PDF icon Download PDF
Ultraschall Med 2009; 30(1): 37-41
DOI: 10.1055/s-2008-1027188
Original Article

© Georg Thieme Verlag KG Stuttgart · New York

Does Routine Transcranial Duplex Ultrasound Heat Up the Patient Brain?

Hirnerwärmung durch transkraniellen Routine Duplex-Ultraschall?H.-G Schlosser1 , F. Doepp2 , C. H. Nolte2 , M. Brock1 , S. J. Schreiber2
  • 1Department of Neurosurgery, Charité – Universitätsmedizin Berlin, Campus Virchow Klinikum (CVK)
  • 2Department of Neurology, Charité – Universitätsmedizin Berlin, Campus Charité Mitte (CCM)
Further Information

Publication History

received: 9.10.2007

accepted: 24.12.2007

Publication Date:
21 May 2008 (online)

Also available ateRefMedOne
   Permissions and Reprints
Preview

Zusammenfassung

Ziel: Der Anstieg der Hirngewebetemperatur bei transkraniellen Ultraschallanwendungen (US) ist als mögliche Gefahr für den Patienten beschrieben worden. Hierfür liegen jedoch keine Studien am Menschen, sondern lediglich an verschiedenen Modellen vor. Der Effekt des trankraniellen Duplex-Ultraschalls bei der Routineuntersuchung auf die intraventrikuläre Temperatur bei Patienten wurde untersucht. Material und Methoden: Patienten, die eine intrakranielle Druck- und Temperatursonde implantiert hatten und US untersucht wurden, werden eingeschlossen. In einer Untersuchungsserie (B-mode-, B- und Color-mode-, B- und Color-mode-plus-Doppler; jeweils für drei Minuten) wird der intrakranielle Thermistor der Messsonde fokussiert, während die intraventrikuläre Temperatur und die Körpertemperatur kontinuierlich (über Blasenkatheter oder rektal) gemessen werden. Die Temperaturänderungen werden analysiert. Ergebnisse: Bei 14 Patienten wurden 31 US durchgeführt. Für die Auswertung wurden 26 US bei 9 Patienten, bei denen die Temperatursonde dargestellt werden konnte, berücksichtigt. Die initialen Körpertemperaturen lagen zwischen 35,1 bis 38,7 °C. Es wurden keine signifikanten Temperaturänderungen während der ersten (B-mode), zweiten (B- und color) und dritten (b- und color plus Doppler) US gesehen. Der T-Test zeigte eine konstante Temperatur während der US (zweiseitige Signifikanz: 1,000; 1,000; 0,0731). Schlussfolgerung: Der transkranielle Routine-US erhöht die Hirntemperatur der Patienten nicht.

Abstract

Purpose: The effect of transcranial duplex ultrasound (US) on the intraventricular temperature in patients was analyzed. Temperature increases during examination have been identified as a potential risk factor but only data from model studies is currently available. Materials and Methods: Patients who had an intracranial pressure/temperature transducer implanted and underwent US assessment were included. In an examination series (B-mode, combined B- and color mode, combined B- and color mode plus Doppler, 3 min for each mode), the intracranial thermodilution thermistor was focused while intraventricular temperature and body temperature (bladder catheter or rectal probe) were recorded continuously and temperature changes were analyzed. Results: Thirty-one US examinations were performed in 14 patients. Twenty-six examinations in 9 patients in which the intracranial temperature probe was depicted were included. Initial patient temperatures ranged from 35.1dgC to 38.7dgC. No significant increase or decrease in intracranial temperature was seen after the first (B-mode), second (B- and color mode) and third (B- and color mode plus Doppler) duplex US examination. T-test for paired samples showed a constant temperature throughout US examination (two-sided significance: 1.000, 1.000, 0.731). Conclusion: Routine transcranial duplex ultrasound does not increase the intracranial temperature in patients.

Key words

ultrasonography - doppler - transcranial - safety

References

  • 1 Barnett S B, Maulik D. Guidelines and recommendations for safe use of Doppler ultrasound in perinatal applications.  J Matern Fetal Med. 2001;  10 75-84
    Search in Google Scholar
  • 2 Whittingham T A. WFUMB Safety Symposium on Echo-Contrast Agents: exposure from diagnostic ultrasound equipment relating to cavitation risk.  Ultrasound Med Biol. 2007;  33 214-223
    Search in Google Scholar
  • 3 Barnett S B. Intracranial temperature elevation from diagnostic ultrasound.  Ultrasound Med Biol. 2001;  27 883-888
    Search in Google Scholar
  • 4 Whittingham T A. Estimated fetal cerebral ultrasound exposures from clinical examinations.  Ultrasound Med Biol. 2001;  27 877-82
    Search in Google Scholar
  • 5 Ziskin M C, Barnett S B. Ultrasound and the developing central nervous system.  Ultrasound Med Biol. 2001;  27 875-6
    Search in Google Scholar
  • 6 Barnett S B, ter Haar G R, Ziskin M C. et al . Current status of research on biophysical effects of ultrasound.  Ultrasound Med Biol. 1994;  20 205-218
    Search in Google Scholar
  • 7 Connor C W, Hynynen K. Patterns of thermal deposition in the skull during transcranial focused ultrasound surgery.  IEEE Trans Biomed Eng. 2004;  51 1693-1706
    Search in Google Scholar
  • 8 Wu J, Cubberley F, Gormley G. et al . Temperature rise generated by diagnostic ultrasound in a transcranial phantom.  Ultrasound Med Biol. 1995;  21 561-568
    Search in Google Scholar
  • 9 Sekoranja L, Loulidi J, Yilmaz H. et al . Intravenous versus combined (intravenous and intra-arterial) thrombolysis in acute ischemic stroke: a transcranial color-coded duplex sonography – guided pilot study.  Stroke. 2006;  37 1805-1809
    Search in Google Scholar
  • 10 Schneider F, Gerriets T, Walberer M. et al . Brain edema and intracerebral necrosis caused by transcranial low-frequency 20-kHz ultrasound: a safety study in rats.  Stroke. 2006;  37 1301-1306
    Search in Google Scholar
  • 11 Molina C A. Monitoring and imaging the clot during systemic thrombolysis in stroke patients.  Expert Rev Cardiovasc Ther. 2007;  5 91-98
    Search in Google Scholar
  • 12 Martini S R, Hill M D, Alexandrov A V. et al . Outcome in hyperglycemic stroke with ultrasound-augmented thrombolytic therapy.  Neurology. 2006;  67 700-702
    Search in Google Scholar
  • 13 Molina C A, Ribo M, Rubiera M. et al . Microbubble administration accelerates clot lysis during continuous 2-MHz ultrasound monitoring in stroke patients treated with intravenous tissue plasminogen activator.  Stroke. 2006;  37 425-429
    Search in Google Scholar
  • 14 Eggers J. Acute stroke: therapeutic transcranial color duplex sonography.  Front Neurol Neurosci. 2006;  21 162-170
    Search in Google Scholar
  • 15 Demchuk A M, Saqqur M, Alexandrov A V. Transcranial Doppler in acute stroke.  Neuroimaging Clin N Am. 2005;  15 473-480, ix
    Search in Google Scholar
  • 16 Sakharov D V, Hekkenberg R T, Rijken D C. Acceleration of fibrinolysis by high-frequency ultrasound: the contribution of acoustic streaming and temperature rise.  Thromb Res. 2000;  100 333-340
    Search in Google Scholar
  • 17 Alexandrov A V, Molina C A, Grotta J C. et al . Ultrasound-enhanced systemic thrombolysis for acute ischemic stroke.  N Engl J Med. 2004;  351 2170-2178
    Search in Google Scholar
  • 18 Eggers J, Seidel G, Koch B. et al . Sonothrombolysis in acute ischemic stroke for patients ineligible for rt-PA Ultrasound-enhanced systemic thrombolysis for acute ischemic stroke. Acceleration of fibrinolysis by high-frequency ultrasound: the contribution of acoustic streaming and temperature rise.  Neurology. 2005;  64 1052-1054
    Search in Google Scholar
  • 19 Barnett S B. Current status of safety of diagnostic ultrasound.  Hosp Med. 2001;  62 726-727
    Search in Google Scholar
  • 20 Nakagawa K, Ishibashi T, Matsushima M. et al . Does long-term continuous transcranial Doppler monitoring require a pause for safer use?.  Cerebrovasc Dis. 2007;  24 27-34
    Search in Google Scholar
  • 21 Rott H. Clinical safety statement for diagnostic ultrasound. European Committee for Medical Ultrasound Safety, Tours, France, March 1998.  Eur J Ultrasound. 1998;  8 67-68
    Search in Google Scholar
  • 22 Krejza J, Weigele J B, Alokaili R. et al . Sonothrombolysis in acute ischemic stroke for patients ineligible for rt-PA.  Neurology. 2006;  66 154-155; author reply 154 – 155
    Search in Google Scholar
  • 23 WFUMB Symposium on Safety and Standardisation in Medical Ultrasound . Issues and Recommendations Regarding Thermal Mechanisms for Biological Effects of Ultrasound. Hornbaek, Denmark, 30 August-1 September 1991.  Ultrasound Med Biol. 1992;  18 731-810
    Search in Google Scholar
  • 24 Duggan P M, Murcott M F, McPhee A J. et al . The influence of variations in blood flow on pulsed doppler ultrasonic heating of the cerebral cortex of the neonatal pig.  Ultrasound Med Biol. 2000;  26 647-654
    Search in Google Scholar
  • 25 Horder M M, Barnett S B, Vella G J. et al . Ultrasound-induced temperature increase in the guinea-pig fetal brain in vitro.  Ultrasound Med Biol. 1998;  24 697-704
    Search in Google Scholar
  • 26 Horder M M, Barnett S B, Vella G J. et al . Ultrasound-induced temperature increase in guinea-pig fetal brain in utero: third-trimester gestation.  Ultrasound Med Biol. 1998;  24 1501-1510
    Search in Google Scholar
  • 27 Horder M M, Barnett S B, Vella G J. et al . In vivo heating of the guinea-pig fetal brain by pulsed ultrasound and estimates of thermal index.  Ultrasound Med Biol. 1998;  24 1467-1474
    Search in Google Scholar
  • 28 Horder M M, Barnett S B, Vella G J. et al . Effects of pulsed ultrasound on sphenoid bone temperature and the heart rate in guinea-pig foetuses.  Early Hum Dev. 1998;  52 221-233
    Search in Google Scholar
  • 29 Mariak Z, Krejza J, Swiercz M. et al . Human brain temperature in vivo: lack of heating during color transcranial Doppler ultrasonography.  J Neuroimaging. 2001;  11 308-312
    Search in Google Scholar
  • 30 Marshall I, Karaszewski B, Wardlaw J M. et al . Measurement of regional brain temperature using proton spectroscopic imaging: validation and application to acute ischemic stroke.  Magn Reson Imaging. 2006;  24 699-706
    Search in Google Scholar
  • 31 Karaszewski B, Wardlaw J M, Marshall I. et al . Measurement of brain temperature with magnetic resonance spectroscopy in acute ischemic stroke.  Ann Neurol. 2006;  60 438-446
    Search in Google Scholar
  • 32 Senneville B D, Mougenot de C, Quesson B. et al . MR thermometry for monitoring tumor ablation.  Eur Radiol. 2007;  17 2401-2410
    Search in Google Scholar
  • 33 Vimeux F C, De Zwart J A, Palussiere J. et al . Real-time control of focused ultrasound heating based on rapid MR thermometry.  Invest Radiol. 1999;  34 190-193
    Search in Google Scholar
  • 34 Pernot M, Aubry J F, Tanter M. et al . High power transcranial beam steering for ultrasonic brain therapy.  Phys Med Biol. 2003;  48 2577-2589
    Search in Google Scholar
  • 35 Moonen C T. Spatio-temporal control of gene expression and cancer treatment using magnetic resonance imaging-guided focused ultrasound.  Clin Cancer Res. 2007;  13 3482-3489
    Search in Google Scholar
  • 36 Hynynen K. Focused ultrasound for blood-brain disruption and delivery of therapeutic molecules into the brain.  Expert Opin Drug Deliv. 2007;  4 27-35
    Search in Google Scholar

Dr. Hans-Georg Schlosser

Department of Neurosurgery, Charité – Universitätsmedizin Berlin, Campus Virchow Klinikum (CVK)

Augustenburger Platz 1

13353 Berlin

Phone: ++ 49/30/4 50 56 07 34

Fax: ++ 49/30/4 50 56 09 19

Email: hans-georg.schlosser@charite.de