Multidisciplinární spolupráce a role sestry v péči o pacienty s blast syndromem / Multidisciplinary Cooperation and the Role of a Nurse in Patient Care Affected by Blast Syndrome

KOPULETÁ, Martina

January 2016

Blast injury is a very serious lesion caused by the shock wave resulting from an explosion. Further secondary injuries can arise from burying under debris, pieces of shards from the explosive cover, at burning, poisonous gases created by chemical reactions during detonation. The injuries often happen to be fatal and the percentage of people who survive it depends on the fact how far from the epicentre they were situated. If the individual is very close, there is almost no chance to survive, if, however, the individual is situated further from the epicentre, a few tens of meters, the chance is higher. It is so called mass disaster, which includes more injured people at an explosion. Therefore it is necessary for nurses and the hospital staff to know what the procedures are at this incident and how to take medical and nursing care of higher number of such patients suffering from blast injury. The care itself is extremely demanding, since the injured are often in critical condition. The aim of this diploma thesis, the topic of which is multidisciplinary cooperation and the role of a nurse when taking care of the patients suffering from blast injury, was to find out the information based on the latest Czech and foreign literature and create a compact overview of the knowledge of this issue, for it is necessary to have this knowledge to carry out nursing care of such patients. The second aim of this diploma thesis was to map the role of a nurse in details when taking care of a patient suffering from blast injury. This aim was stated for the reason of the demanding character and complexity of nursing care at urgent reception and anaesthesiology and resuscitation unit because the nurses at these units are placed demands on high qualification and requirements. This diploma thesis was purely elaborated as theoretical thesis based on Czech and foreign sources. The given pieces of information were obtained from a great deal of professional and scientific publications, monographs, professional journals and internet sources for each chapter. The first part of the thesis was dedicated to the description of the given issue, pre-hospital care and classifying algorithms that are used at mass health losses in such way so that the injured people have a higher chance to survive. The crisis management at hospitals, the reception of the injured, the care at the urgent unit and finally the follow-up care at the anaesthesiology and resuscitation unit are worked out in the following part. Thereafter the theoretical part focuses on nursing care at the critical care department where the nursing care of a patient suffering from blast injury is described as well as the duties of a nurse. The needed competences of a nurse working at the urgent unit, anaesthesiology and resuscitation unit are also defined in this chapter. According to the valid Czech legislation, only specially trained nurses for intensive care should take care of the patients with blast injury because the extent of their competence for intensive care is many times higher than general nurses have. The last chapter deals with team and multidisciplinary cooperation among the doctors and hospital staff as well as the cooperation concerning the pre-hospital care of the emergency services at emergency incident, for their active and quality communication are the keys for good and well done work with the least consequences.

Numerical Simulation of Blast Interaction with the Human Body: Primary Blast Brain Injury Prediction

Haladuick, Tyler

January 2014

In Operations Enduring Freedom and Iraqi Freedom, explosions accounted for 81% of all injuries; this is a higher casualty percentage than in any previous wars. Blast wave overpressure has recently been associated with varying levels of traumatic brain injury in soldiers exposed to blast loading. Presently, the injury mechanism behind primary blast brain injury is not well understood due to the complex interactions between the blast wave and the human body. Despite these limitations in the understanding of head injury thresholds, head kinematics are often used to predict the overall potential for head injury. The purpose of this study was to investigate head kinematics, and predict injury from a range of simulated blast loads at varying standoff distances and differing heights of bursts. The validated Generator of body data multi-body human surrogate model allows for numerical kinematic data simulation in explicit finite element method fluid structure interaction blast modeling. Two finite element methods were investigated to simulate blast interaction with humans, an enhanced blast uncoupled method, and an Arbitrary Lagrangian Eularian fully coupled method. The enhanced blast method defines an air blast function through the application of a blast pressure wave, including ground reflections, based on the explosives relative location to a target; the pressures curves are based on the Convention Weapons databases. LBE model is efficient for parametric numerical studies of blast interaction where the target response is the only necessary result. The ALE model, unlike classical Lagrangian methods, has a fixed finite element mesh that allows material to flow through it; this enables simulation of large deformation problems such as blast in an air medium and its subsequent interaction with structures. The ALE model should be used when research into a specific blast scenario is of interest, since this method is more computationally expensive. The ALE method can evaluate a blast scenario in more detail including: explosive detonation, blast wave development and propagation, near-field fireball effects, blast wave reflection, as well as 3D blast wave interaction, reflection and refraction with a target. Both approaches were validated against experimental blast tests performed by Defense Research and Development Valcartier and ConWep databases for peak pressure, arrival time, impulse, and curve shape. The models were in good agreement with one another and follow the experimental data trend showing an exponential reduction in peak acceleration with increasing standoff distance until the Mach stem effect reached head height. The Mach stem phenomenon is a shock front formed by the merging of the incident and reflected shock waves; it increases the applied peak pressure and duration of a blast wave thus expanding the potential head injury zone surrounding a raised explosive. The enhanced blast model was in good agreement with experimental data in the near-field, and mid-field; however, overestimated the peak acceleration, and head injury criteria values in the far-field due to an over predicted pressure impulse force. The ALE model also over predicted the response based on the head injury criteria at an increased standoff distance due to smearing of the blast wave over several finite elements leading to an increased duration loading. According to the Abbreviated Injury Scale, the models predicted a maximal level 6 injury for all explosive sizes in the near-field, with a rapid acceleration of the head over approximately 1 ms. There is a drastic exponential reduction in the insult force and potential injury received with increasing standoff distance outside of the near-field region of an explosive charge.

Primary Blast Injury

Traumatic Brain Injury

Arbitrary Lagrangian Eularian

ALE

TBI

Fluid Structure Interaction

FSI

Head Injury Criterion

HIC

Mild Traumatic Brain Injury

mTBI

Finite Element Method

FEM

Blast Wave Physics

Explosive Loading on Structures

LS-Dyna

Prasad Mertz Curves

Scaled Distance

Numerical Simulation

Finite Element Modelling

Mach Stem