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Modeling wellbore pressure with application to multi-stage, acid-stimulation treatmentEjofodomi, Efejera A. 16 August 2006 (has links)
Estimation of bottomhole pressure during a matrix-acidizing treatment provides
the information needed to accurately determine the evolution of skin factor during and
after the treatment. It could be a very complicated process, especially when compressible
fluids, such as foams, are involved. Existing models for estimating bottomhole pressure
during a matrix-acidizing treatment ignore the volume reduction of compressible fluids
and its effect on the bottomhole pressure.
This research developed a model that uses a unique solution to the mechanical
energy balance equation, to calculate the bottomhole pressure from known surface
measurements during foamed acid stimulation. The model was used to evaluate two
stimulation treatments. Field examples are presented which illustrate the application of
the model to optimize stimulation treatments.
Properly accounting for the flow behavior and tracking the injected volume of
the foam diverter used during the treatment resulted in more reliable and accurate
bottomhole pressure profile.
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Selection of fracture fluid for stimulating tight gas reservoirsMalpani, Rajgopal Vijaykumar 25 April 2007 (has links)
Essentially all producing wells drilled in tight gas sands and shales are stimulated using
hydraulic fracture treatments. The development of optimal fracturing procedures,
therefore, has a large impact on the long-term economic viability of the wells. The
industry has been working on stimulation technology for more than 50 years, yet
practices that are currently used may not always be optimum. Using information from the
petroleum engineering literature, numerical and analytical simulators, surveys from
fracturing experts, and statistical analysis of production data, this research provides
guidelines for selection of the appropriate stimulation treatment fluid in most gas shale
and tight gas reservoirs. This study takes into account various parameters such as the type
of formation, the presence of natural fractures, reservoir properties, economics, and the
experience of experts we have surveyed. This work provides a guide to operators
concerning the selection of an appropriate type of fracture fluid for a specific set of
conditions for a tight gas reservoir.
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Sensory gating in schizophrenia /Light, Gregory Arden, January 2001 (has links)
Thesis (Ph. D.)--University of California, San Diego and San Diego State University, 2001. / Vita. Includes bibliographical references.
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Effects of low current electrical stimulation of neck muscles on voicingLai, Sin-yi., 賴善怡. January 2010 (has links)
published_or_final_version / Speech and Hearing Sciences / Master / Master of Philosophy
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TAC-TIC : a non-pharmacological approach to the alleviation of neonatal painHayes, Julie Anne January 1996 (has links)
Intensive care IS a stressful environment and this thesis addresses the controversy as to whether tactile stimulation can mitigate the negative influences in ventilated preterms. There is an underlying assumption throughout the thesis that the pre term infant in intensive care experiences and is able to manifest physical and/or psychological pain. Preterms (n=75) were recruited with parental consent against strict entry criteria. A pre-test, post-test time series, counterbalanced design was used to evaluate the impact of an intervention to alleviate pain. The intervention [Touching and Caressing, Tender in Caring (T AC-TIC)] was compared with a control condition (spontaneous activity). Indicators of pain represented in the experiments were immunologic, physiological, and neurobehavioural. Data were analysed using parametric and non-parametric tests. The ontogeny of the secretory Immune system was investigated (n=70) using an enzyme-linked immunosorbant assay for Secretory Immunoglobulin A (SIgA). Ventilated preterms had significantly lower SIgA than infants requiring no mechanical ventilation. Breast milk fed preterms showed increased SIgA compared to other modes of nutrition. TACTIC increased SIgA in a subsample of ventilated preterms (n=35) with no changes following the control condition. Cardiovascular responses remained stable throughout T AC-TIC and spontaneous activity. No changes in gastric pH were observed in a sub-sample of 18 preterms. A neurobehavioural checklist was used to analyse videos for pain and comfort behaviours (n=29). Significantly more comfort behaviours were reported during T AC-TIC. Analysis of behavioural state indicated that more time was spent inactive sleep during than after TAC-TIC. No differences In state occurred between TAC-TIC and control condition. A ventilated subsample (n=25) of the original cohort was subjected to analysis at individual level for determination of congruence between simultaneously measured outcome variables. T AC-TIC produced increases more often in two or three variables. Pilot work has also been conducted addressing further controversies in tactile stimulation. The results are discussed within the theoretical frameworks of Gottlieb's hierarchical systems model, and Adamson-Macedo's Equilibrium model
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EFFECTS OF REDUCED DEEP BRAIN STIMULATION FREQUENCIES IN PARKINSON’S DISEASEAkhtar, Shaan 04 1900 (has links)
A Thesis submitted to The University of Arizona College of Medicine - Phoenix in partial fulfillment of the requirements for the Degree of Doctor of Medicine. / Deep brain stimulation (DBS) of the subthalamic nucleus (STN) is widely used and proven to be highly effective in helping alleviate symptoms of Parkinson’s disease (PD). Nevertheless, although high‐frequency DBS (>120 Hz) is initially effective in improving patients’ motor symptoms (mainly bradykinesia and tremors), many patients still develop gait disturbances, such as freezing of gait (FOG). Recent studies have reported that stimulation of the STN with low frequencies produce positive effects on gait disorders and reduces the number of FOG events. As research is being done to investigate how reduced DBS frequencies will affect gait and balance control, it is also important to understand what effects reduced DBS stimulation will have on their PD symptoms. The aim of this study was to investigate the effects that reduced DBS frequencies have on the severity of PD patients’ symptoms. The effects were studied in twelve PD patients (receiving DBS treatment) after reducing their DBS frequency.
The varied DBS frequencies included: their clinically determined stimulation setting (CDS), a low stimulation setting (30 Hz), and an intermediate stimulation frequency (80 Hz). Symptom severity was measured using the Unified Parkinson’s Disease Rating Scale (UPDRS‐III), and the Hoehn‐Yahr (HY) stage score. The results were supportive of what we expected; that as DBS frequencies are decreased from the patients’ clinically determined setting, the clinical symptoms worsened. This is an important observation which will allow the appropriate clinical decisions be made as we continue to investigate the effects of reduced frequency DBS on gait and posture control.
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Effects of brief, intense transcutaneous electrical stimulation on chronic painJeans, Mary Ellen January 1976 (has links)
No description available.
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Determination of the most effective stimulation parameters for functional electrical stimulationEvans, Nancy C. 08 1900 (has links)
No description available.
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Retinal responses to white-noise modulated current stimuliAbdel-Fattah, Ahmed Bahgat Fattouh 08 1900 (has links)
No description available.
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Measuring magnetically induced eddy current densities in biological structures at low frequencies : circuit design and applicationsAbdulkariem, Heibetullah January 1991 (has links)
Electrical eddy currents can be induced inside biological tissue by time-varying magnetic fields according to Faraday's law of induction. These eddy currents are responsible for biological effects such as visual sensations in eyes called magnetophosphenes and they accelerate the healing process of fractured bones in magnetotherapy operation. Induced eddy currents also cause neuromuscular stimulation of cardiac muscle, shown as a disturbance in the electrocardiogram and respiratory disturbance shown as a brief period of apnoea (stopped breathing) and muscle contraction in the forearm and finger. Brain cortex also can be stimulated by pulsed magnetic fields. A transient decrease in blood flow in the human skin is seen as a result of exposing the skin to pulsed magnetic fields. To study the effects of time-varying magnetic field, a method is needed to assess and measure induced current densities. Many attempts have been made to find such a method, both theoretically and practically. A theoretical model with homogenous and isotropic concentric loops of tissue was suggested but biological tissues are neither homogenous nor isotropic. A Hall effect method using a slab of semiconductor was suggested for measurement of current densities inside tissues, but this method ignored disturbances in the current pathways inside the tissue as a result of differences in impedances between the semiconductor and the tissue. A cube substitution method using platinized conductive faces implanted in the tissue does not consider problems of alignment of the probes with the direction of isopotential lines or electrode-electrolyte impedance. Also, such electrodes measure only dc current. In a method using a three dimensional electrode to provide three-dimensional information, the author did not give evidence that these electrodes have a zero field distortion, and also did not give information about measurements made using his electrodes. None of the above methods provide a solid approach to the problems of measuring induced current densities. This thesis attempts to present a method of measuring induced current density. The method is capable of measuring both the magnitude and direction of induced current densities. It uses five point electrodes, four of them applied inside the tissue while the fifth one is just in electrical contact with the tissue. The method consists of a probe configuration system, an open-loop operational amplifier and a balanced semi-floating current driver. Leakage current, which goes to the ground and causes error, can be adjusted to be very low (about 0.01% of the total output current). A pair of Helmoltz coils was employed to provide a system for producing time-varying magnetic field. The core of the coil pair was shielded and grounded by a cut metal shield, to avoid any interference from time-varying electric field. The shield was also used as a metal incubator to keep biological samples at body temperature. The heat to the shield was supplied by a unit consisting of four power transistors, and a circuit of sensing, and controlling components. The method used in this study was tested by making measurements of eddy current densities induced in physiological saline solution as a model of a biological conducting fluid. The measurements were represented by arrows, each representing a single measurement, with the length of the arrow representing the magnitude of current density and the direction representing the direction of the induced current. Because electrically induced eddy currents are dependent on electric charge density available inside tissue, and therefore dependent on tissue electrical conductivity, this thesis presents a direct and simple method for measuring complex tissue electrical conductivity. The method uses the same five-electrode system and shares the same point electrode configurations and balanced semi-floating current driver as used for eddy current measurements. The method measures both real and imaginary components of tissue complex conductivity. Both systems are gathered into one box and their functions are separated by four toggle switches. Measurements of electrical induced current densities and complex electrical conductivities for body fluids and tissues have been carried out on saline solutions with different ionic concentrations, expired human whole blood, expired human plasma, human cerebrospinal fluid (CSF) and human urine. Solid tissue such as bovine cardiac muscle and liver were also examined. Current-to-field ratios were obtained for experiments in both fluid and tissues.
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