Your search keyword '"Davison, Lucy J."' showing total 8 results

1. Assessment of glucocorticoid and antibiotic exposure as risk factors for diabetes mellitus in selected dog breeds attending UK primary-care clinics.

Author

Heeley, Angela M., Brodbelt, Dave C., O'Neill, Dan G., Church, David B., and Davison, Lucy J.

Subjects

GUT microbiome, GLUCOCORTICOIDS, DOG breeds, DIABETES, BEAGLE (Dog breed), RISK exposure

Published

2023

2. Antibodies against insulin measured by electrochemiluminescence predicts insulitis severity and disease onset in non-obese diabetic mice and can distinguish human type 1 diabetes status

Author

Lo Bernice, Swafford Austin DE, Shafer-Weaver Kimberly A, Jerome Lawrence F, Rakhlin Luba, Mathern Douglas R, Callahan Conor A, Jiang Ping, Davison Lucy J, Stevens Helen E, Lucas Carrie L, White Jill, von Borstel Reid, Todd John A, and Lenardo Michael J

Subjects

NOD mice, diabetes, human autoantibodies, insulin, electrochemiluminescence, IAA, IA, ECL, Medicine

Abstract

Abstract Background The detection of insulin autoantibodies (IAA) aids in the prediction of autoimmune diabetes development. However, the long-standing, gold standard 125I-insulin radiobinding assay (RBA) has low reproducibility between laboratories, long sample processing times and requires the use of newly synthesized radiolabeled insulin for each set of assays. Therefore, a rapid, non-radioactive, and reproducible assay is highly desirable. Methods We have developed electrochemiluminescence (ECL)-based assays that fulfill these criteria in the measurement of IAA and anti-insulin antibodies (IA) in non-obese diabetic (NOD) mice and in type 1 diabetic individuals, respectively. Using the murine IAA ECL assay, we examined the correlation between IAA, histopathological insulitis, and blood glucose in a cohort of female NOD mice from 4 up to 36 weeks of age. We developed a human IA ECL assay that we compared to conventional RBA and validated using samples from 34 diabetic and 59 non-diabetic individuals in three independent laboratories. Results Our ECL assays were rapid and sensitive with a broad dynamic range and low background. In the NOD mouse model, IAA levels measured by ECL were positively correlated with insulitis severity, and the values measured at 8-10 weeks of age were predictive of diabetes onset. Using human serum and plasma samples, our IA ECL assay yielded reproducible and accurate results with an average sensitivity of 84% at 95% specificity with no statistically significant difference between laboratories. Conclusions These novel, non-radioactive ECL-based assays should facilitate reliable and fast detection of antibodies to insulin and its precursors sera and plasma in a standardized manner between laboratories in both research and clinical settings. Our next step is to evaluate the human IA assay in the detection of IAA in prediabetic subjects or those at risk of type 1 diabetes and to develop similar assays for other autoantibodies that together are predictive for the diagnosis of this common disorder, in order to improve prediction and facilitate future therapeutic trials.

Published

2011

3. Comparative Pathogenesis of Autoimmune Diabetes in Humans, NOD Mice, and Canines: Has a Valuable Animal Model of Type 1 Diabetes Been Overlooked?

Author

O'Kell, Allison L., Wasserfall, Clive, Catchpole, Brian, Davison, Lucy J., Hess, Rebecka S., Kushner, Jake A., and Atkinson, Mark A.

Subjects

TYPE 1 diabetes, AUTOIMMUNE diseases, DIABETES, HYPERGLYCEMIA, INFLAMMATION, INSULIN therapy, HYPOGLYCEMIC agents, ANIMAL experimentation, AUTOANTIBODIES, BIOLOGICAL models, COMPARATIVE studies, DOGS, HISTOCOMPATIBILITY antigens, INSULIN, ISLANDS of Langerhans, RESEARCH methodology, MEDICAL cooperation, MICE, PANCREAS, RATS, RESEARCH, RESEARCH funding, HLA-B27 antigen, EVALUATION research

Abstract

Despite decades of research in humans and mouse models of disease, substantial gaps remain in our understanding of pathogenic mechanisms underlying the development of type 1 diabetes. Furthermore, translation of therapies from preclinical efforts capable of delaying or halting β-cell destruction has been limited. Hence, a pressing need exists to identify alternative animal models that reflect human disease. Canine insulin deficiency diabetes is, in some cases, considered to follow autoimmune pathogenesis, similar to NOD mice and humans, characterized by hyperglycemia requiring lifelong exogenous insulin therapy. Also similar to human type 1 diabetes, the canonical canine disorder appears to be increasing in prevalence. Whereas islet architecture in rodents is distinctly different from humans, canine pancreatic endocrine cell distribution is more similar. Differences in breed susceptibility alongside associations with MHC and other canine immune response genes parallel that of different ethnic groups within the human population, a potential benefit over NOD mice. The impact of environment on disease development also favors canine over rodent models. Herein, we consider the potential for canine diabetes to provide valuable insights for human type 1 diabetes in terms of pancreatic histopathology, impairment of β-cell function and mass, islet inflammation (i.e., insulitis), and autoantibodies specific for β-cell antigens. [ABSTRACT FROM AUTHOR]

Published

2017

4. An Allele of IKZF1 (Ikaros) Conferring Susceptibility to Childhood Acute Lymphoblastic Leukemia Protects Against Type 1 Diabetes.

Author

Swafford, Austin D.-E., Howson, Joanna M. M., Davison, Lucy J., Wallace, Chris, Smyth, Deborah J., Schuilenburg, Helen, Maisuria-Armer, Meeta, Mistry, Trupti, Lenardo, Michael J., and Todd, John A.

Subjects

LYMPHOBLASTIC leukemia in children, DIABETES, LYMPHOBLASTIC leukemia, DISEASE susceptibility, GENOMES

Abstract

OBJECTIVE--IKZF1 encoding Ikaros, an essential regulator of lymphopoiesis and immune homeostasis, has been implicated in the development of childhood acute lymphoblastic leukemia (C-ALL). Because recent genome-wide association (GWA) studies have linked a region of the 3'-UTR of IKZF1 with C-ALL susceptibility, we tested whether IKZF1 is associated with the autoimmune disease type 1 diabetes. RESEARCH DESIGN AND METHODS--rs10272724 (T>C) near IKZF1 at 7p12 was genotyped in 8,333 individuals with type 1 diabetes, 9,947 control subjects, and 3,997 families of European ancestry. Association was tested using logistic regression in the case-control data and by the transmission disequilibrium test in the families. Expression data for IKZF1 by rs10272724 genotype were obtained using quantitative PCR of mRNA/cDNA generated from peripheral blood mononuclear cells from 88 individuals, whereas expression data for five other neighboring genes were obtained from the online Genevar dataset. RESULTS--The minor allele of rs10272724 (C) was found to be protective from type 1 diabetes (odds ratio 0.87 [95% CI 0.83-0.91]; P = 1.1 x 10-11). rs10272724 was not correlated with levels of two transcripts of IKZF1 in peripheral blood mononuclear cells. CONCLUSIONS--The major susceptibility genotype for C-ALL confers protection from type 1 diabetes. Our finding strengthens the link between autoinununity and lymphoid cancers. Further investigation is warranted for the genetic effect marked by rs10272724, its impact on IKZF1, and the role of Ikaros and other family members, Ailios (IKZF3) and Eos (IKZF4), in autoimmunity. [ABSTRACT FROM AUTHOR]

Published

2011

5. Evaluation of a continuous glucose monitoring system in cats with diabetes mellitus.

Author

Ristic, Jelena M.E., Herrtage, Michael E., Walti-Lauger, Sabine M.M., Slater, Linda A., Church, David B., Davison, Lucy J., and Catchpole, Briän

Subjects

BLOOD sugar monitoring, DIABETES, GLUCOSE, INSULIN therapy, VENOUS puncture, BLOOD sugar analysis, HEALTH of cats

Abstract

A continuous glucose monitoring system (CGMS) was evaluated in 14 cats with naturally occurring diabetes mellitus. The device measures interstitial fluid glucose continuously, by means of a sensor placed in the subcutaneous tissue. All cats tolerated the device well and a trace was obtained on 15/16 occasions. There was good correlation between the CGMS values and blood glucose concentration measured using a glucometer (r =0.932, P <0.01). Limitations to the use of the CGMS are its working glucose range of 2.2–22.2mmol/l (40–400mg/dl) and the need for calibration with a blood glucose measurement at least every 12h. When compared to a traditional blood glucose curve, the CGMS is minimally invasive, reduces the number of venepunctures necessary to assess the kinetics of insulin therapy in a patient and provides a truly continuous glucose curve. [Copyright &y& Elsevier]

Published

2005

6. Anti-insulin antibodies in dogs with naturally occurring diabetes mellitus

Author

Davison, Lucy J., Ristic, Jelena M.E., Herrtage, Michael E., Ramsey, Ian K., and Catchpole, Brian

Subjects

*DIABETES, *DOGS

Abstract

The presence of anti-insulin antibodies was determined by ELISA in serum samples from 30 diabetic dogs receiving bovine insulin therapy and 30 normoglycaemic dogs. Twenty of the diabetic dogs had significant reactivity to both bovine (heterologous) and porcine (homologous) insulin compared to control dogs. In contrast there was no significant difference between the two populations in reactivity to canine distemper virus (CDV) or canine thyroglobulin. The high degree of correlation between anti-bovine insulin and anti-porcine insulin antibodies suggested cross-reactivity which was confirmed by performing a competition ELISA, with antibody binding to bovine insulin inhibited by pre-incubating serum with porcine insulin. The insulin B-chain, rather than the A-chain was the most reactive component of the insulin molecule although in some cases, diabetics with antibody reactivity to whole insulin protein showed minimal reactivity to the individual subunits. The data suggest that treatment of diabetic dogs with bovine insulin can lead to anti-insulin antibody production. These antibodies cross-react with homologous insulin and recognise conformational as well as linear epitopes. [Copyright &y& Elsevier]

Published

2003

7. Genetics of canine diabetes mellitus part 1: Phenotypes of disease.

Author

Denyer, Alice L., Catchpole, Brian, and Davison, Lucy J.

Subjects

*DIABETES, *GENETICS, *PHENOTYPES, *GENES, *NOSOLOGY

Abstract

• The multiple forms of human diabetes mellitus (DM) have different underlying causes. • Canine DM is likely to be heterogeneous, similar to human DM. • Identifying genetic risk factors is important to improve understanding of canine DM. • Greater understanding of canine DM aetiology will improve disease classification. • Increasing precise disease phenotyping will greatly benefit genetic studies. This two-part article discusses the mechanisms by which genetic variation can influence the risk of complex diseases, with a focus on canine diabetes mellitus. In Part 1, presented here, the importance of accurate methods for classifying different types of diabetes will be discussed, since this underpins the selection of cases and controls for genetic studies. Part 2 will focus on our current understanding of the genes involved in diabetes risk, and the way in which new genome sequencing technologies are poised to reveal new diabetes genes in veterinary species. [ABSTRACT FROM AUTHOR]

Published

2021

8. Genetics of canine diabetes mellitus part 2: Current understanding and future directions.

Author

Denyer, Alice L., Catchpole, Brian, and Davison, Lucy J.

Subjects

*DIABETES, *GENETICS, *NOSOLOGY, *GENETIC disorders, *GENES, *HUMAN genetics

Abstract

• Large scale genetic studies have been key in human diabetes mellitus (DM) research. • Genetic studies in canine DM have primarily used a candidate gene approach, to date. • Recent technological advances have great potential for canine DM genetic research. • The population structure of dogs is important for study of complex genetic diseases. Part 1 of this 2-part review outlined the importance of disease classification in diabetes genetic studies, as well as the ways in which genetic variants may contribute to risk of a complex disease within an individual, or within a particular group of individuals. Part 2, presented here, describes in more detail our current understanding of the genetics of canine diabetes mellitus compared to our knowledge of the human disease. Ongoing work to improve our knowledge, using new technologies, is also introduced. [ABSTRACT FROM AUTHOR]

Published

2021