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Dosimetric effects of bladder and rectal contrast agents in prostate radiotherapy

Published online by Cambridge University Press:  23 April 2013

Ian Gleeson*
Affiliation:
Division of Radiation Therapy, Trinity Centre for Health Sciences, Dublin, Ireland
*
Correspondence to: Ian Gleeson, Maidstone and Tunbridge Wells NHS Trust, Clinical Oncology, Kent Oncology Centre, Kent and Canterbury Hospital, Ethelbert Road, Canterbury, Kent, CT1 3NG, UK. Tel: 0044 7771482380. E-mail: [email protected]
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Abstract

Background and purpose

Accurate delineation of the target volume and organs at risk (OARs) are vital to ensure systematic errors are small. The use of contrast agents (CAs) in the bladder and rectum may aid contouring and reduce inter and intra-observer variability. The aim of this study was to evaluate the dosimetric effect of the presence of such contrast on the monitor units (MUs), planning target volume (PTV), rectum and bladder.

Materials and methods

The prostate, seminal vesicles, rectum and bladder were contoured by a single observer on ten patients with bladder and rectal contrast. To evaluate the dosimetric effect of the presence of contrast, the density of the ten patients with contrast in the bladder and rectum was virtually changed to 1 g/cm3. A four-field 15 MV conformal radiation therapy technique was applied in which dose volume histograms and MUs were compared using computed tomographic (CT) density and the 1 g/cm3 density.

Results

The presence of contrast resulted in a 0·09% (<1 MU) increase in anterior MUs and decrease of 1% (<1 MU) in the posterior beam MUs. Lateral beams were not affected. The PTV and bladder dose increased slightly without contrast. The rectum showed a maximum change of 0·62% dose among the measured dose values. A maximum dose of 0·3 Gy at the 30% volume was also seen.

Conclusions

The dosimetric effect of bladder and rectal CAs on MUs, dose to the PTV and OARs in using this technique was very small. This would not be clinically significant, but only if the extreme limits of dose volume constraints were being reached.

Type
Original Articles
Copyright
Copyright © Cambridge University Press 2013 

Introduction

There are many uncertainties in radiation therapy. These can relate to the volumes and targets outlined, patient positioning and reproducibility, movement during treatment, tumour and contour changes, planning algorithms, dose output fluctuations, imaging modalities and matching variations among observers. With conformal radiotherapy (CRT) and the increasing use of intensity modulated radiotherapy (IMRT) to treat prostate cancer, dose escalations and steep dose gradients require accurate definition of target volumes. Advances in online volumetric kilovoltage imaging have improved the delivery of radiation, however, if the contour is inadequately delineated the therapeutic ratio can still be compromised.

IMRT has allowed for dose escalation without increasing late toxicity and improve disease-free survival.Reference Teh, Woo and Woo1Reference Dearnaley, Sydes and Graham5 This also extends to the organs at risk (OARs). According to ICRU 506 the planning target volume (PTV) includes the set-up margin and internal margin but differences in delineation are not always considered. Factors that may affect the variability includes the imaging modality, slice thickness of computed tomography (CT), experience of observer, resolution and contrast, size of the structure and use of contrast agents (CAs).Reference Fiorino, Reni and Bolognesi7

CT appears to be most commonly used in treatment planning of the prostate despite the increased accuracy of magnetic resonance imaging (MRI) with less inter-observer variability.Reference Rasch, Barillot and Remeijer8Reference Rahmouni, Yang and Tempany11 CT provides volumetric information and electron density maps for dose calculations, but MRI has improved soft tissue contrast allowing for better definition of the apex as well as the rectal–prostate and bladder–prostate interfaces. MRI has been shown to consistently result in smaller prostate volumes and less variability in definition than CT. Thus, the CT apex and base were larger than on MRI and this may lead to increased dose to bladder, rectum and penile tissues.Reference Rasch, Barillot and Remeijer8, Reference Wachter, Wachter-Gerstner and Bock9, Reference Roach, Faillace-Akazawa and Malfatti12

Methods traditionally used to help improve the definition of these structures include the use of CA's, mostly retrograde urethrogram. Valicenti et al.Reference Valicenti, Sweet and Hauck13 showed a significant improvement with bladder contrast. It resulted in improved inter-observer reliability when contouring prostate volumes. Sharma et al.Reference Sharma, Duclos and Chuba14 went on to illustrate a dose disadvantage when bladder contrast was not used as the prostate bladder interface was difficult to distinguish without bladder contrast.

Rectal contrast

Few authors have studied the impact of rectal contrast. Accurate definition of the rectum will provide a ‘true’ dose volume histogram (DVH), which is more comparable between observers and radiotherapy centres. This will allow one to more accurately predict toxicity as studies have shown correlations between DVHs and rectal toxicity in prostate cancer.Reference Fiorino, Vavassori, Sanguineti and Bianchi15

Rectal contrast use is not standardised and Roach et al.Reference Lebesque, Bruce and Kroes16 suggests a nearly empty rectum with 15 cc of contrast to avoid changes in rectal volumes and prostate position. One studyReference Gao, Wilkins and Eapen17 examined the variability in prostate contouring on CT versus 1 mm anatomical photographs. An intra-observer variation of 2–8% SD and 18·8% was found among observers in relation to prostate volumes. A systematic error was found where observers missed an average of 2·8 mm of the prostate posteriorly and included more normal tissue anteriorly (average 5·8 mm). Although only performed on one patient, it indicates that there may be an uncertainty at the posterior aspect of the prostate. Inclusion of rectal contrast may provide the answer in limiting the systematic uncertainty by highlighting the anterior rectal wall.

Bladder and rectal contrast effect on dose

CAs mainly consist of higher atomic numbers (Z) which result in a change to the HUs and hence the electron densities used in calculations. This ‘misinterpretation’ of density may impact on the dose distribution and provide different DVHs and monitor units (MUs) than during treatment when CAs are not present.Reference Harvey and Blomley18 An initial systematic error may be introduced. The planned and delivered dose distribution can potentially differ and should be investigated and corrected for if significant.

When using CAs, the treatment planning system (TPS) accounts for them as high density tissues and higher attenuation for photon beams will be calculated. The MU calculations that a target volume requires for a given dose will also be distorted.Reference Ramm, Damrau and Mose19 Whether or not bladder and rectal contrast will significantly affect the dose distribution and calculation in prostate CRT is not well documented. Some studies have shown minimal change in doses mostly below 5% between contrast and non-contrast plans.Reference Weber, Rouzaud and Miralbell20Reference Burridge, Rowbottom and Burt24 Unfortunately, comparisons are difficult as most studies refer to phantoms and other sites.

Study aim

To investigate the dosimetric effect of rectal and bladder contrast on the PTV and OARs in DVHs using a 15 MV four-field box technique. It is hypothesised that an increase in MUs may be required to deliver the prescribed dose to the isocentre to account for the higher attenuation when contrast is present. This may increase the dose significantly to the PTV and OARs when there is no CA present during treatment.

Method

CT simulation

Ten patients with prostate cancer were assessed in this study whose CT scans were anonymous to the lead investigator. Information regarding the scanning procedures was provided by the radiotherapy department to the investigator. The ten patients had intravesical and rectal contrast. All the patients were positioned supine with ankle immobilisation and underwent a CT scan using a Philips ACQSim scanner (Philips Healthcare, the Netherlands). Patients were instructed to empty their bladders and drink ∼500 ml of water before the scans. For contrast patients, a rectal catheter was inserted with the aid of KY jelly and 5 ml of urograffin was inserted into the catheter.

Following the necessary hygiene procedures, an anaesthetic was injected into the urethra. A catheter was then inserted until it reached the bladder and 15 ml of urograffin were injected. The catheter was then retracted as far as the prostatic urethra and a further 5 ml injected. The catheter was then clamped into position. The amount of contrast used was considered adequate for optimal visualisation of the bladder, prostatic urethra and rectal outline particularly at the level of the prostate. The patients underwent their CT scans for definition of the required volumes. The patients had 3 mm slice scans as per the centres scanning protocol. All the CT data was then imported to the TPS Oncentra Masterplan Version 1.4.3.1 (OTP) by Nucletron (Veenendaal, The Netherlands) in the treatment planning laboratory. These CT datasets were anonymous to the lead investigator and were uploaded by the supervisor of this study.

Delineation

On the ten CT datasets, the bladder, seminal vesicles, prostate, rectum and femoral heads were contoured by the lead investigator. The structures contoured consisted of the following:

  • Rectum: the full rectum including contents was contoured from the recto-sigmoid junction to the anal canal.

  • Bladder: the external wall from dome to base.

  • Seminal vesicles: whole structure contoured separately.

  • Prostate: whole prostate from base to apex.

  • Femoral heads: included femoral neck and greater trochanter.

All the structures above were delineated on every slice using a mouse without any enhancing contrast tools or windowing. Only magnification was used.

Contrast impact on dose

Treatment plans were constructed to analyse the effect of rectal and bladder contrast on dose distributions. The clinical target volume (CTV) was the prostate only. The CTV was expanded by 0·5 cm posteriorly and 1 cm in the other dimensions to create the PTV. A dose of 74 Gy in 37 fractions, 2 Gy per fraction was prescribed to the 100% isodose, and the prescription point was placed at the geometric centre of the PTV. The prescription point was still checked to ensure that it was in an area that had a uniform tissue density within a 2 cm radius. None of the patients had prostate fiducial markers. The four-field box CRT plans were created with 15 MV only. The PTV was kept between 95% and 107% as per ICRU recommendations.6 Dose constraints in Gy for OARs used are listed in Table 1.

Table 1 OAR and DVC used in plans

Abbreviations: OAR, organs at risk; DVC, dose volume constraints.

To simulate a ‘non-contrast scan’ without rescanning the patient, the bulk density of the rectal and bladder volumes were adjusted to mimic tissue density. This was changed to 1 g/cm3. No other change was made to the plan, and the DVHs were compared from both plans. A pencil beam algorithm was used on all plans with a matrix resolution of 0·5 cm.

Plan analysis

Table 2 shows the dose and volumes used to compare the contrast and non-contrast scans.

Table 2 Contrast versus non-contrast dose comparisons

Abbreviations: PTV, planning target volume; MUs, monitor units.

Statistical analysis

All the recorded data were inputted into SPSS version 14 (SPSS Inc., Chicago, USA: now IBM). Paired t-tests performed evaluated whether the MUs, dose to the PTV, rectum and bladder differed significantly when the density was changed. The symbol * denotes a significant p-value (<0·05).

Results

Plan information

Table 3 shows descriptive statistics for the ten plans created with rectal and bladder contrast and for those when the contrast was given unit density.

Table 3 Mean and SD values for contrast and non-contrast plans

Note: *p < 0·05.

Abbreviation: PTV, planning target volume.

As expected, the MUs increased although not significantly by 0·09% (0·05) in the anterior beam, as the presence of the bladder contrast may have required more MUs to deliver the prescribed dose. This was, however, not replicated in the lateral fields which were very similar. The posterior beam gave a 1% (0·55 MU) increase in MU without contrast, and this was the maximum difference. These changes were not, however, statistically significantly different.

Although the minimum and mean PTV doses were statistically significantly higher without the contrast, this was only by an average of 0·94 Gy (1·3%) and 0·22 Gy (0·3%). The rectal dose did not differ statistically significantly with and without contrast except for the 30% volume dose. This was the largest, with an average increase of 0·3 Gy (0·57%) without the contrast.

The bladder showed a more consistent increase in dose when there was no contrast present than did the rectum. This was statistically significant for the maximum dose, 5% and 30% volume consisting of a dose increment of 0·46 Gy (0·6%), 0·72 Gy (0·98%) and 0·88 Gy (1·71%), respectively. Although the 50% volume was deemed not significant, the percentage dose increase without contrast was highest at 4·7% (Table 4).

Table 4 Mean MU and % dose difference (contrast – non-contrast)

Abbreviation: MU, monitor units.

Discussion

The aim of this study was to investigate the effect of rectal and bladder contrast on MUs, and dose to the PTV, rectum and bladder. The hypothesis was based on the fact that contrast material, being of higher Z, attenuates the photon beam to a greater extent and therefore the MUs required may be higher with contrast. As contrast is absent during treatment, the effect of this may have clinical implications. Ramm et al.Reference Ramm, Damrau and Mose19 showed that the effect of introducing contrast materials increased with the concentration, volume and depth of the contrast material. The CT numbers increased with the concentration, illustrating the problem created for the dose calculation. The density and attenuation were therefore overestimated. Here the study showed an increased effect with a 6 versus a 25 MV beam. It was concluded that only 1–3% in dose changes was likely, provided the contrast was <500 HU and <5 cm diameter. It was also discussed that additional beams may reduce the overall effect. In this study the dose differences were also minimal, as expected due to the small amount of contrast used and high-energy 15 MV beams.

The insignificant effect of the high Z contrast media in this study and others may highlight the fact that only ∼25% of X-ray interactions are dominated by the pair production effect at 15 MV.Reference Johns and Cunningham25 As compton interactions are accounting for the majority of MV attenuation in this study (∼75%), this is dependant on electron density and not the atomic number. It is the electron density of the contrast that is therefore of more importance at 15 MV. Most materials have similar numbers of electrons per gram (e/g) apart from hydrogen, so physical density (g/cm3) becomes more important.Reference Johns and Cunningham25 Therefore, at this therapeutic energy, contrast materials with their high Z numbers will not effect the total mass attenuation that much. Increasing the energy higher than 15 MV will increase the pair production interactions which are dependent on Z and thus the high Z contrast may have a greater effect on the calculated dose and MU. Energies above 15 MV are, however, not very common for prostate radiotherapy.

This study only deals with 15 MV four-field CRT plans. It was felt that 15 MV is a very common energy used for prostate CRT. A possible further comparison of contrast and no contrast on 6 MV IMRT on other sites also may be something worth considering. However, it is of the author's opinion that the effect would also likely be clinically insignificant due to the X-ray interactions mostly dominated by the compton effect and the small volume of contrast media used. Studies as shown in Table 5 have also demonstrated minimal effect.

Table 5 Review of the effect of contrast agents on dose calculations in radiotherapy

Abbreviations: ns, not clinically significant; MU, monitor units; PTV, planning target volume; OARs, organs at risk.

It was expected that an increase in the number of MUs would be required with contrast for the prescribed dose. This was true for the anterior beam which gave a very small increase of 0·05 MU (0·09%), but was unchanged in the lateral beams. The posterior beam required more MUs (mean 0·55) without contrast and this may be because of the presence of air in the rectum before the bulk density change. The anterior beam was likely more affected by the larger volume of contrast in the bladder and its proximity. The bulk density correction for the rectal volume included the full lumen and wall as contoured. This, however, may be an extreme scenario as the rectal contrast did not fully fill the rectum throughout all patients because of the small volume used. Individual beam MU changes were all minimal and <1% with a maximum change of 0·55 MU on the posterior beam.

Weber et al.Reference Weber, Rouzaud and Miralbell20 performed a similar study to the present one using bladder contrast only, 18 MV and a six-field technique. The total MU difference consisted of an average increase of 0·31 ± 0·52% with contrast with reported similar minimal changes in MU in the lateral beams. The dose to the prostate and rectum on average increased by 0·03% and 1·13%, respectively, when no contrast was used. The current study showed slight increases in the minimum, mean and maximum dose to the PTV without contrast. This was by 1·32% (0·94 Gy), 0·3% (0·22 Gy) and 0·05% (0·042 Gy), respectively. Choi et al.Reference Choi, Kim and Lee22 demonstrated comparable changes in IMRT head/neck patients. Increases of 0·4% (0·27 Gy), 0·42% (0·29 Gy) and 0·75% (0·59 Gy) were found in the non-contrast PTVs V95, mean and maximum doses. Letourneau et al.Reference Létourneau, Finlay and O'Sullivan23 showed changes of 0·17 Gy to the PTVs minimum dose and 0·12 Gy to the PTVs maximum dose among IMRT head/neck patients. This was concluded as having an insignificant effect. A summary of these studies is given in Table 5.

In this study, the dose to the bladder was more varied than the rectum. The non-contrast bladder dose increased statistically significantly at the maximum, 5% and 30% volume. This was by 0·6% (0·45 Gy), 0·98% (0·72 Gy) and 1·71% (0·88 Gy). All the measurements were <2% dose difference except for V50 with a difference of 4·7% (1·19 Gy). These changes were lower in the rectum perhaps due to amount of contrast used. The rectum had a maximum dose difference under 0·7%. The rectum did not show as much of an increase in dose without contrast similar to the bladder. This is likely due to the increased variation in density within the rectum itself (air pockets). Thus, changing the density to 1 g/cm3 may actually increase its overall density, as opposed to decreasing it and increase the compton effect attenuation. This may be reflected by the increased MU for the posterior beam (0·55 MU) in the non-contrast group.

Owing to the anatomical location of the prostate and the technique used, the presence of bladder and rectal contrast media appear to affect the anterior and posterior beams more than the laterals. A pencil beam algorithm was used for this study. This was very efficient and the insignificance of algorithm selection used in prostate planning has been shown in four-field box technique 15 MV by a study by Knoos et al.Reference Knöös, Wieslander and Cozzi26 It was concluded that for simple four-field box conformal techniques in the mostly uniform density pelvis that the selection of model/system is not critical for the final dose or dose distribution.

The major limitation of this study is that the same CT dataset was used with a bulk density correction, instead of scanning the patients with and without the CAs. It was felt, however, that to scan patients twice was not justified and to do so would also introduce possible variations in rectal and bladder volumes, as well as possible prostate positional changes. These may affect the DVHs and MUs required more so than the actual presence of small amounts of CAs and may make analysis of the contrast effect more difficult.

It is evident that any dosimetric changes that occur when contrast is introduced affect the dose minimally. Consideration must be given to the volumes and concentration used as advised by Ramm et al.Reference Ramm, Damrau and Mose19 The electron density is of importance at therapeutic energies due to the compton effect. When treatment planning dose volume constraints are very close to being met, one must consider the possibility that the dose to the structure can differ if density corrections are not accounted for. Despite these changes being small, they may in very rare occasions affect the acceptability of plans when adhering to constraints.

Acknowledgements

Special thanks to Michelle Leech, Head of Discipline of Radiation Therapy, Trinity College Dublin for all her help and support.

Conflicts of interest

There is no conflict of interest to report for this article.

References

1.Teh, B S, Woo, S Y, Woo, Aet al. Intensity modulated radiation therapy (IMRT): a new promising technology in radiation oncology. Oncologist 1999; 4: 433442.CrossRefGoogle ScholarPubMed
2.Zelefsky, M J, Fuks, Z, Hunt, Met al. High dose intensity modulated radiation therapy for prostate cancer: early toxicity and biochemical outcome in 772 patients. Int J Radiat Oncol Biol Phys 2002; 53: 11111116.CrossRefGoogle ScholarPubMed
3.Pollack, A, Zagars, G K, Starkschall, Get al. Prostate cancer radiation dose response: results of the M. D. Anderson phase III randomized trial. Int J Radiat Oncol Biol Phys 2002; 53 (5): 10971105.CrossRefGoogle Scholar
4.Zietman, A L, DeSilvio, M L, Slater, J Det al. Comparison of conventional dose vs high dose conformal radiation therapy in clinically localized adenocarcinoma of the prostate: a randomized controlled trial. J Am Med Assoc 2005; 294: 12331239.CrossRefGoogle ScholarPubMed
5.Dearnaley, D P, Sydes, M R, Graham, J Det al. Escalated dose versus standard dose conformal radiotherapy in prostate cancer: first results from the MRC RT01 randomised controlled trial. Lancet Oncol 2007; 8: 475487.CrossRefGoogle ScholarPubMed
6.International Commission on Radiation Units and Measurements (ICRU) Report 50. Prescribing, recording and reporting photon beam therapy. Bethesda, MD: International Commission on Radiation Units and Measurements, 1993.Google Scholar
7.Fiorino, C, Reni, M, Bolognesi, Aet al. Intra and inter observer variability in contouring prostate and seminal vesicles: implications for conformal treatment planning. Radiother Oncol 1998; 47 (3): 285292.CrossRefGoogle ScholarPubMed
8.Rasch, C, Barillot, I, Remeijer, Pet al. Definition of the prostate in CT and MRI: a multi-observer study. Int J Radiat Oncol Biol Phys 1999; 43 (1): 5766.CrossRefGoogle ScholarPubMed
9.Wachter, S, Wachter-Gerstner, N, Bock, Tet al. Interobserver comparison of CT and MRI-based prostate apex definition. Clinical relevance for conformal radiotherapy treatment planning. Strahlenther Onkol 2002; 178 (5): 263268.CrossRefGoogle ScholarPubMed
10.Myers, R P, Cahill, D R, Devine, R Met al. Anatomy of radical prostatectomy as defined by magnetic resonance imaging. J Urol 1998; 159 (6): 21482158.CrossRefGoogle ScholarPubMed
11.Rahmouni, A, Yang, A, Tempany, C Met al. Accuracy of in-vivo assessment of prostatic volume by MRI and transrectal ultrasonography. J Comput Assist Tomogr 1992; 16 (6): 935940.CrossRefGoogle ScholarPubMed
12.Roach, M III, Faillace-Akazawa, P, Malfatti, Cet al. Prostate volumes defined by magnetic resonance imaging and computerized tomographic scans for three-dimensional conformal radiotherapy. Int J Radiat Oncol Biol Phys 1996; 35 (5): 10111018.CrossRefGoogle ScholarPubMed
13.Valicenti, R K, Sweet, J W, Hauck, W Wet al. Variation of clinical target volume definition in three-dimensional conformal radiation therapy for prostate cancer. Int J Radiat Oncol Biol Phys 1999; 44 (4): 931935.CrossRefGoogle ScholarPubMed
14.Sharma, R, Duclos, M, Chuba, P Jet al. Enhancement of prostate tumour volume definition with intravesical contrast: a three-dimensional dosimetric evaluation. Int J Radiat Oncol Biol Phys 1997; 38 (3): 575582.CrossRefGoogle ScholarPubMed
15.Fiorino, C, Vavassori, V, Sanguineti, G, Bianchi, C. Rectum contouring variability in patients treated for prostate cancer: impact on rectum dose-histograms and normal tissue complication probability. Radiother Oncol 2002; 63: 249255.CrossRefGoogle Scholar
16.Lebesque, J V, Bruce, A M, Kroes, A Pet al. Variation in volumes, dose-volume histograms, and estimated normal tissue complication probabilities of rectum and bladder during conformal radiotherapy of T3 prostate cancer. Int J Radiat Oncol Biol Phys 1995; 33 (5): 11091119.CrossRefGoogle ScholarPubMed
17.Gao, Z, Wilkins, D, Eapen, Let al. A study of prostate delineation referenced against a gold standard created from the visible human data. Radiother Oncol 2007; 85 (2): 239246.CrossRefGoogle Scholar
18.Harvey, C, Blomley, M. Conventional radiography: contrast agents and safety issues. The Foundation Years 2006; 2 (4): 142145.CrossRefGoogle Scholar
19.Ramm, U, Damrau, M, Mose, Set al. Influence of CT contrast agents on dose calculations in a 3D treatment planning system. Phys Med Biol 2001; 46: 26312635.CrossRefGoogle Scholar
20.Weber, D C, Rouzaud, M, Miralbell, R. Bladder opacification does not significantly influence dose distribution in conformal radiotherapy of prostate cancer. Radiother Oncol 2001; 59 (1): 9597.CrossRefGoogle Scholar
21.Chu, J C, Ni, B, Kriz, Ret al. Applications of simulator computed tomography number for photon dose calculations during radiotherapy treatment planning. Radiother Oncol 2000; 55 (1): 6573.CrossRefGoogle ScholarPubMed
22.Choi, Y, Kim, J, Lee, Het al. Influence of intravenous contrast agent on dose calculations of intensity modulated radiation therapy plans for head and neck cancer. Radiother Oncol 2006; 81 (2): 158162.CrossRefGoogle ScholarPubMed
23.Létourneau, D, Finlay, M, O'Sullivan, Bet al. Lack of influence of intravenous contrast on head and neck IMRT dose distributions. Acta Oncol 2008; 47 (1): 9094.CrossRefGoogle ScholarPubMed
24.Burridge, N A, Rowbottom, C G, Burt, P Aet al. Effect of contrast enhanced CT scans on heterogeneity corrected dose computations in the lung. J Appl Clin Med Phys 2006; 7 (4): 112.CrossRefGoogle ScholarPubMed
25.Johns, H E, Cunningham, J R. The Physics of Radiology, 3rd edition. Springfield, IL: Charles C Thomas, 1969.Google Scholar
26.Knöös, T, Wieslander, E, Cozzi, Let al. Comparison of dose calculation algorithms for treatment planning in external photon beam therapy for clinical situations. Phys Med Biol 2006; 51: 57855807.CrossRefGoogle ScholarPubMed
27.Lees, J, Holloway, L, Fuller, Met al. Effect of intravenous contrast on treatment planning system dose calculations in the lung. Australas Phys Eng Sci Med 2005; 28 (3): 190195.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 OAR and DVC used in plans

Figure 1

Table 2 Contrast versus non-contrast dose comparisons

Figure 2

Table 3 Mean and SD values for contrast and non-contrast plans

Figure 3

Table 4 Mean MU and % dose difference (contrast – non-contrast)

Figure 4

Table 5 Review of the effect of contrast agents on dose calculations in radiotherapy