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문운경 ( Oun Kyong Moon ),김순복 ( Soon Bok Kim ) 한국동물위생학회 2000 한국동물위생학회지 (KOJVS) Vol.23 No.3
Pathological findings of leucocytozoonosis naturally occurred in Korea are described. Most of the affected chickens showed paleness of comb and wattle, egg drop, approximately 20 to 30% mortality, green diarrhea, anorexia and weakness. On the blood smear merozoits and gametocytes were detected. At necropsy, petechial and ecchymotic hemorrhages in liver, kidney, heart, muscle, and splenomegaly were frequently observed. Microscopically schizonts with fine granular merozoits were often detected in kidney, intestine, brain, lung, myocardium, muscle, liver with cenrilobular fatty change, and spleen.
2014년 국내 발생 HPAI(고병원성 조류인플루엔자)의시,공간 군집 분석
문운경 ( Oun Kyong Moon ),조성범 ( Seong Beom Cho ),배선학 ( Sun Hak Bae ) 한국지리정보학회 2015 한국지리정보학회지 Vol.18 No.3
Outbreaks of highly pathogenic avian influenza(HPAI) subtype H5N8 have occurred in Korea, January 2014 and it continued more than a year until 2015. And more than 5 million heads of poultry hads been damaged in 196 farms until May 2014. So, we studied the spatial, temporal and spatio-temporal patterns of the HPAI epidemics for understanding the propagation and diffusion characteristics of the 2014 HPAI. The results are expressed using GIS. Throughout the study period three epidemic waves occurred over the time. And outbreaks made three clusters in space. First spatial cluster is adjacent areas of province of Chungcheongbuk-do, Chungcheongnam-do and Gyeonggi-do. Second is Jeonlabuk-do Gomso Bay area. And the last is Naju and Yeongam in Jeollanam-do. Also, most of spatio-temporal clusters were formed in spatially high clustered areas. Especially, in Gomso Bay area space density and spatio-temporal density were concurrent. It means that the effective prevention activity for HPAI was carried out. But there are some exceptional areas such as Chungcheongbuk-do, Chungcheongnam-do, Gyeonggi-do adjacent area. In these areas the outbreak density was high in space but the spatio-temporal cluster was not formed. It means that the HPAI virus was continuing inflow over a long period.
Epidemiology of brucellosis among cattle in Korea from 2001 to 2011
Hachung Yoon,Oun-Kyong Moon,이수한,Won-Chang Lee,Moon Her,정우석,Suk-Chan Jung,Do-Soon Kim 대한수의학회 2014 Journal of Veterinary Science Vol.15 No.4
In the present study, the outbreak patterns of bovinebrucellosis in Korea from 2000 to 2011 were analyzed tounderstand the epidemiological evolution of this disease inthe country. A total of 85,521 brucella reactor animals wereidentified during 14,215 outbreaks over the 12-year studyperiod. The number of bovine brucellosis cases increasedafter 2003 and peaked in 2006 before decreasing thereafter. The majority of the bovine brucellosis cases were Koreannative cattle, Han Woo. The numbers of human brucellosiscases and cattle outbreaks increased and decreased in thesame pattern. The correlation coefficient for human andbovine cases per year was 0.96 (95% confidence interval =0.86∼0.99; p < 10−3). The epidemiological characteristicsof bovine brucellosis appeared to be affected by the intensityof eradication programs that mainly involved a testand-slaughter policy. Findings from the present study werebased on freely available statistics from web pagesmaintained by government agencies. This unlimited accessto information demonstrates the usefulness of government statistics for continually monitoring the health of animal populations.
Original Articles : Description of national avian influenza surveillance program in Korea
( Hachung Yoon ),( Oun Kyong Moon ),( Ji Da Choi ),( Woo Seog Jeong ),( Jun Hee Han ),( Young Mi Cho ),( Young Myung Kang ),( Hyo Young Ahn ),( Do Soon Kim ),( Tim Carpenter ) 한국예방수의학회 2014 예방수의학회지 Vol.38 No.2
This study describes the national program of year-round surveillance and monitoring for avian influenza (AI). The validity of the epidemiologically-based surveillance scheme was assessed. Korea’s current surveillance program is aimed at detecting subclinical infection of either the highly pathogenic avian influenza (HPAI) virus or the low pathogenic avian influenza virus, types H5 and H7, both of which carry risk of converting to HPAI. The current AI surveillance program has demonstrated that implementing a surveillance strategy is plausible. Farmer and livestock related professional support is the critical step of specimen collection to discover hidden infection. Early detection of AI virus infection can achieve best by the combined efforts of farmers, animal health authorities, and other related industries.