Secondary Insults in Neurointensive Care of Patients with Traumatic Brain Injury

Elf, Kristin

January 2005

Traumatic brain injury (TBI) is a major cause of death and disability. Intracranial secondary insults (e.g. intracranial haematoma, brain oedema) and systemic secondary insults (e.g. hypotension, hypoxaemia, hyperthermia) lead to secondary brain injury and affect outcome adversely. In order to minimise secondary insults and to improve outcome in TBI-patients, a secondary insult program and standardised neurointensive care (NIC) was implemented. The aim of this thesis was to describe patient outcome and to explore the occurrence and prognostic value of secondary insults after the implementation. Favourable outcome was achieved in 79% and 6% died of the 154 adult TBI patients treated in the NIC unit 1996-97. In an earlier patient series from the department, 48% made a favourable outcome and 31% died. Hence, the outcome seems to have improved when NIC was standardised and dedicated to avoiding secondary insults. Secondary insults counted manually from hourly recordings on surveillance charts did not hold any independent prognostic information. When utilising a computerised system, which enables minute-by-minute data collection, the proportion of monitoring time with systolic blood pressure > 160 mm Hg decreased the odds of favourable outcome independent of admission variables (odds ratio 0.66). Hyperthermia was related to unfavourable outcome. Hypertension was correlated to hyperthermia and may be a part of a hyperdynamic state aggravating brain oedema. Increased proportion of monitoring time with cerebral perfusion pressure (CPP) < 60 mm Hg increased the odds of favourable outcome (odds ratio 1.59) in patients treated according to an intracranial pressure (ICP)-oriented protocol (Uppsala). In patients given a CPP-oriented treatment (Edinburgh), CPP <60 mm Hg was coupled to an unfavourable outcome. It was shown that pressure passive patients seem to benefit from an ICP-oriented protocol and pressure active patients from a CPP-oriented protocol. The overall outcome would improve if patients were given a treatment fit for their condition.

Neurosciences

Traumatic brain injury

Neurointensive care

Monitoring

Secondary insults

Intracranial pressure

Cerebral perfusion pressure

Pressure reactivity

Temperature

Neural network

Outcome

Neurovetenskap

Neurology

Neurologi

Biomechanické aspekty dynamiky intrakraniálního tlaku při kraniocerebrálním poranění. / Biomechanical aspects of the dynamics of intracranial pressure in traumatic brain injury

Mayer, Martin

January 2014

Title: Biomechanical aspects of the dynamics of intracranial pressure in traumatic brain injury Author: Ing. Martin Mayer e-mail: mayercz@seznam.cz Department: Department of Anatomy and Biomechanics Supervisor: doc. PaedDr. Karel Jelen, CSc. This PhD thesis "Biomechanical aspects of the dynamics of intracranial pressure in traumatic brain injury" is about the dynamics of intracranial pressure, particularly in relation to the external mechanical action of the patient. Severe head injury is the leading cause of death in patients under 35 years of age. Despite constantly-improving medical and nursing care only one third of patients, after recovery, regained the ability to live independently in the long term. Two-thirds of patients were severely disabled or died. The lifetime cost of such a patient who was not completely cured has been calculated to be $4,000,000. A significant consequence of craniocerebral injuries are secondary brain lesions, which among other means the rise in intracranial pressure (ICP), which can further exacerbate due to intracerebral or extracerebral causes. Therefore, the objective of the treatment is minimizing secondary injury, optimally at the phase of the primary lesion. However, realization of this requirement, about which we can say that is a conditio sine qua non, sometimes leads...

Biomechanické aspekty dynamiky intrakraniálního tlaku při kraniocerebrálním poranění. / Biomechanical aspects of the dynamics of intracranial pressure in traumatic brain injury

Mayer, Martin

January 2014

Title: Biomechanical aspects of the dynamics of intracranial pressure in traumatic brain injury Author: Ing. Martin Mayer e-mail: mayercz@seznam.cz Department: Department of Anatomy and Biomechanics Supervisor: doc. PaedDr. Karel Jelen, CSc. This PhD thesis "Biomechanical aspects of the dynamics of intracranial pressure in traumatic brain injury" is about the dynamics of intracranial pressure, particularly in relation to the external mechanical action of the patient. Severe head injury is the leading cause of death in patients under 35 years of age. Despite constantly-improving medical and nursing care only one third of patients, after recovery, regained the ability to live independently in the long term. Two-thirds of patients were severely disabled or died. The lifetime cost of such a patient who was not completely cured has been calculated to be $4,000,000. A significant consequence of craniocerebral injuries are secondary brain lesions, which among other means the rise in intracranial pressure (ICP), which can further exacerbate due to intracerebral or extracerebral causes. Therefore, the objective of the treatment is minimizing secondary injury, optimally at the phase of the primary lesion. However, realization of this requirement, about which we can say that is a conditio sine qua non, sometimes leads...

Quantitative functional MRI of the Cerebrovascular Reactivity to CO2

Tancredi, Felipe B.

02 1900

Le dioxyde de carbone (CO2) est un résidu naturel du métabolisme cellulaire, la troisième substance la plus abondante du sang, et un important agent vasoactif. À la moindre variation de la teneur en CO2 du sang, la résistance du système vasculaire cérébral et la perfusion tissulaire cérébrale subissent des changements globaux. Bien que les mécanismes exacts qui sous-tendent cet effet restent à être élucidés, le phénomène a été largement exploité dans les études de réactivité vasculaire cérébrale (RVC). Une voie prometteuse pour l’évaluation de la fonction vasculaire cérébrale est la cartographie de la RVC de manière non-invasive grâce à l’utilisation de l’Imagerie par Résonance Magnétique fonctionnelle (IRMf). Des mesures quantitatives et non-invasives de de la RVC peuvent être obtenus avec l’utilisation de différentes techniques telles que la manipu- lation du contenu artériel en CO2 (PaCO2) combinée à la technique de marquage de spin artériel (Arterial Spin Labeling, ASL), qui permet de mesurer les changements de la perfusion cérébrale provoqués par les stimuli vasculaires. Toutefois, les préoccupations liées à la sensibilité et la fiabilité des mesures de la RVC limitent de nos jours l’adoption plus large de ces méthodes modernes de IRMf. J’ai considéré qu’une analyse approfondie ainsi que l’amélioration des méthodes disponibles pourraient apporter une contribution précieuse dans le domaine du génie biomédical, de même qu’aider à faire progresser le développement de nouveaux outils d’imagerie de diagnostique. Dans cette thèse je présente une série d’études où j’examine l’impact des méthodes alternatives de stimulation/imagerie vasculaire sur les mesures de la RVC et les moyens d’améliorer la sensibilité et la fiabilité de telles méthodes. J’ai aussi inclus dans cette thèse un manuscrit théorique où j’examine la possible contribution d’un facteur méconnu dans le phénomène de la RVC : les variations de la pression osmotique du sang induites par les produits de la dissolution du CO2. Outre l’introduction générale (Chapitre 1) et les conclusions (Chapitre 6), cette thèse comporte 4 autres chapitres, au long des quels cinq différentes études sont présentées sous forme d’articles scientifiques qui ont été acceptés à des fins de publication dans différentes revues scientifiques. Chaque chapitre débute par sa propre introduction, qui consiste en une description plus détaillée du contexte motivant le(s) manuscrit(s) associé(s) et un bref résumé des résultats transmis. Un compte rendu détaillé des méthodes et des résultats peut être trouvé dans le(s) dit(s) manuscrit(s). Dans l’étude qui compose le Chapitre 2, je compare la sensibilité des deux techniques ASL de pointe et je démontre que la dernière implémentation de l’ASL continue, la pCASL, offre des mesures plus robustes de la RVC en comparaison à d’autres méthodes pulsés plus âgées. Dans le Chapitre 3, je compare les mesures de la RVC obtenues par pCASL avec l’utilisation de quatre méthodes respiratoires différentes pour manipuler le CO2 artérielle (PaCO2) et je démontre que les résultats peuvent varier de manière significative lorsque les manipulations ne sont pas conçues pour fonctionner dans l’intervalle linéaire de la courbe dose-réponse du CO2. Le Chapitre 4 comprend deux études complémentaires visant à déterminer le niveau de reproductibilité qui peut être obtenu en utilisant des méthodes plus récentes pour la mesure de la RVC. La première étude a abouti à la mise au point technique d’un appareil qui permet des manipulations respiratoires du CO2 de manière simple, sécuritaire et robuste. La méthode respiratoire améliorée a été utilisée dans la seconde étude – de neuro-imagerie – où la sensibilité et la reproductibilité de la RVC, mesurée par pCASL, ont été examinées. La technique d’imagerie pCASL a pu détecter des réponses de perfusion induites par la variation du CO2 dans environ 90% du cortex cérébral humain et la reproductibilité de ces mesures était comparable à celle d’autres mesures hémodynamiques déjà adoptées dans la pratique clinique. Enfin, dans le Chapitre 5, je présente un modèle mathématique qui décrit la RVC en termes de changements du PaCO2 liés à l’osmolarité du sang. Les réponses prédites par ce modèle correspondent étroitement aux changements hémodynamiques mesurés avec pCASL ; suggérant une contribution supplémentaire à la réactivité du système vasculaire cérébral en lien avec le CO2. / Carbon dioxide (CO2) is a natural byproduct of cellular metabolism, the third most abundant substance of blood, and a potent vasoactive agent. The resistance of cerebral vasculature and perfusion of the brain tissue respond to the slightest change in blood CO2 content. The physiology of such an effect remains elusive, yet the phenomenon has been widely exploited in studies of the cerebral vascular function. A promising avenue for the assessment of brain’s vascular function is to measure the cerebrovascular reactivity to CO2 (CVR) non-invasively using functional MRI. Quantitative and non-invasive mapping of CVR can be obtained using respiratory manipulations in arterial CO2 and Arterial Spin Labeling (ASL) to measure the perfusion changes associated with the vascular stimulus. However, concerns related to the sensitivity and reliability of CVR mea- sures by ASL still limit their broader adoption. I considered that a thorough analysis and amelioration of available methods could bring a valuable contribution in the domain of biomedical engineering, helping to advance new diagnostic imaging tools. In this thesis I present a series of studies where I exam the impact of alternative manipulation/ASL methods on CVR measures, and ways to improve the sensitivity and reliability of these measures. I have also included in this thesis a theoretical paper, where I exam the possible contribution of an unappreciated factor in the CVR phenomenon: the changes in blood osmotic pressure induced by the products of CO2 dissolution. Apart from a general introduction (Chapter 1) and conclusion (Chapter 6), this thesis comprises 4 other chapters, in which five different research studies are presented in the form of articles accepted for publication in scientific journals. Each of these chapters begins with its own specific introduction, which consists of a description of the background motivating the study and a brief summary of conveyed findings. A detailed account of methods and results can be found in the accompanying manuscript(s). The study composing Chapter 2 compares the sensitivity of two state-of-the-art ASL techniques and show that a recent implementation of continuous ASL, pCASL, affords more robust measures of CVR than older pulsed methods. The study described in Chapter 3 compares pCASL CVR measures obtained using 4 different respiratory methods to manipulate arterial CO2 (PaCO2) and shows that results can differ significantly when manipulations are not designed to operate at the linear range of the CO2 dose-response curve. Chapter 4 encompasses two complementary studies seeking to determine the degree of reproducibility that can be attained measuring CVR using the most recent methods. The first study resulted in the technical development of a breathing apparatus allowing simple, safe and robust respiratory CO2 manipulations. The improved respiratory method was used in the second – neuroimaging – study, in which I and co-authors investigate the sensitivity and reproducibility of pCASL measuring CVR. The pCASL imaging technique was able to detect CO2-induced perfusion responses in about 90% of the human brain cortex and the reproducibility of its measures was comparable to other hemodynamic measures already adopted in the clinical practice. Finally, in Chapter 5 I present a mathematical model that describes CVR in terms of PaCO2-related changes in blood osmolarity. The responses predicted by this model correspond closely to the hemodynamic changes measured with pCASL, suggesting an additional contribution to the reactivity of cerebral vasculature to CO2.

dyoxide de carbone

IRM fonctionnelle

Arterial Spin Labeling

perfusion cérébrale

pression osmotique du sang

Cerebrovascular reactivity

carbon dioxide

functional MRI

Arterial Spin Labeling

cerebral perfusion

blood osmotic pressure

MR-tomographische Bestimmung der zerebrovaskulären Reservekapazität bei Probanden und Patienten mittels BOLD-Kontrast / Non-invasive measurement of cerebrovascular reserve capacity in healthy adults and patients using BOLD fMRI at 3 Tesla

Rühlmann, Johanna

25 October 2011

No description available.

610 Medizin, Gesundheit

Medicine

Gehirn

Kohlendioxyd

Carotisstenose

Zerebrovaskuläre Zirkulation

Magnetresonanztomographie

Sauerstoff

Zerebrovaskuläre Reservekapazität

Brain

Carbon Dioxide

Carotid Stenosis

Cerebrovascular Circulation

Magnetic Resonance Imaging

Oxygen

Cerebral Perfusion Reserve

44.03

Intra-aortic balloon pump (IABP) counterpulsation improves cerebral perfusion in patients with decreased left ventricular function

Pfluecke, C., Christoph, M., Kolschmann, S., Tarnowski, D., Forkmann, M., Jellinghaus, S., Poitz, D. M., Wunderlich, C., Strasser, R. H., Schoen, S., Ibrahim, K.

17 September 2019

Background: The current goal of treatment after acute ischemic stroke is the increase of cerebral blood flow (CBF) in ischemic brain tissue. Intra-aortic balloon pump (IABP) counterpulsation in the setting of cardiogenic shock is able to reduce left ventricular afterload and increase coronary blood flow. The effects of an IABP on CBF have not been sufficiently examined. We hypothesize that the use of an IABP especially enhances cerebral blood flow in patients with pre-existing heart failure. Methods: In this pilot study, 36 subjects were examined to investigate the effect of an IABP on middle cerebral artery (MCA) transcranial Doppler (TCD) flow velocity change and relative CBF augmentation by determining velocity time integral changes (ΔVTI) in a constant caliber of the MCA compared to a baseline measurement without an IABP. Subjects were divided into two groups according to their left ventricular ejection fraction (LVEF): Group 1 LVEF >30% and Group 2 LVEF ≤30%. Results: Both groups showed an increase in CBF using an IABP. Patients with a LVEF ≤30% showed a significantly higher increase of ΔVTI in the MCA under IABP augmentation compared to patients with a LVEF >30% (20.9% ± 3.9% Group 2 vs.10.5% ± 2.2% Group 1, p<0,05). The mean arterial pressure (MAP) increased only marginally in both groups under IABP augmentation. Conclusions: IABP improves cerebral blood flow, particularly in patients with pre-existing heart failure and highly impaired LVEF. Hence, an IABP might be a treatment option to improve cerebral perfusion in selected patients with cerebral misperfusion and simultaneously existing severe heart failure.

info:eu-repo/classification/ddc/610

ddc:610

Desenvolvimento de cateter implantável de monitorização de pressão intracraniana

Rosario, Jeferson Cardoso do

18 January 2019

Submitted by JOSIANE SANTOS DE OLIVEIRA (josianeso) on 2019-03-25T11:56:58Z No. of bitstreams: 1 Jeferson Cardoso do Rosario_.pdf: 3523684 bytes, checksum: 6d033c623e7ef74a93692efd6ca37e8e (MD5) / Made available in DSpace on 2019-03-25T11:56:58Z (GMT). No. of bitstreams: 1 Jeferson Cardoso do Rosario_.pdf: 3523684 bytes, checksum: 6d033c623e7ef74a93692efd6ca37e8e (MD5) Previous issue date: 2019-01-18 / Nenhuma / O traumatismo cranioencefálico (TCE) é atualmente a terceira maior causa de óbitos no âmbito mundial. Estudos recentes têm demonstrado que a monitorização de pressão intracraniana (PIC), como forma de cálculo da pressão de perfusão cerebral (PPC) é uma ferramenta importante para avaliação do fluxo sanguíneo cerebral (FSC), provocando sensível redução nas taxas de mortalidade. Além do TCE, outras patologias ou situações neurocirúrgicas tem utilizado a técnica de monitorização de PIC. A monitorização desse parâmetro foi proposta já na década de 50, onde um tubo com fluido em contato com o líquido cefalorraquidiano (LCR) era introduzido no espaço intracraniano e conectado a um transdutor de pressão externo. Com a evolução da indústria microeletrônica e dos sistemas microeletromecânicos, foi possível colocar os transdutores na ponta do cateter, permitindo uma monitorização menos invasiva, com menos riscos de infecções. Os cateteres atuais com micro transdutor na ponta podem ser divididos em três grupo: straingauge, fibra óptica e pneumático. Cada grupo possui suas características, entretanto o primeiro tem se demonstrado como solução mais robusta e confiável, com boa relação custo benefício. No presente trabalho foi proposto o desenvolvimento de um cateter implantável de monitorização de pressão intracraniana do tipo micro transdutor strain-gauge. Foram construídos protótipos funcionais e submetidos a ensaios de desempenho, especificados em norma técnica para monitorização de pressão sanguínea, a influência da temperatura na medição de pressão, bem como a exatidão das medições. Os processos empregados no trabalho são utilizados comumente na indústria de encapsulamento de semicondutores, porém foram levadas em consideração as especificidades da aplicação, adequando as técnicas disponíveis às geometrias e materiais empregados, considerando a necessidade de utilização de materiais biocompatíveis. / The traumatic brain injury (TBI) is nowadays the third cause of death in the world. Recent studies have shown the intracranial pressure (ICP) monitoring as an important tool for cerebral perfusion pressure (CPP) calculation and cerebral blood flow (CBF) assestment, reducing significantly the mortality statistics. Besides TBI, several others pathologies and neurosurgery conditions have been using the ICP monitoring technique. The proposal of ICP monitoring first appeared on the 50’s, where a tube fulfilled with fluid in contact with cerebrospinal fluid (CSF) was introduced into the intracranial space and connected to an external pressure transducer. With the waves of the microelectronics and microelectromechanical systems (MEMS) industry evolution, it was possible to put the transducer and all the electronics inside the catheter tip, allowing a less invasive monitoring, decreasing the risk of infection. The state of art catheters with micro transducer on the tip can be divided into three groups: strain-gauge, optical fiber and pneumatic. Each group has it’s own characteristics, however the first has been demonstrated as the rugged solution, being reliable, cost effective and with good accuracy. In the present work, it was proposed the development of an strain-gauge micro transducer implantable catheter for intracranial pressure monitoring. Functional prototypes were built and submitted to performance tests, according to the technical standards in the medical equipment area, the temperature influence over the pressure measurements was evaluated, as well as the accuracy. The adopted processes are commonly used in the semiconductor packaging industry, however it was considered the application special requirements, adapting the processes to the geometry and materials used, considering the needs of biocompatible materials.

Pressão intracraniana (PIC)

Cateter

Monitorização de PIC

Dispositivos implantáveis

Pressão de perfusão cerebral (PPC)

Monitorização invasiva

Polímeros biocompatíveis

Sistemas microeletromecânicos (MEMS)

Intracranial pressure (ICP)

Catheter

ICP monitoring

Implantable devices

Cerebral perfusion pressure (CPP)

Invasive monitoring

Biocompatible polymers

Microelectromechanical systems (MEMS)

Die Bedeutung des zerebralen Perfusionsdruckes in der Behandlung des schweren Schädel-Hirn-Traumes

Kroppenstedt, Stefan Nikolaus

25 November 2003

Die Höhe des optimalen zerebralen Perfusionsdruckes nach schwerem Schädel-Hirn-Trauma wird kontrovers diskutiert. Während im sogenannten Lund-Konzept ein niedriger Perfusionsdruck angestrebt und die Gabe von Katecholaminen aufgrund potentieller zerebraler vasokonstringierender und weiterer Nebeneffekte vermieden wird, befürwortet das CPP-Konzept nach Rosner eine Anhebung des zerebralen Perfusionsdruckes, wenn notwendig unter intravenöser Gabe von Katecholaminen. Vor diesem Hintergrund galt es, in einem experimentellen Schädel-Hirn-Trauma- Modell der Ratte (Controlled Cortical Impact Injury) den Bereich des optimalen zerebralen Perfusionsdruckes nach traumatischer Hirnkontusion zu ermitteln und den Effekt von Katecholaminen auf den posttraumatischen zerebralen Blutfluss und die Entwicklung des sekundären Hirnschadens zu untersuchen. Die wesentlichen Ergebnisse dieser Arbeit lassen sich wie folgt zusammenfassen: In der Akutphase nach Hirnkontusion liegt der Bereich des zerebralen Perfusionsdruckes, welcher die Entwicklung des Kontusionsvolumens nicht beeinflusst, zwischen 70 und 105 mm Hg. Eine Senkung des Perfusionsdruckes unterhalb bzw. Anhebung oberhalb dieser Schwellenwerte vergrößert das Kontusionsvolumen. Die Anhebung des Blutdruckes mittels intravenöser Infusion von Dopamin oder Noradrenalin führt sowohl in der Frühphase als auch in der Spätphase nach Trauma (4 Stunden bzw. 24 Stunden nach kortikaler Kontusion) zu einem signifikanten Anstieg im kortikalen perikontusionellen Blutfluss und in der Hirngewebe-Oxygenierung. Die durch Anhebung des zerebralen Perfusionsdruckes auf über 70 mm Hg induzierte Verbesserung des posttraumatischen zerebralen Blutflusses bewirkte jedoch keine Reduzierung der Hirnschwellung. Für eine Katecholamin-induzierte zerebrale Vasokonstriktion nach kortikaler Kontusion gibt es keinen Anhalt. Um die Entwicklung des sekundären Hirnschadens nach kortikaler Kontusion zu minimieren, sollte der zerebrale Perfusionsdruck nach traumatischem Hirnschaden nicht unterhalb 70 mm Hg liegen. Eine Anhebung des Perfusionsdruckes auf über 70 mm Hg erscheint nicht notwendig oder vorteilhaft zu sein. Wenn notwendig, kann sowohl in der Früh- als auch Spätphase nach Trauma der zerebrale Perfusionsdruck mittels intravenöser Gabe von Katecholaminen angehoben werden. / The optimum cerebral perfusion pressure after severe traumatic brain injury remains to be controversial. In the Lund concept a relatively low cerebral perfusion pressure is preferred, and administration of catecholamines is avoided due to potential catecholamine-mediated cerebral vasoconstriction and other side effects. In contrast, the CPP concept of Rosner recommends elevation of cerebral perfusion pressure, if needed by intravenous administration of catecholamines. Based on this, in an experimental model of traumatic brain injury of the rat (Controlled Cortical Impact Injury) the optimum range of cerebral perfusion pressure after traumatic brain contusion and the effects of catecholamines on posttraumatic cerebral perfusion and development of secondary brain injury were investigated. The most significant results can be summarized as follows: In the acute phase after brain contusion the range of cerebral perfusion pressure that does not affect the development of posttraumatic contusion volume was found to be between 70 and 105 mm Hg. Reduction of the cerebral perfusion pressure below or elevation above these thresholds increases contusion volume. Elevation of blood pressure by intravenous infusion of dopamine or norepinephrine during the early (4 hours) as well as late (24 hours) phase after trauma results in a significant increase in pericontusional blood flow and brain tissue oxygenation. The increase in cerebral blood flow by elevating cerebral perfusion pressure above 70 mm Hg did not decrease cerebral edema formation. There was no evidence of a catecholamine-induced cerebral vasoconstriction after cortical contusion. In order to minimize secondary brain injury after cortical contusion, cerebral perfusion pressure should not fall bellow 70 mm Hg. However, a further active elevation of cerebral perfusion pressure does not appear necessary or beneficial. If needed cerebral perfusion pressure can be elevated by administration of catecholamines in the early as well late phase after trauma.

Schädel-Hirn-Trauma

Dopamin

zerebraler Blutfluss

intrakranieller Druck

zerebraler Perfusionsdruck

Laser Doppler

Cortical Impact Injury

Hirnödem

Noradrenalin

Blutdruckanhebung

traumatic brain injury

dopamine

cerebral blood flow

intracranial pressure

cerebral perfusion pressure

laser Doppler

cortical impact injury

brain swelling

norepinephrine

blood pressue elevation

610 Medizin

33 Medizin

ddc:610