BACKGROUND Geographical(geospatial)clusters have been observed in inflammatory bowel disease(IBD)incidence and linked to environmental determinants of disease,but pediatric spatial patterns in North America are unknow...BACKGROUND Geographical(geospatial)clusters have been observed in inflammatory bowel disease(IBD)incidence and linked to environmental determinants of disease,but pediatric spatial patterns in North America are unknown.We hypothesized that we would identify geospatial clusters in the pediatric IBD(PIBD)population of British Columbia(BC),Canada and associate incidence with ethnicity and environmental exposures.AIM To identify PIBD clusters and model how spatial patterns are associated with population ethnicity and environmental exposures.METHODS One thousand one hundred eighty-three patients were included from a BC Children’s Hospital clinical registry who met the criteria of diagnosis with IBD≤age 16.9 from 2001–2016 with a valid postal code on file.A spatial cluster detection routine was used to identify areas with similar incidence.An ecological analysis employed Poisson rate models of IBD,Crohn’s disease(CD),and ulcerative colitis(UC)cases as functions of areal population ethnicity,rurality,average family size and income,average population exposure to green space,air pollution,and vitamin-D weighted ultraviolet light from the Canadian Environmental Health Research Consortium,and pesticide applications.RESULTS Hot spots(high incidence)were identified in Metro Vancouver(IBD,CD,UC),southern Okanagan regions(IBD,CD),and Vancouver Island(CD).Cold spots(low incidence)were identified in Southeastern BC(IBD,CD,UC),Northern BC(IBD,CD),and on BC’s coast(UC).No high incidence hot spots were detected in the densest urban areas.Modeling results were represented as incidence rate ratios(IRR)with 95%CI.Novel risk factors for PIBD included fine particulate matter(PM2.5)pollution(IRR=1.294,CI=1.113-1.507,P<0.001)and agricultural application of petroleum oil to orchards and grapes(IRR=1.135,CI=1.007-1.270,P=0.033).South Asian population(IRR=1.020,CI=1.011-1.028,P<0.001)was a risk factor and Indigenous population(IRR=0.956,CI=0.941-0.971,P<0.001),family size(IRR=0.467,CI=0.268-0.816,P=0.007),and summer ultraviolet(IBD=0.9993,CI=0.9990–0.9996,P<0.001)were protective factors as previously established.Novel risk factors for CD,as for PIBD,included:PM2.5 air pollution(IRR=1.230,CI=1.056-1.435,P=0.008)and agricultural petroleum oil(IRR=1.159,CI=1.002-1.326,P=0.038).Indigenous population(IRR=0.923,CI=0.895–0.951,P<0.001),as previously established,was a protective factor.For UC,rural population(UC IRR=0.990,CI=0.983-0.996,P=0.004)was a protective factor and South Asian population(IRR=1.054,CI=1.030–1.079,P<0.001)a risk factor as previously established.CONCLUSION PIBD spatial clusters were identified and associated with known and novel environmental determinants.The identification of agricultural pesticides and PM2.5 air pollution needs further study to validate these observations.展开更多
Agricultural information cooperative services (AICS) are now becoming an important aspect of agriculture informatization. This study offers an ontological conception of the agricultural production process, establish...Agricultural information cooperative services (AICS) are now becoming an important aspect of agriculture informatization. This study offers an ontological conception of the agricultural production process, establishing operational divisions corresponding to both the stages and the fundamental information requirements of the dairy industry production process in China, yielding a process ontology for the dairy industry as well as a business chain model. A framework for a dairy industry information cooperative service system was established, with service functions realized in a prototype system. The resulting agricultural process ontology built on the basis of biological characteristics has advantages as a classification standard for agricultural information; whereas the business chain model based on this agricultural process ontology allows for an effective distribution of agricultural information cooperative services. This study outlines a concept and demonstrates a prototype of a cooperative service capable of integrating diverse online agricultural information relevant to the dairy industry in China.展开更多
基金supported as a MSc student by the University of British Columbia Graduate Support Initiative and International Tuition Awardsupported by the Moffat Foundation+7 种基金supported by the BCCH Research Institute Studentshipthe Lutsky Foundationsupport by the Canada Research Chairs Programthe Canada Foundation for Innovation.funding from Indiana Universitysupported by the Children with Intestinal and Liver Disorders (CHILD) Foundationthe BCCH Research Institute Clinician Scientists Award ProgramUniversity of British Columbia
文摘BACKGROUND Geographical(geospatial)clusters have been observed in inflammatory bowel disease(IBD)incidence and linked to environmental determinants of disease,but pediatric spatial patterns in North America are unknown.We hypothesized that we would identify geospatial clusters in the pediatric IBD(PIBD)population of British Columbia(BC),Canada and associate incidence with ethnicity and environmental exposures.AIM To identify PIBD clusters and model how spatial patterns are associated with population ethnicity and environmental exposures.METHODS One thousand one hundred eighty-three patients were included from a BC Children’s Hospital clinical registry who met the criteria of diagnosis with IBD≤age 16.9 from 2001–2016 with a valid postal code on file.A spatial cluster detection routine was used to identify areas with similar incidence.An ecological analysis employed Poisson rate models of IBD,Crohn’s disease(CD),and ulcerative colitis(UC)cases as functions of areal population ethnicity,rurality,average family size and income,average population exposure to green space,air pollution,and vitamin-D weighted ultraviolet light from the Canadian Environmental Health Research Consortium,and pesticide applications.RESULTS Hot spots(high incidence)were identified in Metro Vancouver(IBD,CD,UC),southern Okanagan regions(IBD,CD),and Vancouver Island(CD).Cold spots(low incidence)were identified in Southeastern BC(IBD,CD,UC),Northern BC(IBD,CD),and on BC’s coast(UC).No high incidence hot spots were detected in the densest urban areas.Modeling results were represented as incidence rate ratios(IRR)with 95%CI.Novel risk factors for PIBD included fine particulate matter(PM2.5)pollution(IRR=1.294,CI=1.113-1.507,P<0.001)and agricultural application of petroleum oil to orchards and grapes(IRR=1.135,CI=1.007-1.270,P=0.033).South Asian population(IRR=1.020,CI=1.011-1.028,P<0.001)was a risk factor and Indigenous population(IRR=0.956,CI=0.941-0.971,P<0.001),family size(IRR=0.467,CI=0.268-0.816,P=0.007),and summer ultraviolet(IBD=0.9993,CI=0.9990–0.9996,P<0.001)were protective factors as previously established.Novel risk factors for CD,as for PIBD,included:PM2.5 air pollution(IRR=1.230,CI=1.056-1.435,P=0.008)and agricultural petroleum oil(IRR=1.159,CI=1.002-1.326,P=0.038).Indigenous population(IRR=0.923,CI=0.895–0.951,P<0.001),as previously established,was a protective factor.For UC,rural population(UC IRR=0.990,CI=0.983-0.996,P=0.004)was a protective factor and South Asian population(IRR=1.054,CI=1.030–1.079,P<0.001)a risk factor as previously established.CONCLUSION PIBD spatial clusters were identified and associated with known and novel environmental determinants.The identification of agricultural pesticides and PM2.5 air pollution needs further study to validate these observations.
基金supported by the National High Technology R&D Program of China (863 Program,2006AA10Z239)the National Key Technologies R&D Program of China during the 11th Five-Year Plan period(2006BAD10A05)
文摘Agricultural information cooperative services (AICS) are now becoming an important aspect of agriculture informatization. This study offers an ontological conception of the agricultural production process, establishing operational divisions corresponding to both the stages and the fundamental information requirements of the dairy industry production process in China, yielding a process ontology for the dairy industry as well as a business chain model. A framework for a dairy industry information cooperative service system was established, with service functions realized in a prototype system. The resulting agricultural process ontology built on the basis of biological characteristics has advantages as a classification standard for agricultural information; whereas the business chain model based on this agricultural process ontology allows for an effective distribution of agricultural information cooperative services. This study outlines a concept and demonstrates a prototype of a cooperative service capable of integrating diverse online agricultural information relevant to the dairy industry in China.
