RESUMO
Health professionals in health-care organisations are frequently challenged to strategise their services, reshape patterns of care delivery and to adapt to changing environments. Relocation of services into new hospital buildings is one example of a situation that generates these challenges. In this paper the authors discuss an innovative modelling strategy that was employed to assist nurses to explore their current daily care practices, to visualise them in the context of proposed new buildings, and to work towards planning care in readiness for the new context. The modelling technique of 'plotting' is presented as a way of capturing the natural spatial-service wisdom that exists within teams, and assisting them to translate their knowledge of this to each other and to co-operatively work towards a new clinical future. Plotting will be of use to health professionals, clinical leaders and educators who are interested in spatial analysis of care and other health service practices.
Assuntos
Unidades Hospitalares/organização & administração , Modelos de Enfermagem , Papel do Profissional de Enfermagem , Recursos Humanos de Enfermagem Hospitalar/organização & administração , Local de Trabalho/organização & administração , Educação Continuada em Enfermagem/organização & administração , Previsões , Mudança das Instalações de Saúde , Humanos , Decoração de Interiores e Mobiliário , Descrição de Cargo , Avaliação das Necessidades , Recursos Humanos de Enfermagem Hospitalar/educação , Recursos Humanos de Enfermagem Hospitalar/psicologia , Técnicas de Planejamento , Aprendizagem Baseada em Problemas/organização & administração , Local de Trabalho/psicologiaRESUMO
BACKGROUND: Common chromosome 9p21 single nucleotide polymorphisms (SNPs) increase coronary heart disease risk, independent of traditional lipid risk factors. However, lipids comprise large numbers of structurally related molecules not measured in traditional risk measurements, and many have inflammatory bioactivities. Here, we applied lipidomic and genomic approaches to 3 model systems to characterize lipid metabolic changes in common Chr9p21 SNPs, which confer ≈30% elevated coronary heart disease risk associated with altered expression of ANRIL, a long ncRNA. METHODS: Untargeted and targeted lipidomics was applied to plasma from NPHSII (Northwick Park Heart Study II) homozygotes for AA or GG in rs10757274, followed by correlation and network analysis. To identify candidate genes, transcriptomic data from shRNA downregulation of ANRIL in HEK-293 cells was mined. Transcriptional data from vascular smooth muscle cells differentiated from induced pluripotent stem cells of individuals with/without Chr9p21 risk, nonrisk alleles, and corresponding knockout isogenic lines were next examined. Last, an in-silico analysis of miRNAs was conducted to identify how ANRIL might control lysoPL (lysophosphospholipid)/lysoPA (lysophosphatidic acid) genes. RESULTS: Elevated risk GG correlated with reduced lysoPLs, lysoPA, and ATX (autotaxin). Five other risk SNPs did not show this phenotype. LysoPL-lysoPA interconversion was uncoupled from ATX in GG plasma, suggesting metabolic dysregulation. Significantly altered expression of several lysoPL/lysoPA metabolizing enzymes was found in HEK cells lacking ANRIL. In the vascular smooth muscle cells data set, the presence of risk alleles associated with altered expression of several lysoPL/lysoPA enzymes. Deletion of the risk locus reversed the expression of several lysoPL/lysoPA genes to nonrisk haplotype levels. Genes that were altered across both cell data sets were DGKA, MBOAT2, PLPP1, and LPL. The in-silico analysis identified 4 ANRIL-regulated miRNAs that control lysoPL genes as miR-186-3p, miR-34a-3p, miR-122-5p, and miR-34a-5p. CONCLUSIONS: A Chr9p21 risk SNP associates with complex alterations in immune-bioactive phospholipids and their metabolism. Lipid metabolites and genomic pathways associated with coronary heart disease pathogenesis in Chr9p21 and ANRIL-associated disease are demonstrated.