identified in sawfish species that came from the port of Buenaventura (Colombia). No statistical association was found between the presence of Anisakis spp. and the explored variables (e.g., place of origin, market, type of fish) (table 2).

Identification of Anisakidae larvae genus

Identification was done under electron microscopy visualization, determining that the found larvae belonged to the genus Anisakis spp. (figure 1).

Figure 1 Microphotography of larvae of the genus Anisakis spp. (A) and (B) show the anterior portion of Anisakis spp. larvae. Anatomical structures are observed: presence of papillae, excretory pore, tooth, and ventral lip. (C) and (D) show the posterior portion of the larvae, with the presence of a mucron structure.

Identification of Anisakidae larvae species

Further molecular analysis confirmed the genus of the larvae as Anisakis spp. (figure 2) and A. pegreffii as the species. This could be established with the phylogenetic reconstruction of the analyzed sequences by means of maximum likelihood analysis, and collated the sequences reported in GenBank (figure 3).

Figure 2 PCR results for the detection of Anisakis spp. Seven lanes are observed were the L-lane corresponds to the molecular weight marker or ladder; the second lane is the negative control of the PCR reaction -water; the third and fourth lanes are the samples M1 and M2 for the 211B/210 primers; and the fifth lane is the negative control for NC2/NC5 PCR amplification products.

Figure 3 Phylogenetic tree of maximum likelihood comparison of Anisakis spp., based on the ITS1-5.8S-ITS2 region of rDNA.

Discussion

This study aimed to determine the presence of larvae of the Anisakidae family in frozen raw fish fillets intended for human consumption, sold in three markets in Medellín and its metropolitan area. To the authors’ knowledge, this is the first study conducted in this area using ultraviolet light as larval identification method.

Worldwide, frequencies of up to 100% of fish analyzed have been reported. Similar data have been reported in fresh fish in Buenaventura and the Colombian Pacific coast ²¹^-²³, representing an important criterion for identification and quantification of these parasites in frozen raw fish. The reported frequency of Anisakidae larvae herein seems to be relatively low (1.04%), compared to studies. This low frequency found in the present study may be due to several conditions; one of which is the analyzed type of sample (fillet).

Considering different studies, it has been established that most Anisakidae worms are found in viscera from where they migrate to muscles, depending on the time it takes for evisceration ²⁴^,²⁵. Reported ratios also differ in several studies. However, a 2:1 ratio could be found, decreasing the probability of finding larvae in muscle ²⁶. In addition to this, it has been reported that A. pegreffii larvae have a lower penetration speed into the muscle, which could explain a lower presentation of worms at muscle level ²⁷. Another reason for this frequency is the type of fish analyzed. Although the most consumed species in Medellin and its metropolitan area were analyzed, there are other reported types of fish with a higher presence of these parasites, that were not selected in the present study.

Such studies have been also carried out by a convenience sampling, which does not allow direct comparison of the data since the identification method differs greatly with respect to that used in the present study ¹²^,¹³. Furthermore, it is known that the probability of finding larvae in frozen raw fish fillets is much lower than the probability of finding larvae in viscera ²⁸, which would explain the low frequency found herein. However, this is the first study with a proportional-based design carried out on frozen fish fillets sold in different markets in Medellin and its metropolitan area. Therefore, our results demonstrate the existence of Anisakidae worms in frozen fish that are available for sale, which allows the assumption of a potential risk of parasitic transmission to humans.

No statistical association was found between the presence of Anisakis spp. and the explored variables (e.g., place of origin, market, type of fish), probably due to the relatively limited data. It is likely that a similar study using a larger sample size could show potential statistical associations. Nevertheless, the whole study reveals the significant risk of transmission to humans due to infected fish consumption, regardless of statistical association to a specific variable.

As stated before, the pressing technique followed by the ultraviolet light examination was used herein. This method has a high probability of detecting the presence of larvae in frozen fillets (sensitivity and specificity of 99%) ²⁹^,³⁰, contributing to an efficient and economical way to accurately identify nematodes, such as those of the Anisakidae family. Similar studies have used this same method, detecting four Hysterothylacium spp. larvae in the analyzed samples, determining that ice crystals related to the freezing conservation method, contribute to the release of lipofuscin, an enzyme that generates a reaction to ultraviolet light ³⁰^,³¹. This is an accurate technique to identify Anisakidae nematodes when it is necessary to evaluate large batches of frozen fish prior to be commercialized for human consumption ³². This method is one of the most effective ones from an economic point of view, compared to others such as the enzyme digestion test, which has good sensitivity and specificity, but its high costs make this technique unfeasible as a frequent diagnostic alternative in the fishing industry ²⁹^,³⁰.

It was possible to identify the presence of Anisakidae larvae, demonstrating the circulation of these nematodes in Medellin and its metropolitan area, which turns out to be relevant, since until now, there were no previous studies that reported the status of this parasitosis in the department of Antioquia. Through taxonomic analysis, it was possible to establish that the identified larvae present in the raw fish fillets belonged to the genus Anisakis spp., which are the most important species regarding parasitic human infections, due to the allergic and digestive symptoms they might trigger ³³. Hence, the species described in the present study (A. pegreffi) reflects a potential risk for raw fish consumers, who could be infected with live larvae.

These findings are similar to previous reports ¹²^,¹³ which state that the genus Anisakis spp. on the Pacific and Atlantic coasts of Colombia, as well as other genera, are of public health concern. From the epidemiological point of view, this is representative since the distribution of different fish species intended for human consumption comes from places where the finding is evident, which could represent potentially risky species for public health if they consumed raw or undercooked ³⁴.

Since A. pegreffi has been detected in fish from the Colombian and Ecuadorian Pacific coasts ¹⁴, it could be established that fish that come from the Colombian Pacific could carry this species of Anisakis in products that are intended for human consumption. Similarly, although this species does not produce allergic reactions as A. simplex, it can cause severe gastroenteric symptoms in carriers, risking their lives ⁶^-⁸. Most of the fillets that were analyzed in this study came from the port of Buenaventura, where the nematode has been reported at very high frequencies in different fish species intended for human consumption ¹⁴. In addition, fishing methods in Colombia are mainly artisanal ³⁵, which increases the possibility of selling fish infected with these worms such as Anisakis spp., since they are sold without sanitary control and visual inspection from the health and food authorities.

According to the analysis of the study variables, the presence of A. pegreffii larvae in sawfish fillets come from the port of Buenaventura, which allows it to be classified as a potentially risky species when consumed raw in different culinary preparations such as ceviche³⁶. Anisakis pegreffii and A. simplex are considered to share similar ways of causing disease in humans, a relevant situation to public health. Due to the gastrointestinal damage caused by the infection of the larvae, and the subsequent sequelae it leaves, it has been reported that these species of nematodes may be a risk factor for developing gastric cancer due to mucosal damage, and at the same time, trigger an immune reaction when in contact with the larvae antigens, though this last effect is still under study ³⁴^,³⁷.

This report agrees with what was found in Mexico, where the Pacific sawfish was found to be one of the species that is most likely to be infected with Anisakis spp. ³⁸. It should be noted that the capture method, selling, and habitat of this type of species in countries such as Mexico are like the processes carried out in Colombia, and that the presence of larvae may be subject to the time it takes to eviscerate, from capture to landing.

The results show a relatively low frequency, which cannot be considered epidemiologically significant. However, it is a starting point for further research on this nematode found in frozen fish. Additionally, only choosing four species of fish used for raw fish culinary preparations could have decreased the probability of finding a higher number of larvae, which, for future research, should be necessary to include risk groups and increase the number of fish species to be analyzed in order to better understand the behavior of the disease.

The present study is the first to report a frequency of 1.04% Anisakidae larvae compatible with the genus Anisakis and the species pegreffii in frozen raw fish fillets ready for human consumption in the department of Antioquia (Colombia). Our findings are of public health importance, revealing an important research approach in the field, oriented to expose the potential zoonotic risk and the impact that these parasitosis may have on the fishing industry and on human health. In addition, this type of study serves as an information mechanism for consumers, since they could prevent contamination from raw fish products using appropriate freezing, preservation, and cooking measures.

Acknowledgments

Authors thank the Laboratorio de Parasitología of the Facultad de Ciencias Agrarias and Grupo de Investigación Centauro (Universidad de Antioquia) for diagnostic procedures and funding, respectively.

References

1. Furuya K, Nakajima H, Sasaki Y, Urita Y. Anisakiasis: The risks of seafood consumption. Niger J Clin Pract. 2018;21:1492-4. https://doi.org/10.4103/njcp.njcp_256_17 [ Links ]

2. Patiño JA, Olivera MJ. Anisakiasis gastro-alérgica, primera descripción de un caso en Colombia y revisión bibliográfica. Biomédica. 2019;39:241-6. https://doi.org/10.7705/biomedica.v39i2.3936 [ Links ]

3. Castellanos-Garzón JA, Falla-Zúñiga LF, Salazar L, Pustovrh-Ramos MC. Anisákidos y anisakidosis: generalidades y su actualidad en Colombia. Revisión bibliográfica. IATREIA. 2020;33:143-54. https://doi.org/10.17533/udea.iatreia.47 [ Links ]

4. de Las Vecillas L, Muñoz-Cacho P, López-Hoyos M, Monttecchiani V, Martínez-Sernández V, Ubeira FM, et al. Analysis of Ani s 7 and Ani s 1 allergens as biomarkers of sensitization and allergy severity in human anisakiasis. Sci Rep. 2020;10:11275. https://doi.org/10.1038/s41598-020-67786-w [ Links ]

5. Pardo V, Manuel J. El anisakis y sus enfermedades como enfermedad profesional. Med Segur Trab (Madr). 2016;62:223-40. [ Links ]

6. Morsy K, Badr AM, Abdel-Ghaffar F, El Deeb S, Ebead S. Pathogenic potential of fresh, frozen, and thermally treated Anisakis spp. Type II (L3) (Nematoda: Anisakidae) after oral inoculation into Wistar rats: A histopathological study. J Nematol. 2017,49:427-36. https://doi.org/10.21307/jofnem-2017-092 [ Links ]

7. Aibinu IE, Smooker PM, Lopata AL. Anisakis nematodes in fish and shellfish- from infection to allergies. Int J Parasitol Parasites Wildl. 2019;9:384-93. https://doi.org/10.1016/j.ijppaw.2019.04.007 [ Links ]

8. Bao M, Pierce GJ, Pascual S, González-Muñoz M, Mattiucci S, Mladineo I, et al. Assessing the risk of an emerging zoonosis of worldwide concern: Anisakiasis. Sci Rep . 2017;7:43699. https://doi.org/10.1038/srep43699 [ Links ]

9. Amir A, Ngui R, Ismail WHW, Wong KT, Ong JSK, Lim YAL, et al. Anisakiasis causing acute dysentery in Malaysia. Am J Trop Med Hyg. 2016;95:410-2. https://doi.org/10.4269/ajtmh.16-0007 [ Links ]

10. Chung Y-B, Lee J. Clinical characteristics of gastroallergic anisakiasis and diagnostic implications of immunologic tests. Allergy Asthma Immunol Res. 2014;6:228-33. https://doi.org/10.4168/aair.2014.6.3.228 [ Links ]

11. Restrepo-Betancurt LF, Rodríguez-Espinosa H, Valencia-Y D. Caracterización del consumo de pescado y mariscos en población universitaria de la ciudad de Medellín - Colombia. Universidad y Salud. 2016;18:257. https://doi.org/10.22267/rus.161802.36 [ Links ]

12. Olivero-Verbel J, Baldiris-Ávila R, Güette-Fernández J, Benavides-Álvarez A, Mercado-Camargo J, Arroyo-Salgado B. Contracaecum sp. infection in Hoplias malabaricus (moncholo) from rivers and marshes of Colombia. Vet Parasitol. 2006;140:90-7. https://doi.org/10.1016/j.vetpar.2006.03.014 [ Links ]

13. Castellanos JA, Santana-Piñeros AM, Mercado R, Peña S, Pustovrh C, Cruz-Quintana Y. Presence of anisakid larvae in commercial fishes landed in the Pacific coast of Ecuador and Colombia. Infectio. 2018;22:206. https://doi.org/10.22354/in.v22i4.739 [ Links ]

14. CDC-Centers for Disease Control, Prevention. CDC - anisakiasis - frequently asked questions (FAQs). 2010. Accessed: July 16, 2022. Available at: Available at: https://www.cdc.gov/parasites/anisakiasis/faqs.html [ Links ]

15. García-García JA, Reding-Bernal A, López-Alvarenga JC. Cálculo del tamaño de la muestra en investigación en educación médica. Investig Educ Médica. 2013;2:217-24. [ Links ]

16. Departamento Administrativo Nacional de Estadística. Sistema de información de precios (SIPSA). Accessed: July 16, 2022. Available at: Available at: https://www.dane.gov.co/index.php/estadisticas-por-tema/agropecuario/sistema-de-informacion-de-precios-sipsa [ Links ]

17. Karl H, Leineman M. A fast and quantitative detection method for nematodes in fish fillets and fishery products. Archiv für Lebensmittelhygiene. 1993;44:124-5. https://doi.org/10.1016/j.fawpar.2016.07.003 [ Links ]

18. Keim A. Manual de métodos parasitológicos e histopatológicos en piscicultura. 1982. Accessed: July 16, 2022. Available at: Available at: https://aquadocs.org/handle/1834/4913 [ Links ]

19. Ishii Y, Fujino T, Weerasooriya MV. Morphology of anisakine larvae. En: Gastric Anisakiasis in Japan. Tokyo: Springer Japan; 1989. p.19-29. [ Links ]

20. StataCorp. Stata Statistical Software: Release 16. College Station, TX: StataCorp LLC. (2019). Accessed: July 16, 2022. Available at: Available at: https://www.stata.com/support/faqs/resources/citing-software-documentation-faqs/ [ Links ]

21. Sonko P, Chih-Cheng Chen S, Chou C-M, Huang Y-C, Hsu S-L, Barčák D, et al. Multidisciplinary approach in study of the zoonotic Anisakis larval infection in the blue mackerel(Scomber australasicus) and the largehead hairtail (Trichiurus lepturus) in Northern Taiwan. J Microbiol Immunol Infect. 2020;53:1021-9. https://doi.org/10.1016/j.jmii.2019.04.012 [ Links ]

22. Torres-Frenzel P, Torres P. Anisakid parasites in commercial hake ceviche in southern Chile. J Food Prot. 2014;77:1237-40. http://doi.org/10.4315/0362-028X.JFP-13-538 [ Links ]

23. Guardone L, Nucera D, Lodola LB, Tinacci L, Acutis PL, Guidi A, et al. Anisakis spp. Larvae in different kinds of ready to eat products made of anchovies (Engraulis encrasicolus) sold in Italian supermarkets. Int J Food Microbiol. 2018;268:10-8. https://doi.org/10.1016/j.ijfoodmicro.2017.12.030 [ Links ]

24. Klapper R, Kuhn T, Münster J, Levsen A, Karl H, Klimpel S. Anisakid nematodes in beaked redfish (Sebastes mentella) from three fishing grounds in the North Atlantic, with special notes on distribution in the fish musculature. Vet Parasitol. 2015;207:72-80. https://doi.org/10.1016/j.vetpar.2014.11.017 [ Links ]

25. Guardone L, Nucera D, Pergola V, Costanzo F, Costa E, Tinacci L, et al. Visceral larvae as a predictive index of the overall level of fish batch infection in European anchovies (Engraulis encrasicolus): A rapid procedure for food business operators to assess marketability. Int J Food Microbiol. 2017;250:12-8. https://doi.org/10.1016/j.ijfoodmicro.2017.03.011 [ Links ]

26. Mercken E, van Damme I, Vangeenberghe S, Serradell A, De Sterck T, Lumain JPL, et al. Ascaridoids in commercial fish: Occurrence, intensity and localization in whole fish and fillets destined for the Belgian market. Int J Food Microbiol. 2020;327:108657. https://doi.org/10.1016/j.ijfoodmicro.2020.108657 [ Links ]

27. Suzuki J, Murata R, Hosaka M, Araki J. Risk factors for human Anisakis infection and association between the geographic origins of Scomber japonicus and anisakid nematodes. Int J Food Microbiol. 2010;137:88-93. https://doi.org/10.1016/j.ijfoodmicro.2009.10.001 [ Links ]

28. Colombo F, Cattaneo P, Castelletti M, Bernardi C. Prevalence and mean intensity of Anisakidae parasite in seafood caught in the Mediterranean Sea focusing on fish species at risk of being raw-consumed. A metaanalysis and systematic review. Crit Rev Food Sci Nutr. 2016;56:1405-16. https://doi.org/10.1080/10408398.2012.755947 [ Links ]

29. Wang X, Jia H, Gong H, Zhang Y, Mi R, Zhang Y, et al. Expression and functionality of allergenic genes regulated by simulated gastric juice in Anisakis pegreffii. Parasitol Int. 2021;80:102223. https://doi.org/10.1016/j.parint.2020.102223 [ Links ]

30. Gómez-Morales MA, Castro CM, Lalle M, Fernández R, Pezzotti P, Abollo E, et al. UV-press method versus artificial digestion method to detect Anisakidae L3 in fish fillets: Comparative study and suitability for the industry. Fish Res. 2018;202:22-8. https://doi.org/10.1016/j.fishres.2016.12.011 [ Links ]

31. Levsen A, Maage A. Absence of parasitic nematodes in farmed, harvest quality Atlantic salmon (Salmo salar) in Norway - Results from a large scale survey. Food Control. 2016;68:25-9. https://doi.org/10.1016/j.foodcont.2016.03.020 [ Links ]

32. Cipriani P, Giulietti L, Palomba M, Mattiucci S, Bao M, Levsen A. Occurrence of larval ascaridoid nematodes in the Argentinean short-finned squid Illex argentinus from the Southwest Atlantic Ocean (off Falkland Islands). Int J Food Microbiol. 2019;297:27-31. https://doi.org/10.1016/j.ijfoodmicro.2019.02.019 [ Links ]

33. Villafruela-Cives M, Henríquez-Santana A. Anisakiasis. Rev Esp Enferm Dig. 2010;102:216. [ Links ]

34. Mattiucci S, Cipriani P, Levsen A, Paoletti M, Nascetti G. Molecular epidemiology of Anisakis and anisakiasis: An ecological and evolutionary road map. Adv Parasitol. 2018;99:93-263. https://doi.org/10.1016/bs.apar.2017.12.001 [ Links ]

35. Moreno LT. La pesca de los pescadores artesanales en Colombia. PEGADA - A Revista da Geografia do Trabalho. 2018;19. https://doi.org/10.33026/peg.v19i2.5514 [ Links ]

36. Lucano-Ramírez G, Ruiz-Ramírez S, Palomera-Sánchez FI, González-Sansón G. Biología reproductiva de la sierra Scomberomorus sierra (Pisces, Scombridae) en el Pacífico central mexicano. Cienc Mar. 2011;37:249-60. [ Links ]

37. Abattouy N, López AV, Maldonado JL, Benajiba MH, Martín-Sánchez J. Epidemiology and molecular identification of Anisakis pegreffii (Nematoda: Anisakidae) in the horse mackerel Trachurus trachurus from northern Morocco. J Helminthol. 2014;88:257-63. https://doi.org/10.1017/S0022149X13000102 [ Links ]

38. Lerena MSM, Torres EP, Ramírez MÁP, Orozco JAH, Estrada GE, Esparza CD. Presencia de parásitos en pescado en el mercado local de la Zona Metropolitana de Guadalajara. e-CUCBA. 2018:21-6. [ Links ]

Citation: Betancourt P, Gómez J, Fernández-Silva JA, González J. Anisakidae parasites in frozen fish fillets intended for human consumption. Biomédica. 2022;42:591-601. https://doi.org/10.7705/biomedica.6533

Author contributions:

Patricia Betancourth: Study conception and methodological design, collection of samples and data, and writing of the manuscript

Juliana González: Methodological design and writing of the manuscript

Jorge Arturo Fernández: Methodological advisory and writing of the manuscript

Jairo Enrique Gómez: Methodological advisory

Funding:

The project was financed by the Grupo de Investigación Centauro of the Escuela de Medicina Veterinaria of the Facultad de Ciencias Agrícolas at the Universidad de Antioquia.

Received: March 16, 2022; Accepted: August 27, 2022; Published: August 29, 2022

^*Corresponding author: Patricia Betancourth, Grupo Centauro, Facultad de Ciencias Agrarias, Universidad de Antioquia, Medellín, Colombia Telephone: (+57) (315) 534-0515 patricia.betancourth@udea.edu.co

All authors participated in data analysis, writing, and approval of the final version of the manuscript.

^{Conflicts of interest:}

The authors declare that they have no conflict of interest for the publication of this article.

This is an open-access article distributed under the terms of the Creative Commons Attribution License