Your search keyword '"Minamikawa, Miku"' showing total 7 results

1. Environmental and host factors underlying tick-borne virus infection in wild animals: Investigation of the emerging Yezo virus in Hokkaido, Japan

Author

Ito, Mebuki, Minamikawa, Miku, Kovba, Anastasiia, Numata, Hideka, Itoh, Tetsuji, Ariizumi, Takuma, Shigeno, Asako, Katada, Yuki, Niwa, Shiho, Taya, Yurie, Shiraki, Yuto, Pandey, Gita Sadaula, Nonaka, Nariaki, Nakao, Ryo, Omori, Ryosuke, Ohari, Yuma, Isoda, Norikazu, Shimozuru, Michito, Tsubota, Toshio, Matsuno, Keita, and Sashika, Mariko

Published

2024

2. Environmental and host factors underlying tick infestation in invasive raccoons (Procyon lotor) in Hokkaido, Japan

Author

Ito, Mebuki, Minamikawa, Miku, Kovba, Anastasiia, Numata, Hideka, Itoh, Tetsuji, Katada, Yuki, Niwa, Shiho, Taya, Yurie, Shiraki, Yuto, Pandey, Gita Sadaula, Kelava, Samuel, Nonaka, Nariaki, Nakao, Ryo, Omori, Ryosuke, Ohari, Yuma, Isoda, Norikazu, Shimozuru, Michito, Tsubota, Toshio, Matsuno, Keita, and Sashika, Mariko

Published

2024

3. Epidemiological Survey of Canine Distemper Virus Infection: Exploring the Link Between Virus Spread and Invasive Raccoon (Procyon lotor) Population Growth in Hokkaido, Japan.

Author

Minamikawa, Miku, Ito, Mebuki, Kovba, Anastasiia, Kobayashi, Yumi, Abe, Go, Kooriyama, Takanori, Maeda, Ken, Shimozuru, Michito, Tsubota, Toshio, and Sashika, Mariko

Subjects

*CANINE distemper virus, *ANIMAL population density, *RACCOON, *RACCOON dog, *VIRUS diseases

Abstract

ABSTRACT Invasive raccoons (Procyon lotor) naturalized in Hokkaido, Japan, potentially spreading infectious diseases. Canine distemper virus infection is a serious epizootic disease, for which the raccoon is one of the hosts. We investigated the virus's prevalence in Hokkaido's wild raccoons, using 611 serum samples collected from captured raccoons in 2007–2012, 2021, and 2022. Higher seropositivity rates were confirmed in 2007 (32.7%), 2021 (46.4%), and 2022 (46.8%) than in 2008–2012 (0.00%–6.06%), suggesting the occurrence of an epidemic in 2007, 2021, and 2022 and its disappearance in 2008–2012. However, the infection status has recently changed, with high seropositivity rates consecutively confirmed in 2021 and 2022. Logistic regression analysis was performed to investigate the relationships among the catch per unit effort (an index of animal population density), host and environmental factors, and antibody status. The catch per unit effort correlated with seropositivity in 2007. As for environmental factors, the forest area ratio had a weak influence on seroprevalence in 2007; however, the residential area ratio had a clear influence on seroprevalence in 2021 and 2022. The epidemic occurred in forested areas in 2007; nonetheless, recent raccoon population growth and habitat expansion may have caused widespread infections even around residential areas in 2021 and 2022. Continuous monitoring of the infection and reinforcement of raccoon control programs are necessary to avoid serious damage through disease transmission to sympatric native raccoon dog (Nyctereutes procyonoides) and fox (Vulpes vulpes) populations, as well as health consequences for domestic dogs (Canis familiaris). [ABSTRACT FROM AUTHOR]

Published

2024

4. No Evidence of SARS‐CoV‐2 Infection in Urban Wildlife of Hokkaido, Japan.

Author

Kovba, Anastasiia, Nao, Naganori, Shimozuru, Michito, Sashika, Mariko, Takahata, Chihiro, Sato, Kei, Uriu, Keiya, Yamanaka, Masami, Nakanishi, Masanao, Ito, Genta, Ito, Mebuki, Minamikawa, Miku, Shimizu, Kotaro, Goka, Koichi, Onuma, Manabu, Matsuno, Keita, Tsubota, Toshio, and Al Salihi, Karima

Subjects

URBAN animals, SIKA deer, SARS-CoV-2 Delta variant, SARS-CoV-2 Omicron variant, RACCOON dog, BROWN bear

Abstract

Various domestic and wildlife species have been found susceptible to and infected with SARS‐CoV‐2, the causative agent of COVID‐19, around the globe, raising concerns about virus adaptation and transmission to new animal hosts. The virus circulation in the white‐tailed deer population in North America has further called to action for virus surveillance in the wildlife. Here, we report on the first SARS‐CoV‐2 survey of wild animals in Japan, where frequent wildlife invasions of urban areas have occurred due to the limited predation, field abandonment, the increase of human acclimatization. Genetic testing using nasal swabs and serological screening have been conducted for sika deer, brown bears, raccoons, and raccoon dogs captured in Hokkaido prefecture from the end of the Delta variant wave to the spread of the Omicron variant, between March 2022 and February 2023. No viral RNA was detected in raccoons (0/184), sika deer (0/107), and brown bears (0/14) indicating that the virus was unlikely to spread within the population of these animal species. Among 171 raccoons, 20 raccoon dogs, 100 sika deer, and 13 brown bears, one raccoon, one brown bear, and two deer tested positive in the antibodies screening with multispecies SARS‐CoV‐2 N‐protein ELISA. Still, ELISA‐positive samples tested negative in three other serological tests, emphasizing the importance of confirming serological screening results. Our results suggested that SARS‐CoV‐2 was unlikely to spillback from humans to wildlife in Hokkaido during the study period, with the emergence of new variants, continuous surveillance is of utmost importance. [ABSTRACT FROM AUTHOR]

Published

2024

5. Pesticide Contamination Levels in the Stomach Contents of Wild Raccoons (Procyon lotor) and Masked Palm Civets (Paguma larvata) in Japan

Author

Shinya, So, primary, Sashika, Mariko, additional, Minamikawa, Miku, additional, Itoh, Tetsuji, additional, Tanikawa, Tsutomu, additional, Tanaka, Kazuyuki D., additional, Nakayama, Shouta M. M., additional, Ishizuka, Mayumi, additional, and Ikenaka, Yoshinori, additional

Published

2024

6. Estimation of the Effects of Neonicotinoid Insecticides on Wild Raccoon, Procyon lotor, in Hokkaido, Japan: Urinary Concentrations and Hepatic Metabolic Capability of Neonicotinoids

Author

Shinya, So, 1000030722954, Sashika, Mariko, Minamikawa, Miku, Itoh, Tetsuji, Yohannes, Yared Beyene, 1000090647629, Nakayama, Shouta M. M., 1000050332474, Ishizuka, Mayumi, Nimako, Collins, 1000040543509, Ikenaka, Yoshinori, Shinya, So, 1000030722954, Sashika, Mariko, Minamikawa, Miku, Itoh, Tetsuji, Yohannes, Yared Beyene, 1000090647629, Nakayama, Shouta M. M., 1000050332474, Ishizuka, Mayumi, Nimako, Collins, 1000040543509, and Ikenaka, Yoshinori

Abstract

Toxicological effects of neonicotinoid insecticides (NNIs) have been reported for mammals, such as humans, rats, and mice. However, there are limited reports on their toxic effects on wild mammals. To predict NNI-induced toxic effects on wild mammals, it is necessary to determine the exposure levels and metabolic ability of these species. We considered that raccoons could be an animal model for evaluating NNI-induced toxicities on wildlife because they live near agricultural fields and eat crops treated with NNIs. The objective of the present study was to estimate the effects of NNI exposure on wild raccoons. Urinary concentrations of NNI compounds (n = 59) and cytochrome P450-dependent metabolism of NNIs (n = 3) were evaluated in wild raccoons captured in Hokkaido, Japan, in 2020. We detected either one of the six NNIs or one metabolite, including acetamiprid, imidacloprid, clothianidin, dinotefuran, thiacloprid, thiamethoxam, and desmethyl-acetamiprid in 90% of raccoons (53/59); the average cumulative concentration of the seven NNI compounds was 3.1 ng/ml. The urinary concentrations were not much different from those reported previously for humans. Furthermore, we performed an in vitro assessment of the ability of raccoons to metabolize NNIs using hepatic microsomes. The amounts of NNI metabolites were measured using liquid chromatography-electrospray ionization-tandem mass spectrometry and compared with those in rats. Raccoons showed much lower metabolic ability; the maximum velocity/Michaelis-Menten constant (V-max/K-m) values for raccoons were one-tenth to one-third of those for rats. For the first time, we show that wild raccoons could be frequently exposed to NNIs in the environment, and that the cytochrome P450-dependent metabolism of NNIs in the livers of raccoons might be low. Our results contribute to a better understanding of the effects of NNIs on raccoons, leading to better conservation efforts for wild mammals. Environ Toxicol Chem 2022;00:1-10. (c) 2

Published

2022

7. Estimation of the Effects of Neonicotinoid Insecticides on Wild Raccoon, Procyon lotor , in Hokkaido, Japan: Urinary Concentrations and Hepatic Metabolic Capability of Neonicotinoids

Author

Shinya, So, primary, Sashika, Mariko, additional, Minamikawa, Miku, additional, Itoh, Tetsuji, additional, Yohannes, Yared Beyene, additional, Nakayama, Shouta M. M., additional, Ishizuka, Mayumi, additional, Nimako, Collins, additional, and Ikenaka, Yoshinori, additional

Published

2022