Your search keyword '"Thomas L. Ellis"' showing total 2 results

1. Subsecond dopamine fluctuations in human striatum encode superposed error signals about actual and counterfactual reward

Author

Thomas L. Ellis, Mark R. Witcher, Adrian W. Laxton, Paul E. M. Phillips, P. Read Montague, Jason P. White, Stephen B. Tatter, Kenneth T. Kishida, Ignacio Saez, and Terry Lohrenz

Subjects

0301 basic medicine, Counterfactual thinking, Multidisciplinary, Addiction, media_common.quotation_subject, Striatum, ENCODE, medicine.disease, Reward processing, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, 0302 clinical medicine, chemistry, Schizophrenia, Dopamine, medicine, Psychology, Neurotransmitter, Neuroscience, 030217 neurology & neurosurgery, medicine.drug, media_common

Abstract

In the mammalian brain, dopamine is a critical neuromodulator whose actions underlie learning, decision-making, and behavioral control. Degeneration of dopamine neurons causes Parkinson's disease, whereas dysregulation of dopamine signaling is believed to contribute to psychiatric conditions such as schizophrenia, addiction, and depression. Experiments in animal models suggest the hypothesis that dopamine release in human striatum encodes reward prediction errors (RPEs) (the difference between actual and expected outcomes) during ongoing decision-making. Blood oxygen level-dependent (BOLD) imaging experiments in humans support the idea that RPEs are tracked in the striatum; however, BOLD measurements cannot be used to infer the action of any one specific neurotransmitter. We monitored dopamine levels with subsecond temporal resolution in humans (n = 17) with Parkinson's disease while they executed a sequential decision-making task. Participants placed bets and experienced monetary gains or losses. Dopamine fluctuations in the striatum fail to encode RPEs, as anticipated by a large body of work in model organisms. Instead, subsecond dopamine fluctuations encode an integration of RPEs with counterfactual prediction errors, the latter defined by how much better or worse the experienced outcome could have been. How dopamine fluctuations combine the actual and counterfactual is unknown. One possibility is that this process is the normal behavior of reward processing dopamine neurons, which previously had not been tested by experiments in animal models. Alternatively, this superposition of error terms may result from an additional yet-to-be-identified subclass of dopamine neurons.

Published

2015

2. Safety and feasibility of the NanoKnife system for irreversible electroporation ablative treatment of canine spontaneous intracranial gliomas

Author

Theresa E. Pancotto, Rafael V. Davalos, John H. Rossmeisl, Paulo A. Garcia, Natalia Henao-Guerrero, Thomas L. Ellis, Robert E. Neal, and John L. Robertson

Subjects

Male, Telencephalon, medicine.medical_specialty, Electrochemotherapy, medicine.medical_treatment, Brain tumor, Nanoknife, Neurosurgical Procedures, Dogs, Glioma, Biopsy, medicine, Animals, Dog Diseases, Prospective Studies, medicine.diagnostic_test, Brain Neoplasms, business.industry, Electroporation, Irreversible electroporation, medicine.disease, Ablation, Combined Modality Therapy, Surgery, Feasibility Studies, Female, Neurosurgery, Radiology, business

Abstract

OBJECT Irreversible electroporation (IRE) is a novel nonthermal ablation technique that has been used for the treatment of solid cancers. However, it has not been evaluated for use in brain tumors. Here, the authors report on the safety and feasibility of using the NanoKnife IRE system for the treatment of spontaneous intracranial gliomas in dogs. METHODS Client-owned dogs with a telencephalic glioma shown on MRI were eligible. Dog-specific treatment plans were generated by using MRI-based tissue segmentation, volumetric meshing, and finite element modeling. After biopsy confirmation of glioma, IRE treatment was delivered stereotactically with the NanoKnife system using pulse parameters and electrode configurations derived from therapeutic plans. The primary end point was an evaluation of safety over the 14 days immediately after treatment. Follow-up was continued for 12 months or until death with serial physical, neurological, laboratory, and MRI examinations. RESULTS Seven dogs with glioma were treated. The mean age of the dogs was 9.3 ± 1.6 years, and the mean pretreatment tumor volume was 1.9 ± 1.4 cm3. The median preoperative Karnofsky Performance Scale score was 70 (range 30–75). Severe posttreatment toxicity was observed in 2 of the 7 dogs; one developed fatal (Grade 5) aspiration pneumonia, and the other developed treatment-associated cerebral edema, which resulted in transient neurological deterioration. Results of posttreatment diagnostic imaging, tumor biopsies, and neurological examinations indicated that tumor ablation was achieved without significant direct neurotoxicity in 6 of the 7 dogs. The median 14-day post-IRE Karnofsky Performance Scale score of the 6 dogs that survived to discharge was 80 (range 60–90), and this score was improved over the pretreatment value in every case. Objective tumor responses were seen in 4 (80%) of 5 dogs with quantifiable target lesions. The median survival was 119 days (range 1 to > 940 days). CONCLUSION With the incorporation of additional therapeutic planning procedures, the NanoKnife system is a novel technology capable of controlled IRE ablation of telencephalic gliomas.

Published

2015