A comparative analysis of the effect of critical care nursing interventions on acute outcomes in patients with traumatic brain injury

Watts, Jennifer M.

01 January 2010

Traumatic brain injury (TBI) is a leading cause of morbidity and mortality among young children and adults. This primary injury initiates an inflammatory response that may lead to a secondary brain injury. Nursing care in the critical care setting supports prevention or reduction of secondary injury through control of intracranial pressure (ICP), mean arterial pressure (MAP), and the subsequent cerebral perfusion pressure (CPP). While secondary injury may be preventable, some nursing interventions may contribute to increased ICP and decreased CPP. Patients with increased ICP or decreased CPP are at risk for poor clinical outcomes. This literature review examined the effort of routine nursing care interventions on outcomes of TBI patients in the critical care setting. Eleven research articles studying head of bed elevation, head and neck positioning, turning, and spacing of patient care activities were the focus of the analysis. Results typically showed positive outcomes by elevating the head of the bed to thirty degrees. CPP was also maintained at thirty degrees, but showed varied results. ICP and CPP are best controlled with the head and neck in a neutral position. Turning patients is a routine nursing intervention that contributes to increased ICP in some positions in some patients. Most studies suggest ICP is lowest in the supine position and highest in the left lateral position, but differences in findings were noted. Providing basic nursing care interventions in close succession also may contribute to increases in ICP in some patients. Results from this review provide evidence to support the importance of assessing and planning care for each TBI patient individually. It is hoped that findings from this review will provide guidance for bedside nurses to improve clinical practice and drive future research to support best practices for care of patients who suffer TBI.

Nursing

Numerical Modeling of the Effects of Hydrologic Conditions and Sediment Transport on Geomorphic Patterns in Wetlands

Mahmoudi, Mehrnoosh

30 September 2014

This dissertation focused on developing a numerical model of spatial and temporal changes in bed morphology of ridge and slough features in wetlands with respect to hydrology and sediment transport when a sudden change in hydrologic condition occurs. The specific objectives of this research were: (1) developing a two-dimensional hydrology model to simulate the spatial distribution of flow depth and velocity over time when a pulsed flow condition is applied, (2) developing a process-based numerical model of sediment transport coupled with flow depth and velocity in wetland ecosystems, and (3) use the developed model to explore how sediment transport may affect the changes in bed elevation of ridge and slough landscape patterns observed in wetlands when a conditional pulsed flow was applied. The results revealed the areas within deep sloughs where flow velocities and directions change continuously. This caused enhanced mixing areas within the deep slough. These mixing areas may have had the potential to affect processes such as sediment redistribution and nutrient transport. The simulation results of solute/sediment transport model also supported the existence of areas within the domain where the mixing processes happened. These areas may have caused that nutrients and suspended particles stay longer time rather than entraining toward downstream and exiting the system. The results of bed simulation have shown very small magnitude of change in bed elevation inside deep slough and no changes on the ridge portion of the study area, when a conditional pulsed flow is applied. These findings may suggest that implementing pulsed flow condition did not increase suspended sediment concentration, which results in insignificant changes in bed morphology of a ridge and slough landscape. Therefore sediment transport may not play an important role in wetland bed morphology and ridge and slough stability. Results from the model development and numerical simulations from this research will provide an improved understanding of how wetland features such as ridge may have formed and degraded by changes in water management that resulted from increasing human activity in wetlands such as The Florida Everglades, over the past decades.

Wetland landscape

hydrology modeling

sediment transport

bed elevation

ridge and slough

wetland patterning

erosion and deposition

the Everglades

Environmental Engineering

Environmental Monitoring

Hydrology

Numerical Analysis and Computation

Partial Differential Equations

Water Resource Management