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B. Schmidt, M. Czosnyka*, P. Smielewski*, R. Plontke,

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Presentation on theme: "B. Schmidt, M. Czosnyka*, P. Smielewski*, R. Plontke,"— Presentation transcript:

1 Non-invasive assessment of intracranial pressure - a plugin function of ICM+ system
B. Schmidt, M. Czosnyka*, P. Smielewski*, R. Plontke, J. Schwarze, J. Klingelhöfer Dept. of Neurology, Medical Centre Chemnitz, Germany * Ac. Neurosurgical Unit, Addenbrooke’s Hospital, Cambridge, UK

2 Non-invasive ICP assessment procedure - for scientific use only -
 The procedure calculates Intracranial Pressure from Arterial Blood Pressure and Transcranial Doppler Blood Flow Velocitiy of Middle Cerebral Artery  Patented: by Patent Nr. DE  Distributed by the authors as a Plugin of ICM+ Monitoring Software / University Cambridge, UK - for scientific use only -

3 The list of functions in ICM+ can be extended by plugins
The list of functions in ICM+ can be extended by plugins. One such plugin already available for ICM+ enables non-invasive calculation of ICP from TCD FV and ABP signals in real time. ICP Non-invasive ICP ICP Non-invasive ICP

4 How to insert nICP plugin into ICM+:.
- The non-invasive ICP plugin is a DLL file, developed in a C++ Borland environment. - Copy the plugin into the ICM+ plugin folder, e.g. pathname is "C:\Documents and Settings\All Users\Documents\ICM+\Plugins\" - Now start ICM+. The plugin should be shown in the registration dialogue under "3rd Party Plugins”. You send us the registration data of your ICM+ license, which contains name, company and ICM+ install code. The data should be exactly the same as it is in the ICM+ registration form. - Using this data we calculate your registration key for the nICP plugin and send it back to you by . - You enter the registration key of this plugin in the ICM+ dialogue. This activates the nICP plugin, unlimited in time. DE

5 Basic principle of the procedure
Calculate the signal of intracranial pressure (ICP) from signals of arterial blood pressure (ABP) and blood flow velocity (FV) of the middle cerebral artery (MCA)

6 Non-invasive ICP assessment – basic method
TCD-characteristics { tcdj } j = 0, ..., m FV ABP weight function ABP ® ICP { wi } i = 0, ..., n nICP (non-invasive ICP) FV : blood flow velocity in middle cerebral artery ABP: arterial blood pressure ICP: intracranial pressure TCD: transkranial Doppler ultrasound weight function = impulse response: signal transformation, time domain equivalent of transfer function

7 S Generation of the nICP Procedure FV ABP ICP w  A * tcd + B
Signal data of reference patients FV ABP ICP ICPj = ABPj-k * wk k=0 S n TCD characteristics tcd = (tcd0, tcd1, ..., tcdm) weight function ABP ® ICP w = (w0, w1, ..., wn) Multiple Regression analyses w  A * tcd + B A (n+1) x (m+1) Matrix B n+1-dim. Vektor (A,B) : nICP Matrix, (n+1) x (m+2) Dim

8 non-invasive ICP assessment – basic method
weight function ABP ® FV { tj } j = 0, ..., 12 FV ABP { wi } = A * ( {tj}x , PI, dFV, ) + B weight function ABP ® ICP { wi } i = 0, ..., n nICP Matrix A, Vector B generated by multiple regression analyses of reference data TCD-characteristics ® weight function ABP ® ICP PI: Pulsatility index dFV: diastolic FV

9 Results 1 - non-invasive ICP assessment
on average of  patient-day recordings: mean DICP = 5.2 ± 3.7 mm Hg 95% CI = 12.4 mm Hg median DICP = 4.2 mm Hg  patient recordings: mean DICP = 5.0 ± 3.3 mm Hg 95% CI = 10.8 mm Hg DICP = mean abs (ICP-nICP)

10 Bland-Altman Plot of nICP - ICP comparison
-30 -25 -20 -15 -10 -5 5 10 15 20 25 30 40 50 95% CI Bland-Altman Plot of nICP - ICP comparison on average of Daily Recordings: N = 315 nICP-ICP [mm Hg] (nICP+ICP)/2 [mm Hg] -20 -15 -10 -5 5 10 15 20 25 30 40 Bland-Altman Plot of nICP - ICP comparison on average of Patient Recordings: N = 137 nICP-ICP [mm Hg] 95% CI (nICP+ICP)/2 [mm Hg]

11 nICP - ICP comparison in recordings nICP - ICP comparison in patients
40 ICP [mm Hg] y = 0,863x + 1 35 30 25 20 15 10 5 5 10 15 20 25 30 35 40 45 nICP - ICP comparison in patients 40 ICP [mm Hg] 35 30 25 20 15 10 5 5 10 15 20 25 30 35 40 nICP [mm Hg]

12 Results 3 - non-invasive ICP assessment
nICP assessment replicates ICP trends in recordings with high ICP dynamic:  95th perc ICP > 5th perc ICP + 10 mm Hg , 33 recordings, mean nICP - ICP correlation R = 0.53 ± 0.47  90th perc ICP > 10th perc ICP + 9 mm Hg , 27 recordings, mean nICP - ICP correlation R = 0.57 ± 0.46

13 Example 1 033040AL.1L5

14 Example 2 038080JM.0L5

15 Example 2 038080JM.0L5

16 Example 4 053022AW.0L5

17 Conclusions  in the clinically relevant range of ICP the nICP assessment showed a reasonable accuracy  nICP assessment replicates ICP changes and trends  nICP plugin of ICM+ may be used for clinical studies * in patients without implanted ICP probes * Pfister D, Schmidt B, Smielewski P, Siegemund M, Strebel SP, Rüegg S, Marsch SCU, Pargger H, Steiner LA. Intracranial Pressure in Patients with Sepsis. Acta Neurochir Suppl. 102:71-75, 2008 Schmidt B, Weinhold M, Czosnyka M, May SA, Steinmeier R, Klingelhöfer J. Accuracy of non-invasive ICP assessment can be increased by an initial individual calibration. Acta Neurochir Suppl. 102: 49-52, 2008 Schmidt B, Klingelhöfer J, Perkes I, Czosnyka M. Cerebral Autoregulatory Response Depends on the Direction of Change in Perfusion Pressure. J Neurotrauma. 26:1-6, 2009 Reinhard M, Neunhoeffer F, Gerds TA, Niesen WD, Buttler KJ, Timmer J, Schmidt B, Czosnyka M, Weiller C, Hetzel A (2010). Secondary decline of cerebral autoregulation is associated with worse outcome after intracerebral hemorrhage. Intensive Care Med 36(2):264-71, 2010 Oeinck M, Neunhoeffer F, Buttler K-J, Meckel S, Schmidt B, Czosnyka M, Weiller C and Reinhard M. Dynamic Cerebral Autoregulation in Acute Intracerebral Hemorrhage. Stroke. published online August 13, 2013;

18 Pfister D, Schmidt B, Smielewski P, Siegemund M, Strebel SP, Rüegg S, Marsch SCU, Pargger H, Steiner LA (2008). Intracranial Pressure in Patients with Sepsis. Acta Neurochir Suppl. 102:71-75 Schmidt B, Weinhold M, Czosnyka M, May SA, Steinmeier R, Klingelhöfer J (2008). Accuracy of non-invasive ICP assessment can be increased by an initial individual calibration. Acta Neurochir Suppl. 102: 49-52 Schmidt B, Klingelhöfer J, Perkes I, Czosnyka M (2009). Cerebral Autoregulatory Response Depends on the Direction of Change in Perfusion Pressure. J Neurotrauma. 26:1-6 Reinhard M, Neunhoeffer F, Gerds TA, Niesen WD, Buttler KJ, Timmer J, Schmidt B, Czosnyka M, Weiller C, Hetzel A (2010). Secondary decline of cerebral autoregulation is associated with worse outcome after intracerebral hemorrhage. Intensive Care Med 36(2):264-71 Maximilian Oeinck, Florian Neunhoeffer, Klaus-Juergen Buttler, Stephan Meckel, Bernhard Schmidt, Marek Czosnyka, Cornelius Weiller and Matthias Reinhard. Dynamic Cerebral Autoregulation in Acute Intracerebral Hemorrhage. Stroke. published online August 13, 2013;

19 S Flow diagram of the nICP procedure FV ABP nICP w  A * tcd + B
Signal data of current patient FV ABP nICP every 10 Seconds ICPj = ABPj-k * wk k=0 S n weight function ABP ® ICP w = (w0, w1, ..., wn) TCD characteristics tcd = (tcd0, tcd1, ..., tcdm) w  A * tcd + B A (n+1) x (m+1) Matrix B n+1-dim. Vektor (A,B) : nICP Matrix, (n+1) x (m+2) Dim

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