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ClarityIQ technology

Industry leading image quality at a fraction of the dose 1-37, f

 
Superb image quality and low X-ray dose come together with ClarityIQ and Azurion. Our clinically proven ClarityIQ technology combines advanced, real-time image processing algorithms with state-of-the-art hardware. This unlocks superb visualization and significant dose reduction capabilities. ClarityIQ is available on Azurion systems.

Demonstrated results

Up to 75% patient dose reduction in interventional cardiology

 

Compared to a system without ClarityIQ, up to 75% patient dose reduction in interventional cardiology procedures can be achieved while maintaining image quality.6, a, b In this clinical area, 16 studies were performed with 11,629 patients worldwide.1-16

Up to 83% patient dose reduction in interventional radiology

 

Compared to a system without ClarityIQ, up to 83% patient dose reduction can be achieved in interventional radiology procedures while maintaining image quality.33, a, c In this clinical area, 18 studies were performed with 6,167 patients worldwide.17-34

 

Up to 75% patient dose reduction in interventional neuroradiology

 

Compared to a system without ClarityIQ, up to 75% patient dose reduction can be achieved in interventional neuroradiology procedures while maintaining image quality.36, a, d In this clinical area, 3 studies were performed with 1,872 patients worldwide.35-37

Features

Clinician views  clinical images on screen in the control room

Clinically proven technology


Significantly lower radiation dose for patients at equivalent image quality. ClarityIQ is clinically proven to deliver significantly lower dose - based on 37 peer-reviewed clinical studies with over 19,000 patients.1-37, e Depending on the clinical area, dose reductions between 23% and 83% have been achieved.7, 33

Clinicians in the exam room performing a PCI procedure using Azurion with ClarityIQ

Validated reduction in staff and scatter radiation exposure


ClarityIQ technology touches every part of the Azurion imaging chain, from tube to display, to dramatically reduce X-ray dose, including reductions in staff 15,29 or scatter 33 exposure. Its powerful image processing drives this dramatic step forward in X-ray dose reduction without sacrificing IQ.1-37, f

Low dose vasculature image acquired via  Azurion Image-guided therapy system with ClarityIQ technology

Powerful image processing technology


ClarityIQ Image processing works in real-time, enabled by the latest computing technology. It uses the following powerful image processing technology: Real-time Pixel shift (P) with Automatic Motion Control, Motion compensation (M), Noise reduction (N) and Image enhancement (I). Image processing enhances image quality without increasing patient dose. ClarityIQ image processing enables usage for any clinical domain and patient size.

Clinicians in the exam room performing a PCI procedure using Azurion with ClarityIQ

Investigation of differences in radiation dose related to image quality for interventional fluoroscopy systems


This study identifies differences between image-guided therapy systems from different vendors. Philips interventional fluoroscopy system shows lower radiation use and higher subjective perception of image quality in multi-vendor study.25

Unlimited imaging flexibility

Azurion 7 C20 with FlexArm

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References

 

1. Balter, S., et al., Novel radiation dose reduction fluoroscopic technology facilitates chronic total occlusion percutaneous coronary interventions. EuroIntervention, 2017.13(12): p. e1468-e1474.

2. Bracken, J.A., et al., A Radiation Dose Reduction Technology to Improve Patient Safety During Cardiac Catheterization Interventions. J Interv Cardiol, 2015. 28(5): p. 493-7.

3. Busse, T., J. Reifart, and N. Reifart, Influence of novel X-ray imaging technology on radiation exposure during chronic total occlusion procedures. Catheter CardiovascInterv, 2018. 92(7): p. 1268-1273.

4. Buytaert, D., et al., Evaluation of patient and staff exposure with state of the art x ray technology in cardiac catheterization: A randomized controlled trial. Journal of Interventional Cardiology, 2018. 31(6): p. 807-814.

5. ten Cate, T., et al., Novel X-ray image noise reduction technology reduces patient radiation dose while maintaining image quality in coronary angiography. Netherlands Heart Journal, 2015. 23(11): p. 525-530.

6. Eloot, L., et al., Novel X-ray imaging technology enables significant patient dose reduction in interventional cardiology while maintaining diagnostic image quality. Catheter Cardiovasc Interv, 2015. 86(5): p. E205-12.

7. Faroux, L., et al., Minimizing exposure to radiation in invasive cardiology using modern dose-reduction technology: Evaluation of the real-life effects. Catheter Cardiovasc Interv, 2018. 91(7): p. 1194-1199.

8. Gunja, A., et al., Image noise reduction technology reduces radiation in a radial-first cardiac catheterization laboratory. Cardiovascular Revascularization Medicine, 2017. 18(3): p. 197-201

9. Kastrati, M., et al., Reducing Radiation Dose in Coronary Angiography and Angioplasty Using Image Noise Reduction Technology. Am J Cardiol, 2016. 118(3): p. 353-6.

10. Nakamura, S., et al., Patient radiation dose reduction using an X-ray imaging noise reduction technology for cardiac angiography and intervention. HeartVessels, 2015.

11. Gislason-Lee, A.J., et al., Impact of latest generation cardiac interventional X-ray equipment on patient image quality and radiation dose for trans-catheter aortic valve implantations. Br J Radiol, 2016. 89(1067): p. 20160269.

12. Haas, N.A., et al., Substantial radiation reduction in pediatric and adult congenital heart disease interventions with a novel X-ray imaging technology. IJC Heart & Vasculature, 2015. 6: p. 101-109.

13. Lauterbach, M. and K.E. Hauptmann, Reducing Patient Radiation Dose With Image Noise Reduction Technology in Transcatheter Aortic Valve Procedures. The American Journal of Cardiology, 2016. 117(5): p. 834-838.

14. Sullivan, P.M., et al., Reduction in Radiation Dose in a Pediatric Cardiac Catheterization Lab Using the Philips AlluraClarity X-ray System. Pediatric Cardiology, 2017. 38(8): p. 1583-1591.

15. Dekker, L.R., et al., New image processing and noise reduction technology allows reduction of radiation exposure in complex electrophysiologic interventions while maintaining optimal image quality: a randomized clinical trial. Heart Rhythm, 2013. 10(11): p. 1678-82.

16. van Dijk, J.D., et al., Impact of new X-ray technology on patient dose in pacemaker and implantable cardioverter defibrillator (ICD) implantations. J Interv Card Electrophysiol, 2017. 48(1): p. 105-110.

17. Dave, J.K., et al., A Phantom Study and a Retrospective Clinical Analysis to Investigate the Impact of a New Image Processing Technology on Radiation Dose and Image Quality during Hepatic Embolization. Journal of Vascular and Interventional Radiology, 2016. 27(4): p. 593-600.

18. Durrani, R.J., et al., Radiation dose reduction utilizing noise reduction technology during uterine artery embolization: a pilot study. Clinical Imaging, 2016. 40(3): p. 378-381.

19. Kohlbrenner, R., et al., Patient Radiation Dose Reduction during Transarterial Chemoembolization Using a Novel X-Ray Imaging Platform. Journal of Vascular and Interventional Radiology, 2015. 26(9): p. 1331-1338.

20. Schernthaner, R.E., et al., A new angiographic imaging platform reduces radiation exposure for patients with liver cancer treated with transarterial chemoembolization. European radiology, 2015. 25(11): p. 3255-3262.

21. Schernthaner, R.E., et al., Characteristics of a New X-Ray Imaging System for Interventional Procedures: Improved Image Quality and Reduced Radiation Dose. Cardiovasc Intervent Radiol, 2018. 41(3): p. 502-508.

22. Spink, C., et al., Noise reduction angiographic imaging technology reduces radiation dose during bronchial artery embolization. European Journal of Radiology, 2017. 97: p. 115-118.

23. Spink, C., et al., Radiation dose reduction during transjugular intrahepatic portosystemic shunt implantation using a new imaging technology. European Journal of Radiology, 2017. 86: p. 284-288.

24. Thomaere, E., et al., A new imaging technology to reduce the radiation dose during uterine fibroid embolization. Acta Radiol, 2018. 59(12): p. 1446-1450.

25. Trunz, L.M., et al., Investigation of Radiation Dose Estimates and Image Quality Between Commercially Available Interventional Fluoroscopy Systems for Fluoroscopically Guided Interventional Procedures. Acad Radiol, 2021. 28(11): p. 1559-1569.

26. Wen, X., et al., Novel X-Ray Imaging Technology Allows Substantial Patient Radiation Reduction without Image Quality Impairment in Repetitive Transarterial Chemoembolization for Hepatocellular Carcinoma. Academic Radiology, 2015. 22(11): p. 1361-1367.

27. Alsafi, A., et al., Adrenal Vein Sampling: Radiation Dose Reduction on New Angiography Platform. The Arab Journal of Interventional Radiology, 2020. 4(02): p.102-106.

28. Baumann, F., et al., The Effect of a New Angiographic Imaging Technology on Radiation Dose in Visceral Embolization Procedures. Vasc Endovascular Surg, 2017.51(4): p. 183-187.

29. van den Haak, R.F., et al., Significant Radiation Dose Reduction in the Hybrid Operating Room Using a Novel X-ray Imaging Technology. Eur J Vasc Endovasc Surg, 2015. 50(4): p. 480-6.

30. Kirkwood, M.L., et al., New image-processing and noise-reduction software reduces radiation dose during complex endovascular procedures. Journal of Vascular Surgery, 2016. 64(5): p. 1357-1365.

31. de Ruiter, Q.M., et al., AlluraClarity Radiation Dose-Reduction Technology in the Hybrid Operating Room During Endovascular Aneurysm Repair. J Endovasc Ther, 2016. 23(1): p. 130-8.

32. Stangenberg, L., et al., Modern Fixed Imaging Systems Reduce Radiation Exposure to Patients and Providers. Vasc Endovascular Surg, 2018. 52(1): p. 52-58.

33. van Strijen, M.J., et al., Evaluation of a Noise Reduction Imaging Technology in Iliac Digital Subtraction Angiography: Noninferior Clinical Image Quality with Lower Patient and Scatter Dose. Journal of Vascular and Interventional Radiology, 2015. 26(5): p. 642-650.e1.

34. Strauss, K.J., et al., Estimates of diagnostic reference levels for pediatric peripheral and abdominal fluoroscopically guided procedures. AJR Am J Roentgenol, 2015. 204(6): p. W713-9.

35. van der Marel, K., et al., Reduced Patient Radiation Exposure during Neurodiagnostic and Interventional X-Ray Angiography with a New Imaging Platform. AJNR Am J Neuroradiol, 2017. 38(3): p. 442-449.

36. Söderman, M., et al., Image noise reduction algorithm for digital subtraction angiography: clinical results. Radiology, 2013. 269(2): p. 553-60.

37. Söderman, M., et al., Radiation dose in neuroangiography using image noise reduction technology: a population study based on 614 patients. Neuroradiology, 2013. 55(11): p. 1365-1372.

 

Footnotes

 

a. The results of the application of dose reduction techniques will vary depending on the clinical task, patient size, anatomical location and clinical practice. The interventional radiologist assisted by a physicist as necessary has to determine the appropriate settings for each specific clinical task.

b. Results based on total dose area product from a single center prospectively randomized cohort study on 70 consecutive patients (35 for Allura Xper without ClarityIQ and 35 for Allura Xper with ClarityIQ). Number of cine images and contrast medium did not significantly differ between the two cohorts, while fluoroscopy time was significantly higher for the ClarityIQ group. Image quality was based on subjective assessment of two cine runs selected from each patient in two specific projections. Ratings for image contrast, resolution and general appearance were not statistically different. Image noise was more apparent for ClarityIQ images.

c. Results based on DSA dose area product per frame from a single center prospective randomized study on 48 patients. DSA runs for Allura Xper with ClarityIQ and Allura Xper without ClarityIQ were randomly acquired on the same patient under same condition of geometry, field of view and injection protocol. Image quality was based on subjective assessment (side-by-side, equal or superior than the other, blinded review by 5 independent radiologists).

d. Results based on DSA dose area product per frame from a single center prospective study on 20 patients. DSA runs for Allura Xper with ClarityIQ and Allura Xper without ClarityIQ were acquired on the frontal and lateral channel on the same patient under same condition of geometry, field of view and injection protocol. Image quality was based on subjective assessment (score 1-5, 1=very poor, 5=excellent, blinded review by 3 radiologists involved in the study).

e. Patient age (when reported) ranged between 0 days – 92 years. Patient weight (when reported) ranged between 1.6-135 kg. Patient BMI (when reported) ranged between 5-41 kg/m2.

f. In 37 individual comparative studies, Philips ClarityIQ was associated with reductions in patient radiation exposure.

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