Indian Journal of Radiology Indian Journal of Radiology  

   Login   | Users online: 861

Home Bookmark this page Print this page Email this page Small font sizeDefault font size Increase font size     

 

 Table of Contents    
TECHNICAL NOTES  
Year : 2020  |  Volume : 30  |  Issue : 3  |  Page : 372-375
Radiological aspects of CO2peripheral DSA: Preliminary analysis on the dedicated protocols


1 O.U. Medical Physics, University of Bologna, Viale Berti Pichat 6/2, 40124 Bologna; Experimental, Diagnostic and Specialty Medicine Department, University of Bologna, Via Massarenti 9, 40138 Bologna, Italy
2 Medical Physics Unit, Istituto Scientifico Romagnolo per lo Studio e la Cura dei Tumori IRCCS, Meldola, FC, Italy
3 Experimental, Diagnostic and Specialty Medicine Department, University of Bologna, Via Massarenti 9, 40138 Bologna, Italy

Click here for correspondence address and email

Date of Submission12-Apr-2020
Date of Acceptance18-Aug-2020
Date of Web Publication15-Oct-2020
 

   Abstract 


Objectives: Thanks to its lack of allergic reactions and renal toxicity, CO2represents an alternative to iodine as a contrast medium for peripheral subtraction angiography. Since CO2has a lower and negative contrast than iodine, postprocessing DSA and stacking are mandatory. So, it seems that higher doses than traditional iodine angiography are required. We addressed the dosimetric aspects of CO2angiography for two different commercial DSA-apparatus. Materials and Methods: Two different radiological suites were analyzed by recreating the same setup on all the apparatuses: we used a PMMA slabs phantom with a MPD Barracuda dosimeter on its side to collect all radiological parameters. Results: Results show that the irradiation parameters were left completely unchanged between the traditional and CO2angiographic programs. Conclusions: This leads to thinking that these CO2protocols do not operate on the X-ray emission, but only differ on image manipulation. The possibility of improvements by changing radiological parameters are still not explored and really promising.

Keywords: Carbon dioxide contrast medium; digital subtraction angiography; X-ray spectrum

How to cite this article:
Rossi PL, Bianchini D, Lombi A, Sapignoli S, Zanzi M, Corazza I. Radiological aspects of CO2peripheral DSA: Preliminary analysis on the dedicated protocols. Indian J Radiol Imaging 2020;30:372-5

How to cite this URL:
Rossi PL, Bianchini D, Lombi A, Sapignoli S, Zanzi M, Corazza I. Radiological aspects of CO2peripheral DSA: Preliminary analysis on the dedicated protocols. Indian J Radiol Imaging [serial online] 2020 [cited 2020 Oct 26];30:372-5. Available from: https://www.ijri.org/text.asp?2020/30/3/372/298200



   Introduction Top


The increasing of number and complexity of radiological medical procedures[1],[2],[3] start to involve patients with serious clinical conditions, such as renal impairment and allergies to iodinated contrast medium (CM),[1],[3],[4],[5],[6] introducing the necessity to study the performance and usage of alternative contrast mediums during interventional procedure, such as carbon dioxide (CO2).

The biomechanical aspects involved in CO2 angiography were previously studied, with great attention on gas flow control and possible damages at the vessel walls during the gas injection[7],[8] and the possibility to simulate operative conditions.[9]

In fact, the visualization of a gas inside a vessel requires different considerations if compared with typical liquid CM (i.e., iodine contrast medium). While iodine mixes with blood, full-fills the vessel and has a k-edge absorption peak at photon energy of 33.2 keV, CO2 is inflated into the vessel in form of “moving bubbles” with a negative contrast[4],[6],[10] without any edge absorption in the linear attenuation coefficient curve.

Furthermore, the CO2 is 400 times less viscous than iodine: this characteristic is a great advantage for angiographies not only as it allows the quick injection of large volumes of the gas through very small catheters, but it also allows CO2 to pass through small vessels, visualize tight stenosis and collaterals, and small bleeding.

Moreover, inflated CO2 cannot completely displace the blood and runs along the anterior part of the vessel, potentially underestimating the diameter of a vessel and introducing a nonoptimal contrast due to the incorrect fill. The gas buoyancy may also cause preferential filling of some branches, based on patient positioning. It is therefore fundamental to choose carefully the patient's position or change it during the procedure.

The aim of this work was to study the radiological aspects of the procedures, analyzing different fluoroscopy equipments and their automatic irradiation conditions when CO2 protocols are used, in particular analyzing if these differences are stressed to optimize imaging in CO2-peripheral DSA.


   Materials and Methods Top


To study the irradiation parameters applied during CO2 protocols, we worked on two fluoroscopy suites from different manufacturers [Ziehm VISION RFD, GE INNOVA GS - [Figure 1] and [Table 1], used for peripheral DSA CO2-angiography. We have chosen these two apparatuses because both ZIEHM and GE implement dedicated protocols for CO2 contrast medium: other manufacturers perform the DSA with the same program independently of the contrast medium used.
Figure 1: The fluoroscopic suites during the tests (from left to right: ZIEHM and GE)

Click here to view
Table 1: Specifications of the fluoroscopic suites

Click here to view


We are interested in investigating how different equipments perform fluoroscopy with DSA, in both traditional and CO2 specific program, to evaluate if implemented protocols are optimized or not.

The inspected equipments operate in pulsed-mode, allowing the operator to choose the pulse rate (in frames per se cond). To analyze the behavior of different radiological suites, we have recreated the same set-up on all the apparatus: instead of patient, we used a PMMA slabs phantom (thickness of 12 cm), with a multipurpose MPD Barracuda dosimeter on its side to collect all parameters (such as kV, exposure time, dose rate waveforms). All radiological parameters are settled automatically by the automatic exposures control system.


   Results Top


Ziehm Vision RFD

On the Ziehm equipment, we measured the dose rate waveforms in DSA fluoroscopy with 25, 12.5, 8, and 4 frames per se cond and for both traditional and CO2 programs [Figure 2]. During the acquisition, all data (as kV, mA) are settled automatically and collected [Table 2].
Figure 2: Examples of dose rate waveforms for ZIEHM (25 fps, iodine protocols and CO2protocols)

Click here to view
Table 2: Comparisons between protocols for ZIEHM

Click here to view


GE Innova IGS

The same measurements were performed on the GE equipment with pulse rates of 7.5 and 4 frames per se cond. The dose-rate waveforms for the traditional DSA fluoroscopy and for the CO2 specific program are shown in [Figure 3].
Figure 3: Examples of dose rate waveforms for GE Innova (7.5 fps, iodine protocols and CO2protocols)

Click here to view


As in the Ziehm equipment, even here we found no actual difference between the traditional DSA and the CO2 DSA programs. In this case, however, the emission parameters changed for different pulse rates [Table 3]. As for the previous apparatus, no clear phases can be seen in the waveforms, thus the mask image is acquired at the selected pulse rate.
Table 3: Comparisons between protocols for GE Innova

Click here to view



   Conclusions Top


Results show that the irradiation parameters were left completely unchanged between the traditional and CO2 angiographic programs. This leads to thinking that these CO2 protocols do not operate on the X-ray emission but only differ on image manipulation level to enhance contrast.

These measures disprove the hypothesis that, on currently employed equipment, CO2 angiography is intrinsically more dose-heavy than traditional DSA, as described by authors. The only parameter that could lead to an actual increment of the patient dose is an augmented fluoroscopy time, probably due to the clinical staff's lack of experience with CO2 injection and its technical difficulties, therefore requiring multiple repetitions during the acquisition.

During the tests, emission parameters are settled by the automatic exposure control system, and their choice is a trade-off between administered dose and image quality but optimized for traditional ICM. However, CO2 is quite different from traditional contrast media for both X-ray absorption characteristics, such as the absence of a K-edge, and for its dynamical and mechanical characteristics.

Moreover

  1. Emission spectra for DSA are traditionally set considering the use of iodinated contrast media, hence they try to maximize the emission at energies corresponding to a higher iodine-tissue contrast. Considering that CO2 does not have such limits, as it doesn't have a K-edge, and considering that modern flat panel detectors have wider dynamical ranges than traditional systems, higher tube voltages could be taken into consideration
  2. The frame rate and the pulse length became very important parameters to optimize images. Due to its physical properties, it seems to be advisable for CO2 DSA protocols a long pulse time, as the main interest did not lay in the imaging of the single bubble, but in obtaining an image of a contrail of bubbles, realized by averaging over the length of the pulse. Since modern fluoroscopes can perform complex image manipulations without significant time lag, new protocols could be taken into consideration. For example, we could evaluate whether acquiring with higher frame rates and shorter pulse lengths, and then stacking the resulting images, could give an interesting or better outcome. More complex stacking algorithms could be tested, e.g., a thresholded algorithm that emphasizes the bubble signal by adding where the signal exceeds a certain threshold, while averaging if it doesn't
  3. The transit of CO2 bubbles inside the vessels could be very fast, thus it might be captured in just a few of the images. In this case, a simple stacking of all the acquired photograms does not represent the best solution, and a selective addition of the interesting imaged would be advisable. This process could even be implemented as an automatic system, for example by selecting an ROI around the vessel and only stacking the images in which this ROI has a change of contrast
  4. An important consideration on patient dose should also be made. As already stated, the patient dose for diagnostic and interventional procedures should be kept as low as reasonably achievable, based on a careful risk-benefit evaluation. In some clinical cases, however, it is clear that the minimization of dose is secondary to the need of good angiographic images. This is the case of the growing number of senior patients with relatively short life expectancy, serious vascular diseases with a concrete risk of gangrene, and with risk factors for contrast medium nephrotoxicity. For such patients, CO2 DSA could be the only possibility of intervention, and therefore an eventual increase in administered dose would be negligible when compared to the clinical benefits


In conclusion, we believe that there is room for further researches and improvements on the choice of the optimal emission parameters for CO2 DSA.

Financial support and sponsorship

Nil.

Conflicts of interest

There are no conflicts of interest.



 
   References Top

1.
Persson PB, Hansell P, Liss P. Pathophysiology of contrast medium-induced nephropathy. Kidney Int 2005;68:14-22.  Back to cited text no. 1
    
2.
Goodney PP, Tarulli M, Faerber AE, Schanzer A, Zwolak RM. Fifteen-year trends in lower limb amputation, revascularization, and preventive measures among medicare patients. JAMA Surg 2015;150:84-6.  Back to cited text no. 2
    
3.
Stacul F, van der Molen AJ, Reimer P, Webb JAW, Thomsen HS, Morcos SK, et al. Contrast induced nephropathy: Updated ESUR Contrast Media Safety Committee guidelines. Eur Radiol 2011;21:2527-41.  Back to cited text no. 3
    
4.
Hawkins IF, Wilcox CS, Kerns SR, Sabatelli FW. CO2 digital angiography: A safer contrast agent for renal vascular imaging? Am J Kidney Dis Off J Natl Kidney Found 1994;24:685-94.  Back to cited text no. 4
    
5.
Moresco KP, Patel NH, Namyslowski Y, Shah H, Johnson MS, Trerotola SO. Carbon dioxide angiography of the transplanted kidney: Technical considerations and imaging findings. AJR Am J Roentgenol 1998;171:1271-6.  Back to cited text no. 5
    
6.
Shaw DR, Kessel DO. The current status of the use of carbon dioxide in diagnostic and interventional angiographic procedures. Cardiovasc Intervent Radiol 2006;29:323-31.  Back to cited text no. 6
    
7.
Corazza I, Rossi PL, Feliciani G, Pisani L, Zannoli S, Zannoli R. Mechanical aspects of CO2 angiography. Phys Med. 2013;29(1):33–8.  Back to cited text no. 7
    
8.
Zannoli R, Bianchini D, Rossi PL, Caridi JG, Corazza I. Understanding the basic concepts of CO2 angiography. J Appl Phys. 2016;120(19).  Back to cited text no. 8
    
9.
Corazza I, Sapignoli S, Cercenelli L, Marcelli E, Faggioli G, Gargiulo M, Stella A, Diemberger I, Rossi PL, Zannoli R. Automated CO2 angiography: Injection pressure and volume settings. Med Eng Phys. 2020;80:65-71. doi: 10.1016/j.medengphy.2020.03.007.  Back to cited text no. 9
    
10.
Bianchini D, Rossi PL, Feliciani G, Lombi A, Corazza I, Zannoli R. Carbon dioxide angiography: Simulation of operative conditions for diagnostic image optimization. J Mech Med Biol. 2015;15(2).  Back to cited text no. 10
    

Top
Correspondence Address:
Dr. Ivan Corazza
Experimental, Diagnostic and Specialty Medicine Department, University of Bologna, Via Massarenti 9, 40138 Bologna
Italy
Login to access the Email id

Source of Support: None, Conflict of Interest: None


DOI: 10.4103/ijri.IJRI_247_20

Rights and Permissions


    Figures

  [Figure 1], [Figure 2], [Figure 3]
 
 
    Tables

  [Table 1], [Table 2], [Table 3]



 

Top
 
 
  Search
 
   Similar in PUBMED
   Search Pubmed for
   Search in Google Scholar for
 Related articles
    Email Alert *
    Add to My List *
* Registration required (free)  


    Abstract
   Introduction
    Materials and Me...
   Results
   Conclusions
    References
    Article Figures
    Article Tables

 Article Access Statistics
    Viewed59    
    Printed0    
    Emailed0    
    PDF Downloaded2    
    Comments [Add]    

Recommend this journal