Konservative Therapie bei Hirnödem – welche Wege führen nach Rom?

 

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Zusammenfassung

Bei Patienten mit Hirnödem muss die Pathophysiologie der unterschiedlichen Formen des Hirnödems berücksichtigt werden, um die auch heute noch eingeschränkten Behandlungsmöglichkeiten unverzüglich, sinnvoll und konsequent einsetzen zu können. Man unterscheidet 2 Arten von Hirnödemen, das zytotoxische und das vasogene Hirnödem, die in unterschiedlicher Ausprägung nebeneinander bei einem Patienten auftreten können. Oberkörper–Hochlagerung, Hyperventilation, osmotisch aktive Substanzen oder eine gezielte Senkung des Hirnstoffwechsels durch Sedierung oder Hypothermie sollten unter Überwachung von ICP und Blutdruck erfolgen. Möglicherweise führt eine Berücksichtigung der individuellen Autoregulationsmöglichkeiten in der Zukunft zu einem effektiveren Einsatz der dargestellten Behandlungsprinzipien. Die weitere Erforschung der Aquaporine kann neue Wege eröffnen, die Entstehung und die Mobilisation eines Hirnödems zu beeinflussen.

Abstract:

In patients with brain edema the pathophysiology of the different forms of edema have to be considered to ensure the prompt, sensible and consistent use of the limited treatment modalities available. Brain edema may be classified into cytotoxic and vasogenic edema, these two types often coexist in one patient. Head elevation, hyperventilation, osmotic therapy and reduction of brain metabolism by sedation or hypothermia should be used closely monitoring ICP and blood pressure. In the future considering the autoregulatory capacity of the individual patient will possibly lead to a more effective action of the treatment modalities described. Further research will open new perspectives how aquaporines are involved in the genesis and mobilisation of brain edema.

Kernaussagen

• Das zytotoxische Ödem ist definiert als Ansammlung von Flüssigkeit im Inneren der Zelle, die häufigste Ursache hierfür ist eine zerebrale Ischämie. Das vasogene Ödem entsteht durch eine Öffnung der Blut–Hirn–Schranke.

• Beim Schädel–Hirn–Trauma ist das Ödem zunächst überwiegend zytotoxischer Natur – ein vasogenes Ödem spielt erst nach 24 bis 48h eine Rolle.

• Nach intrazerebraler Blutung ist die Aktivierung der Gerinnungskaskade (neben Raumforderung und osmotischen Effekten) für die Entstehung eines Ödems von entscheidender Bedeutung.

• Nach Subarachnoidalblutung entsteht durch die Ischämie ein zytotoxisches Ödem. Als Ursache wird eine vorübergehende globale Ischämie verbunden mit einem initialen Bewusstseinsverlust diskutiert.

• Aquaporin 4 ist impliziert sowohl bei der Entstehung eines zytotoxischen Ödems als auch beim Ausschwemmen eines vasogenen Ödems. Eine Beeinflussung der Aquaporine würde einen neuen Ansatz zur Hirnödemtherapie darstellen, der die bisherigen Therapiemodule sinnvoll ergänzen könnte.

• Eine routinemäßige Oberkörper–Hochlagerung kann ohne entsprechendes Monitoring nicht empfohlen werden.

• Die durch eine unkritisch angewendete, prophylaktische Hyperventilation induzierte zerebrale Vasokonstriktion kann Ischämien verursachen.

• Mannitol wird meist zur kurzfristigen Hirndrucksenkung bei diagnostischen Maßnahmen (CT) oder operativen Eingriffen (Hämatomausräumung) eingesetzt.

• Hypertone Lösungen konnten erfolgreich bei mannitolrefraktären Hirndruckanstiegen eingesetzt werden, es gibt derzeit aber keine allgemeingültige Dosisempfehlung.

• Eine Hypovolämie ist beim Einsatz von osmotisch wirksamen Substanzen unbedingt zu vermeiden.

• Die moderate Hypothermie (33–35°C) ist eine erwiesenermaßen wirksame Methode zur Senkung erhöhter Hirndrücke. Ob durch sie das Outcome der Patienten verbessert wird, ist derzeit noch unklar. Unabhängig davon sind sich alle Experten einig, dass Hyperthermie bei Schädel–Hirn–Verletzten, Reanimierten oder Schlaganfallpatienten unbedingt zu vermeiden ist.

• Das Haupteinsatzgebiet der Barbiturate ist die maximale Reduzierung des Hirnstoffwechsels mit zerebraler Vasokonstriktion zur Beherrschung einer Hirndruckkrise nachdem alle anderen Maßnahmen bereits ausgeschöpft sind.

• Dexametheson und andere Steroide sollten, außer bei Tumoren und Hirnabszessen, nicht zur Standardtherapie des Hirnödems eingesetzt werden.

• Die aktuellen Leitlinien der Brain–Trauma–Foundation geben ein Klasse–II–Empfehlung, CPP–Werte über 70 mmHg unbedingt zu vermeiden.

• Die unkritische Anwendung von Katecholaminen zur Steigerung des CPP kann bei Patienten mit aufgehobener zerebraler Autoregulation die Ödembildung verstärken.

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Prof. Dr. med. Ralf Scherer

Email: r.scherer@clemenshospital.de

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