Neural Effects of Transcranial Direct Current Stimulation in Schizophrenia: A Case Study Using Functional Near-Infrared Spectroscopy

Taylor, S. Trevor, Chhabra, Harleen, Sreeraj, Vanteemar S., Shivakumar, Venkataram, Kalmady, Sunil V., Venkatasubramanian, Ganesan

01 September 2017

Schizophrenia is a severe neuropsychiatric disorder characterized by delusions, hallucinations, behavioral symptoms, and cognitive deficits. Roughly, 70%-80% of schizophrenia patients experience auditory verbal hallucinations (AVHs), with 25%-30% demonstrating resistance to conventional antipsychotic medications. Studies suggest a promising role for add-on transcranial direct current stimulation (tDCS) in the treatment of medication-refractory AVHs. The mechanisms through which tDCS could be therapeutic in such cases are unclear, but possibly involve neuroplastic effects. In recent years, functional near-infrared spectroscopy (fNIRS) has been used successfully to study tDCS-induced neuroplastic changes. In a double-blind, sham-controlled design, we applied fNIRS to measure task-dependent cerebral blood flow (CBF) changes as a surrogate outcome of single session tDCS-induced effects on neuroplasticity in a schizophrenia patient with persistent auditory hallucinations. The observations are discussed in this case report.

auditory signal detection

functional near-infrared spectroscopy

schizophrenia

transcranial direct current stimulation

Oxygen Uptake Kinetics in Skeletal Muscle Using Near-Infrared Spectroscopy (NIRS): Evaluating Healthy Responses of Muscle Deoxygenation

Goodwin, Ashley

January 2021

The purpose of this dissertation series was to examine oxygen uptake kinetics in skeletal muscle by evaluating responses of local muscle deoxygenation during incremental exercise in healthy individuals using near-infrared spectroscopy (NIRS). Metabolic activity in skeletal muscle, as part of the integrative responses of the cardiovascular, respiratory and neuromuscular systems, are major determinants of an individual’s physical capacity and function. The workings of these systems, called whole-body metabolism, affect the capability of an individual to engage in activities of daily living, to exercise, and participate in athletic performance. Thus, they have a strong impact on health as engagement in physical activity is well known to be effective in improving cardiorespiratory fitness and reducing the risks of chronic disease. At this time, the in vivo relationships between whole-body metabolism and local muscle metabolic activity are not well understood, but with the availability of NIRS technology this is possible. NIRS is a noninvasive optical technique used to continuously measure changes in muscle tissue oxygen saturation locally, allowing interrogation of the functional integration between muscle metabolism and the cardiovascular system in intact human beings, which is what the series of studies in this dissertation evaluate. Healthy adults and adolescents were enrolled as healthy control participants into an observational study evaluating changes in local muscle oxygen uptake in neuromuscular disease during exercise. Participants performed a maximal cardiopulmonary exercise test (CPET) on a recumbent cycle ergometer. Changes in muscle deoxygenation (HHb), reflecting local oxygen uptake, were measured using NIRS and whole-body metabolism was assessed synchronously via expired gas analysis. After an initial increase in HHb at exercise onset, a consistent pattern of plateau in HHb was observed in the healthy participants near the end of peak exercise. Despite increasing workload and oxygen uptake (VO2) in the final minutes of the test, it was unclear what mechanisms were contributing to this HHb response. It was hypothesized that the HHb-Workload relationship evaluated at the time of VO2peak would be non-linear, such that a greater maximum workload achieved at VO2peak would not be linearly matched by greater ΔHHb (i.e., greater total change from rest to VO2peak). First, a critical evaluation of the literature was conducted to explore this hypothesis. Chapter 2 provides the results of a scoping review that was performed in order to better understand the scientific evidence using NIRS that describes the relationships between indices of muscle oxygen saturation and workload during incremental exercise. This formed the basis to pursue the hypothesis-driven research presented in the subsequent chapters, interrogating the overarching question of this dissertation related to the HHb-Workload relationship. The review revealed there are three methodological approaches to examining changes in muscle oxygen saturation and workload, the least common of which was examination of HHb and workload at the VO2peak time point. Changes in muscle oxygen saturation and work have also been studied as the change in muscle oxygenation over the duration of exercise and at a certain time point or intensity during incremental exercise. Based on the literature, it was clear that there was a dearth of research examining the HHb plateau response in relation to work at VO2peak. Accordingly, chapter 3 provides the results of a pilot study that evaluated the relationship between change in HHb (ΔHHb) and the maximum workload (MW) achieved at VO2peak, where it was hypothesized that the relationship at this time point would be non-linear. A polynomial regression model was used to describe the relationship. The results of this study showed that at lower maximum workloads there were initial increases in ΔHHb with increasing maximum workload but at the highest maximum workloads, ΔHHb attenuated. A polynomial model including ΔHHb and MW, with VO2peak (an indicator of cardiorespiratory fitness) as a covariate, best characterized the relationship. Age was not significantly related to ΔHHb or MW, and VO2peak appeared to play a partial role as its inclusion as a covariate helped explain approximately a quarter of the variance, suggesting other factors may be contributing to the attenuated HHb response. From this pilot work it was hypothesized that the attenuation in ΔHHb at higher maximum workloads, and the HHb plateau observed during CPET, could be explained by muscle efficiency. If so, a longer duration and lesser slope of the HHb plateau in the minutes leading up to VO2peak occurs in muscles with higher metabolic efficiency. As muscle efficiency is defined as a ratio of external work accomplished to internal energy expended, the hypothesis, if true, would support a better matching of the internal work (VO2) to the external work (workload on the ergometer). Chapter 4 provides the results of a secondary analysis that sought to determine whether the observed plateau in HHb reflected muscular efficiency by comparing the slope of the HHb plateau (HHb[s]) to a commonly used method of assessing muscle efficiency, delta efficiency (DE). It was hypothesized that HHb[s] and DE would be inversely and significantly correlated, providing a potential mechanism for the attenuated HHb response and a noninvasive method for assessing muscle efficiency. In contrast to the hypothesis, HHb[s] and DE were not associated, suggesting that a mechanism other than muscle efficiency is contributing to the HHb plateau. Collectively, this series of studies demonstrate that there is a need to better understand the relationship between HHb and workload in healthy individuals, because of a paucity of evidence exploring the HHb-MW relationship at VO2peak, the finding that ΔHHb attenuates at higher maximum workloads, and that results suggest the HHb plateau phenomenon cannot be explained by muscle efficiency. Future work should seek to elucidate the mechanism that allows healthy individuals to achieve higher workloads (i.e., continue exercising at high intensity) without further increasing muscle oxygen uptake, in a larger more heterogeneous sample.

Kinesiology

Oxygen consumption (Physiology)

Near infrared spectroscopy

Exercise--Physiological aspects

Metabolism

Analysis Methods toward Brain-Machine Interfaces in Real Environments / 実環境BMIに向けた解析法に関する研究

Morioka, Hiroshi

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(情報学) / 甲第19126号 / 情博第572号 / 新制||情||100(附属図書館) / 32077 / 京都大学大学院情報学研究科システム科学専攻 / (主査)教授 石井 信, 教授 田中 利幸, 教授 加納 学 / 学位規則第4条第1項該当 / Doctor of Informatics / Kyoto University / DFAM

Brain-machine interface (BMI)

Non-invasive measurement

Electroencephalography (EEG)

Near-infrared spectroscopy (NIRS)

Multisubject analysis

007

Raman and near infrared spectroscopic analysis of amniotic fluid : metabolomics of maternal and fetal health indicators

Power, Kristin Marie.

January 2007

No description available.

Birth weight.

Fetus -- Growth.

Raman spectroscopy.

Near infrared spectroscopy.

Diabetes in pregnancy.

Amniotic liquid -- Analysis.

Molecular characterization of seminal plasma from boars with divergent sperm quality

Dlamini, Notsile Hleliwe

12 May 2023

Seminal plasma (SP) is the microenvironment of spermatozoa whose composition reflects semen quality and constitutes an excellent source for detecting non-invasive biomarkers. This study characterizes good vs. poor quality semen using seminal extracellular vesicles coupled proteins and miRNA. Fresh boar semen samples were screened, centrifuged, and SP supernatants were collected for near-infrared spectroscopy (NIRS) analysis. EVs were extracted from SP (SP-EVs), characterized, and those of extremely poor or good sperm quality groups were subjected to proteomics and small RNA sequencing. Significant differences were set for P

semen

semen quality

extracellular vesicles

miRNAs

near-infrared spectroscopy

pigs

Animal Sciences

Bioinformatics

Brain activity during flow : A systematic review

Andersson, Isak

January 2022

The flow state is a subjective experience that most people can relate to. It represents an optimal balance between skills and difficulty and is the state that people often refer to when performing their best, with phrases like: “I was in the zone” or “I was in the bubble”. The flow state has mainly been studied through its psychological and behavioral components; it is not until lately the neuroscientific aspects have been investigated. This review attempts to go through the existing literature and find potential neural signatures of the flow state. The studies indicate that flow is related to activity in the dorsolateral prefrontal cortex and putamen, but the findings are too divided to reach a conclusion.

Flow state

neural signatures

functional magnetic resonance imaging

functional near-infrared spectroscopy

electroencephalogram

Neurosciences

Neurovetenskaper

Oxygen Uptake Responses to Pseudo-Random Binary Sequence Cycling Protocols

Scheuermann, Britton C.

January 2021

No description available.

Kinesiology

Critical closing pressure with pulsatile diffuse optical signals

Wu, Kuan Cheng

12 June 2023

Cerebral hemodynamics monitoring is vital in the neuroscience intensive care unit to assess brain health. Diffuse optical methods using near-infrared light, e.g., near-infrared spectroscopy (NIRS) and diffuse correlation spectroscopy (DCS), allow for non-invasive prolonged monitoring of cerebral hemoglobin oxygenation and blood flow. For patients suffering from cerebral fluid or tissue volume buildup, intracranial pressure (ICP) is monitored invasively as its elevation compromises cerebral perfusion. The critical closing pressure (CrCP) is a transcranial doppler (TCD) derived non-invasive parameter that correlates with ICP; however, its use is limited due to discomfort during extended TCD measurement. I expanded on Sutin’s preliminary study using DCS to estimate CrCP and found high correlations between DCS obtained CrCP against TCD (R2: 0.77-0.83) in stroke patients. The use of DCS to monitor CrCP is advantageous because its sensors are comfortable to wear and easy to use continuously without the need of a specialized operator. However, the low DCS signal-to-noise ratio (SNR) limits the depth sensitivity and temporal resolution of CrCP measures. Following these encouraging results, I built a low-cost wireless cerebral oximeter based on multi-distance continuous wave NIRS called FlexNIRS, which exhibits high SNR (NEP < 70 fw/Hz0.5) and high sampling rate (266 Hz). This device not only quantifies cerebral oxygenation but resolves the pulsatile blood volume signal at large source-detector separations (33 mm). Using the relationship between blood flow and volume, I augmented pulsatile DCS blood flow measurements with FlexNIRS pulsatile signals. I experimentally demonstrated the high fidelity (R2: 0.98) and > 50-fold SNR improvement of the method, resulting in a one order of magnitude increase in the temporal resolution of CrCP estimates. / 2024-06-12T00:00:00Z

Biomedical engineering

Cerebral blood flow

Critical closing pressure

Diffuse correlation spectroscopy

Intracranial pressure

Near-infrared spectroscopy

Identifying the Impact of Noise on Anomaly Detection through Functional Near-Infrared Spectroscopy (fNIRS) and Eye-tracking

Gabbard, Ryan Dwight

11 August 2017

No description available.

Neurosciences

Biomedical Engineering

functional near-infrared spectroscopy

workload

prefrontal cortex

eye tracking

noise

anomaly detection

Design of a low-cost wireless NIRS system withembedded Linux and a smartphone interface

Dias, Diogo Da Silva

January 2015

No description available.

Biomedical Engineering

Computer Engineering

near-infrared spectroscopy

wireless

low-cost

embedded linux

portable

smartphone