A case of stiff dog syndrome associated with anti-glutamic acid decarboxylase antibodies

Pancotto, Theresa E.; Rossmeisl, John H.

doi:10.1186/s40734-017-0053-3

Cited by 9 publications

(16 citation statements)

References 16 publications

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“…ELISAs for GAD65 and IA2 autoantibodies were kindly carried out by Dr. Boris Fehse, University of Hamburg, Germany, using GAD65 and IA2 ELISA kits (both from Euroimmun, Lübeck, Germany, EA 1022–9601 G and EA 1023–9601 G, respectively) and the same serum samples were analyzed for allo-antibody levels. The GAD65 kit has previously been shown to cross-react with dog antibodies [30].…”

Section: Methodsmentioning

confidence: 99%

Interim report on the effective intraperitoneal therapy of insulin-dependent diabetes mellitus in pet dogs using “Neo-Islets,” aggregates of adipose stem and pancreatic islet cells (INAD 012-776)

Gooch¹,

Zhang²,

Hu³

et al. 2019

PLoS ONE

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We previously reported that allogeneic, intraperitoneally administered “Neo-Islets,” composed of cultured pancreatic islet cells co-aggregated with high numbers of immunoprotective and cytoprotective Adipose-derived Stem Cells, reestablished, through omental engraftment, redifferentiation and splenic and omental up-regulation of regulatory T-cells, normoglycemia in autoimmune Type-1 Diabetic Non-Obese Diabetic (NOD) mice without the use of immunosuppressive agents or encapsulation devices. Based on these observations, we are currently testing this Neo-Islet technology in an FDA guided pilot study (INAD 012–776) in insulin-dependent, spontaneously diabetic pet dogs by ultrasound-guided, intraperitoneal administration of 2x10e5 Neo-Islets/kilogram body weight to metabolically controlled (blood glucose, triglycerides, thyroid and adrenal functions) and sedated animals. We report here interim observations on the first 4 canine Neo-Islet-treated, insulin-dependent pet dogs that are now in the early to intermediate-term follow-up phase of the planned 3 year study (> 6 months post treatment). Current results from this translational study indicate that in dogs, Neo-Islets appear to engraft, redifferentiate and physiologically produce insulin, and are rejected by neither auto- nor allo-immune responses, as evidenced by (a) an absent IgG response to the allogeneic cells contained in the administered Neo-Islets, and (b) progressively improved glycemic control that achieves up to a 50% reduction in daily insulin needs paralleled by a statistically significant decrease in serum glucose concentrations. This is accomplished without the use of anti-rejection drugs or encapsulation devices. No adverse or serious adverse events related to the Neo-Islet administration have been observed to date. We conclude that this minimally invasive therapy has significant translational relevance to veterinary and clinical Type 1 diabetes mellitus by achieving complete and at this point partial glycemic control in two species, i.e., diabetic mice and dogs, respectively.

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Section: Methodsmentioning

confidence: 99%

Interim report on the effective intraperitoneal therapy of insulin-dependent diabetes mellitus in pet dogs using “Neo-Islets,” aggregates of adipose stem and pancreatic islet cells (INAD 012-776)

Gooch¹,

Zhang²,

Hu³

et al. 2019

PLoS ONE

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“…Companion animals, particularly dogs, display a broad phenotypic range of abnormal involuntary movements ( Table 2 ) ( Richter et al, 2015 ; Urkasemsin and Olby, 2014 ; Podell, 2004 ; Waln and Jankovic, 2015 ; Pancotto and Rossmeisl, 2017 ; Gilliam et al, 2014 ; Bhalerao et al, 2002 ; Quitt et al, 2018 ; Lowrie et al, 2018 ; Gill et al, 2012 ; Kolicheski et al, 2017 ; Geiger and Klopp, 2009 ; Gill et al, 2011 ). These movement disorders (MD) are classified using a scheme that parallels that of humans in which the abnormal movement is first defined as hyperkinetic or hypokinetic, followed by the frequency that the abnormal movements are observed (episodic/paroxysmal or constant/continual), and then a description of the cardinal phenotypic manifestation of the abnormal movement (dyskinesia, dystonia, myoclonus, myokymia/neuromyotonia, and myotonia) ( Richter et al, 2015 ; Urkasemsin and Olby, 2014 ; Podell, 2004 ; Waln and Jankovic, 2015 ).…”

Section: Spontaneous Neurological Diseases In Companion Animalsmentioning

confidence: 99%

“…Etiologies of MD in companion animals are equally diverse. Examples that recapitulate human conditions ( Table 2 ) include autoimmune disorders (stiff-dog-syndrome ( Pancotto and Rossmeisl, 2017 ), canine epileptoid cramping syndrome ( Lowrie et al, 2018 )), inherited glial ( KCNJ10 , spinocerebellar ataxia with myokymia, seizures, or both ( Gilliam et al, 2014 )) or sarcolemmal ( CLCN1 , myotonia congenita ( Bhalerao et al, 2002 ; Quitt et al, 2018 )) ion channelopathies, spinal cord serotonin deficiency (Scottish terrier cramp ( Geiger and Klopp, 2009 )), glycine transporter mutations (Startle disease ( Gill et al, 2011 )), and suspected neurodegenerative diseases of subcortical circuits and basal nuclei ( Garosi et al, 2005b ).…”

Section: Spontaneous Neurological Diseases In Companion Animalsmentioning

confidence: 99%

“…In dogs, the majority of gliomas appear as intra-axial tumors associated with both gray and white matter located within the telencephalon or diencephalon in close contact with the lateral ventricle. In both species, most tumors appear hypointense on T1-weighted images and hyperintense on T2-weighted images ( Pancotto and Rossmeisl, 2017 ; Gilliam et al, 2014 ). Common features include contrast-enhancement, ring-like contrast enhancement, intralesional cystic regions and hemorrhage ( Young et al, 2011 ; Rodenas et al, 2011 ; Wisner et al, 2011 ; Stadler et al, 2017 ; Bentley et al, 2013 ).…”

Section: Spontaneous Neurological Diseases In Companion Animalsmentioning

confidence: 99%

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Companion animal models of neurological disease

Partridge

Rossmeisl

2020

Journal of Neuroscience Methods

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Clinical translation of novel therapeutics that improve the survival and quality of life of patients with neurological disease remains a challenge, with many investigational drug and device candidates failing in advanced stage clinical trials. Naturally occurring inherited and acquired neurological diseases, such as epilepsy, inborn errors of metabolism, brain tumors, spinal cord injury, and stroke occur frequently in companion animals, and many of these share epidemiologic, pathophysiologic and clinical features with their human counterparts. As companion animals have a relatively abbreviated lifespan and genetic background, are immunocompetent, share their environment with human caregivers, and can be clinically managed using techniques and tools similar to those used in humans, they have tremendous potential for increasing the predictive value of preclinical drug and device studies. Here, we review comparative features of spontaneous neurological diseases in companion animals with an emphasis on neuroimaging methods and features, illustrate their historical use in translational studies, and discuss inherent limitations associated with each disease model. Integration of companion animals with naturally occurring disease into preclinical studies can complement and expand the knowledge gained from studies in other animal models, accelerate or improve the manner in which research is translated to the human clinic, and ultimately generate discoveries that will benefit the health of humans and animals.

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“…ELISAs for GAD65 and IA2 autoantibodies were kindly carried out by Dr. Boris Fehse, University of Hamburg, Germany, using GAD65 and IA2 ELISA kits (both from Euroimmun, Luebeck, Germany, EA 1022-9601 G and EA 1023-9601 G, respectively) and the same serum samples were analyzed for allo-antibody levels. The GAD65 kit has previously been shown to cross-react with dog antibodies [28].…”

Section: Enzyme Linked Immunosorbent Assays (Elisas)mentioning

confidence: 99%

First report on the effective intraperitoneal therapy of insulin-dependent Diabetes mellitus in pet dogs using “Neo-Islets,” aggregates of adipose stem and pancreatic islet cells

Gooch

Zhang

et al. 2019

Preprint

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22We previously reported that allogeneic, intraperitoneally administered "Neo-Islets," composed 23 of cultured pancreatic islet cells co-aggregated with high numbers of immunoprotective and 24 cytoprotective Adipose-derived Stem Cells, reestablished, through omental engraftment, 25 redifferentiation and splenic and omental up-regulation of Regulatory T-cells, normoglycemia in 26 autoimmune Type-1 Diabetic Non-Obese Diabetic (NOD) mice without the use of 27 immunosuppressive agents or encapsulation devices. Based on these observations, we are 28 currently testing this Neo-Islet technology in an FDA guided Pilot Study (INAD 012-776) in 29 insulin-dependent, spontaneously diabetic pet dogs by the intraperitoneal administration of 30 2x10e5 Neo-Islets/kilogram body weight to metabolically controlled (blood glucose, 31 triglycerides, thyroid and adrenal functions) animals under sedation and local anesthesia and 32 ultrasound guidance. We report here initial observations on the first 4 Neo-Islet-treated, insulin 33 dependent pet dogs that are now in the intermediate-term follow-up phase of the study (> 6 34 months post treatment). Current results indicate that in dogs, Neo-Islets appear to engraft, 35 redifferentiate and physiologically produce insulin, and are neither rejected by auto-or allo-36 immune attacks, as evidenced by (a) an absent IgG response to the allogeneic cells contained in 37 the administered Neo-Islets, and (b) progressively improved glycemic control that achieves up to 38 a 50% reduction in daily insulin needs paralleled by a significant fall in serum glucose levels. 39 This is accomplished without the use of anti-rejection drugs or encapsulation devices. No 40 adverse or serious adverse events related to the Neo-Islet administration have been observed to 41 date. We conclude that this minimally invasive therapy has significant translational relevance to 42 veterinary and clinical Type 1 Diabetes Mellitus by achieving complete and at this point partial 43 glycemic control in two species, i.e., diabetic mice and dogs, respectively. 48 by lack of insulin secretion in response to glucose, resulting in hyperglycemia, acid-base and 49 electrolyte disorders, polydipsia, polyuria and weight loss, and is accompanied by a broad 50 spectrum of diabetes-induced end organ and other complications, including blindness due to 51 retinopathy and cataracts, opportunistic infections, neurological and other serious micro-and 52 macro-vascular complications [4-6]. Although dogs were the model in which insulin was 53 originally discovered, and remain a major large animal model for the refinement of diabetic 54 treatments such as pancreas and islet cell transplants, almost no advances in the treatment for 55 diabetic dogs have been made in the last 50 years [7]. A few studies have examined xeno-or 56 allogeneic islet transplantation to reverse or ameliorate diabetes in dogs and have had varying 57 degrees of success. Yet, insulin replacement therapy and blood glucose monitoring remain the 58 only currently available ther...

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A case of stiff dog syndrome associated with anti-glutamic acid decarboxylase antibodies

Cited by 9 publications

References 16 publications

Interim report on the effective intraperitoneal therapy of insulin-dependent diabetes mellitus in pet dogs using “Neo-Islets,” aggregates of adipose stem and pancreatic islet cells (INAD 012-776)

Interim report on the effective intraperitoneal therapy of insulin-dependent diabetes mellitus in pet dogs using “Neo-Islets,” aggregates of adipose stem and pancreatic islet cells (INAD 012-776)

Companion animal models of neurological disease

First report on the effective intraperitoneal therapy of insulin-dependent Diabetes mellitus in pet dogs using “Neo-Islets,” aggregates of adipose stem and pancreatic islet cells

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