Elektrische Signale der Harnblase unter Neurostimulation und Anticholinergika: Echtes EMG oder Chaos?[1]

 

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Zusammenfassung

In vivo aufgezeichnete Signale des Detrusor Vesicae entziehen sich dem positiven Beweis ihres myogenen Ursprungs, da der Ausschluss aller denkbaren anderen Signalanteile unmöglich ist. Ziel dieser Arbeit war, mittels Algorithmen aus der Sprachverarbeitung und nichtlinearen Dynamik (Chaos-Theorie) zusätzliche Informationen über das zugrundeliegende dynamische System zu gewinnen. Zuvor aufgezeichnete Signale vom Detrusor von 10 Minipigs unter sakraler Vorderwurzelstimulation vor und nach Gabe von Anticholinergika wurden zunächst mit der Wavelet-Transformation (WT) erneut analysiert; nach Attraktorrekonstruktion wurden die Parameter Correlation Dimension (CD, Komplexität), Central Tendency Measure (CTM, Variabilität) und Lyapunov-Exponent (LE, Chaotizität) bestimmt. Hierbei zeigte sich, dass das Signal unter SARS weniger komplex und chaotisch aber variabler erscheint. Unter Anticholinergika sind die Werte für CD und LE etwa doppelt so hoch. Offensichtlich liegt den aufgezeichneten Signalen ein dynamisches System zugrunde, das in spezifischer Weise auf SARS und Anticholinergika reagiert. Während SARS das System ordnet, stören Anticholinergika diese Ordnung. Dies und die gute Korrelation mit dem Blasendruck sind weitere Indizien dafür, dass diese Signale zumindest zum Teil myogenen Ursprungs sind.

Abstract

Signals recorded from the detrusor vesicae in vivo cannot be proven to originate from smooth muscle since the abolition of all possible influences on the signal is impossible. Our objective was to gain additional information about the underlying dynamic system using algorithms from digital speech analysis and nonlinear dynamics. Previously recorded signals from the detrusor in 10 minipigs under sacral anterior root stimulation (SARS), before and after administration of anticholinergics, were re-analyzed with Wavelet-Transformation (WT). After reconstruction of the attractors, correlation dimension (CD, complexity), central tendency measure (CTM, variability) and Lyapunov exponents (LE, chaoticity) were calculated. The signal under SARS appears less complex, less chaotic, but more variable than the native signal. Under the influence of anticholinergics, the base line values for CD and LE are about doubled. The dynamic system generating these signals obviously responds in a characteristic manner to the experimental settings. SARS brings order to the system, whereas this order is disturbed by anticholinergics. This and the correlation with bladder pressure indicate that signals recorded from the urinary bladder are at least in part myogenic and hence a real detrusor EMG.

1 Gefördert durch DFG Sche 494/2-1

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1 Gefördert durch DFG Sche 494/2-1

J Weiss

Urologische Klinik Klinikum

68135 Mannheim

Email: E-mail: joachim.weiss@uro.ma.uni-heidelberg.de