ASSESSING PATIENT'S PERCEPTION OF ORAL TELECONSULTATION.

OBJECTIVES: The evaluation of telemedicine from the patient's point of view has focused on the patient pathway and patient satisfaction. However, research in this field does not provide us with the means to assess a patient's perception of the procedure if their reasoning ability is impaired. In this study, we use direct observation of a patient's behavior and mood to assess their perception of an oral teleconsultation procedure. METHODS: This study has been conducted in the context of a pilot project using an asynchronous teleconsultation to improve access to dental care for the dependent elderly, disabled people, and prisoners, some of whom may be cognitively impaired. We use a direct observation form consisting of five behavioral variables and eight affect variables to reflect the patient's experience of the oral teleconsultation procedure. RESULTS: A total of 135 patients were evaluated; 10 refused the procedure. Psychotic patients (n = 33) had a somewhat negative experience during the oral teleconsultation procedure. Patients who were not psychotic had a positive experience; this decreased as we moved from the autonomous to the semi-autonomous and then to the dependent sub-group. Some gender differences were also noted. CONCLUSIONS: Improving evidence on evaluating the acceptance of the cognitively impaired is required to improve the technology development process so that it can be translated into an improved patient experience and adherence. Although the study was specifically focused on teledentistry, the approach described in this study could be adapted to other forms of teleconsultation.

Evolution of Deep Brain Stimulation: Human Electrometer and Smart Devices Supporting the Next Generation of Therapy.

Deep Brain Stimulation (DBS) provides therapeutic benefit for several neuropathologies including Parkinson's disease (PD), epilepsy, chronic pain, and depression. Despite well established clinical efficacy, the mechanism(s) of DBS remains poorly understood. In this review we begin by summarizing the current understanding of the DBS mechanism. Using this knowledge as a framework, we then explore a specific hypothesis regarding DBS of the subthalamic nucleus (STN) for the treatment of PD. This hypothesis states that therapeutic benefit is provided, at least in part, by activation of surviving nigrostriatal dopaminergic neurons, subsequent striatal dopamine release, and resumption of striatal target cell control by dopamine. While highly controversial, we present preliminary data that are consistent with specific predications testing this hypothesis. We additionally propose that developing new technologies, e.g., human electrometer and closed-loop smart devices, for monitoring dopaminergic neurotransmission during STN DBS will further advance this treatment approach.

High frequency stimulation of the subthalamic nucleus evokes striatal dopamine release in a large animal model of human DBS neurosurgery.

Subthalamic nucleus deep brain stimulation (STN DBS) ameliorates motor symptoms of Parkinson's disease, but the precise mechanism is still unknown. Here, using a large animal (pig) model of human STN DBS neurosurgery, we utilized fast-scan cyclic voltammetry in combination with a carbon-fiber microelectrode (CFM) implanted into the striatum to monitor dopamine release evoked by electrical stimulation at a human DBS electrode (Medtronic 3389) that was stereotactically implanted into the STN using MRI and electrophysiological guidance. STN electrical stimulation elicited a stimulus time-locked increase in striatal dopamine release that was both stimulus intensity- and frequency-dependent. Intensity-dependent (1-7V) increases in evoked dopamine release exhibited a sigmoidal pattern attaining a plateau between 5 and 7V of stimulation, while frequency-dependent dopamine release exhibited a linear increase from 60 to 120Hz and attained a plateau thereafter (120-240Hz). Unlike previous rodent models of STN DBS, optimal dopamine release in the striatum of the pig was obtained with stimulation frequencies that fell well within the therapeutically effective frequency range of human DBS (120-180Hz). These results highlight the critical importance of utilizing a large animal model that more closely represents implanted DBS electrode configurations and human neuroanatomy to study neurotransmission evoked by STN DBS. Taken together, these results support a dopamine neuronal activation hypothesis suggesting that STN DBS evokes striatal dopamine release by stimulation of nigrostriatal dopaminergic neurons.