The importance of using anterior and posterior views in the calculation of differential renal function using 99Tcm-DMSA

Evaluation of Renal Function in Obstructed Ureter Model Using 99mTc-DMSA

BACKGROUND/AIM

Urinary obstruction is a condition of impaired urinary drainage, which may result in progressive renal deterioration. This study applied ^99mTc-labeled dimercaptosuccinic acid (^99mTc-DMSA) renal scintigraphy to a rabbit model of right ureter obstruction and evaluated its utility in studying obstructive renal diseases.

MATERIALS AND METHODS

Complete unilateral ureter obstruction in rabbits was generated by complete ligation of the right ureter. Renal function was investigated during a 4-week post-obstruction period by obtaining planar images of ^99mTc-DMSA activity following ear vein injection. Renal blood perfusion was evaluated by non-invasive scintigraphy in conjunction with parallel histological and hematological examinations.

RESULTS

Renal perfusion was remarkably and rapidly reduced in the ureter-obstructed kidneys. During the experimental period, the size of left kidney appeared normal in the scintigraphic images, but the ureter-obstructed right kidney progressively became larger. Histopathological examination showed flattening and atrophy of tubules, enlargement of interstitial areas, accumulation of extracellular martices and infiltration of inflammatory cells in the obstreucted kidney.

CONCLUSION

^99mTc-DMSA scintigraphy is a sensitive, non-invasive method to assess renal function in unilateral kidney diseases.

Influence of CT-based depth correction of renal scintigraphy in evaluation of living kidney donors on side selection and postoperative renal function: is it necessary to know the relative renal function?

PURPOSE

To analyse the influence of CT-based depth correction in the assessment of split renal function in potential living kidney donors.

METHODS

In 116 consecutive living kidney donors preoperative split renal function was assessed using the CT-based depth correction. Influence on donor side selection and postoperative renal function of the living kidney donors were analyzed. Linear regression analysis was performed to identify predictors of postoperative renal function.

RESULTS

A left versus right kidney depth variation of more than 1 cm was found in 40/114 donors (35%). 11 patients (10%) had a difference of more than 5% in relative renal function after depth correction. Kidney depth variation and changes in relative renal function after depth correction would have had influence on side selection in 30 of 114 living kidney donors. CT depth correction did not improve the predictability of postoperative renal function of the living kidney donor. In general, it was not possible to predict the postoperative renal function from preoperative total and relative renal function. In multivariate linear regression analysis, age and BMI were identified as most important predictors for postoperative renal function of the living kidney donors.

CONCLUSIONS

Our results clearly indicate that concerning the postoperative renal function of living kidney donors, the relative renal function of the donated kidney seems to be less important than other factors. A multimodal assessment with consideration of all available results including kidney size, location of the kidney and split renal function remains necessary.

Simple renal cyst and renal dysfunction: A pilot study using dimercaptosuccinic acid renal Scan

AIM

Little is known about the association between renal cyst and renal dysfunction. We evaluated the deterioration of renal function in patients with unilateral, large, simple renal cysts.

METHODS

Fifty patients with unilateral, simple renal cysts measuring ≥ 4 cm (cyst group) and 50 kidney donors (control group) were enrolled. Dimercaptosuccinic acid (DMSA) renal scans were performed to calculate split renal function. The differences between split renal function were calculated and compared. Clinical factors affecting decreased renal function in the cyst group were assessed.

RESULTS

The mean age of the patients in the cyst group was higher than the control group (59.1 vs 39.2 years; P = 0.001). Patients with renal cysts tended to be diagnosed with hypertension (P = 0.001), However, the two groups did not significantly differ in terms of the other characteristics. The median cyst size was 7.2 cm (range, 4.5-14.2), and 31 of the 50 patients (60.2%) in the cyst group demonstrated decreased renal function in the cystic kidney units (median: 5.8%; range, 0.2-33). Although there were no differences in split renal function (50.1% vs 49.9%; P = 0.629) in the control group, the relative renal function of the cystic kidney units were significantly lower than the contralateral kidney units in the cyst group (48.3% vs 51.7%; P = 0.001). The decrease in relative renal function (>8%) in the cystic kidney units was associated with a higher serum uric acid levels and higher RENAL complexity (P = 0.035 and P = 0.007, respectively).

CONCLUSION

A significant proportion of unilateral, large, simple renal cysts are associated with decreased relative renal function on DMSA renal scans.

Optimizing scintigraphic evaluation of split renal function in living kidney donors using the geometric mean method: a preliminary retrospective study

BACKGROUND

Accurate assessment of pre-transplant split renal function in candidates for living kidney donation is indispensable for side-selection and a sufficient long-term residual renal function.

OBJECTIVE

To analyse the need of depth correction in the assessment of split renal function in potential living kidney donors.

METHODS

In 13 consecutive patients screened for living kidney donation split renal function was measured with four different methods including conventional posterior MAG-3-scintigraphy, the geometric mean method in MAG-3-scintigraphy, MAG-3-scintigraphy with CT-based depth correction and CT-volumetry. Correlation and agreement of methods were analyzed using Spearman's rho correlation coefficient and the Bland-Altman method.

RESULTS

Despite good correlation and agreement between the different radioisotopic methods there were clinically relevant differences in split renal function in 2/13 patients (15 %) between conventional posterior MAG-3 scan and the geometric mean method. The best correlation was found between the two scintigraphic methods with depth correction. Comparing radioisotopic methods with CT-volumetry, significant differences were found in up to 6/13 patients (46 %).

CONCLUSIONS

Our results clearly indicate that in the case of living kidney donation further assessment concerning the accuracy and reliability of measuring split renal function is necessary. As there are no differences in duration of examination, costs and radiation exposure between techniques with and without depth correction, but clinically relevant differences in up to 46 % of patients, kidney depth should be incorporated in daily clinical practice of living kidney donor evaluation. The geometric mean method could significantly improve future patient assessment in cases of living kidney donation.

Comparison of computer tomographic volumetry versus nuclear split renal function to determine residual renal function after living kidney donation

BACKGROUND

Living-donor kidney transplantation is an established practice. Traditionally a combination of renal scintigram and computed tomography (CT) is used to select the kidney that is to be harvested in each donor.

PURPOSE

To evaluate the ability of split renal volume (SRV) calculated from volumetric examination of CT images compared to nuclear split renal function (nSRF) derived from gamma camera scintigram to predict donor residual single kidney function after donor nephrectomy.

MATERIAL AND METHODS

This pilot study comprised a retrospective analysis of CT images and renal scintigrams from 12 subsequent live kidney donors who had at least 12 months post-donation renal function follow-up.

RESULTS

nSRF derived from the renal scintigram, expressed as the right kidney's function in percent of the total, was 50.2 ± 3.3 (range, 44.1-54.0%) and SRV estimated following analysis of CT imaging was 49.0 ± 2.9 (range, 46.4-52.3%). Although the correlation between nSRF and SRV was moderate (R = 0.46), there was 92% agreement on the dominant kidney if a difference of <2% in nSRF versus SRV was considered. Post-donation glomerular filtration rate (GFR) by CKD-EPI formula was 92 ± 10 mL/min/1.73m2 at 1 year and the correlation between estimated GFR (eGFR) at 1 year and extrapolated single kidney eGFR adjusted by nSRF (R(2 )= 0.69, P = 0.0007) or SRV (R(2 )= 0.74, P = 0.0003) was similar.

CONCLUSION

Calculation of SRV from pre-donation CT examination is a valid method to estimate nSRF with good concordance with nSRF determined by renal scintigram and could replace the latter in the assessment of potential kidney donors.

Optimizing evaluation of split renal function in a living kidney donor using scintigraphy and calculation of the geometric mean: a case report

Within the evaluation process of living kidney donors, split renal function is usually evaluated by renal scintigraphy. Since split renal function measured by conventional posterior scans depends on the position of the kidney, actual suitable donors may be rejected because of an inaccurate examination technique. We report the case of a 28-year-old male living kidney donor. Due to a complex vascular anatomy of the right kidney, only his left kidney was considered eligible for transplantation. In conventional posterior Tc99m-mercapto-acetyltriglycine scintigraphy, the left kidney had a relative function of 60%. A second scintigraphy using anterior and posterior dimercaptosuccinic acid scans with calculation of the geometric mean showed an adapted relative function of the left kidney of 53%, now meeting the inclusion criteria for living kidney donation. This case shows that the geometric mean method using simultaneous anterior and posterior views obtained with a dual-head gamma camera can be a very helpful approach to determine split renal function of potential living kidney donors. Further investigation is necessary to prove the benefit of a general bilateral scan before living kidney donation.

Impact of geometric mean imaging in the accurate determination of partial function in MAG3 renal scanning in a patient with retroperitoneal mass

Liposarcoma frequently occurs in the retroperitoneum and lower extremities, accounting for 20% of all mesenchymal malignancies. Liposarcomas vary by histology and can be classified into four types. Those four types are well differentiated, myxoid/round cell, pleomorphic and dedifferentiated. Due to retroperitoneal location of this tumor, it is expected to affect the kidney position. Renography has provided a unique tool for noninvasive evaluation of various functional parameters e.g. relative renal function. Most renography studies are carried out using the posterior view, under the assumption that the depths of both kidneys are similar so that the radiotracer counts in the region of interest will be attenuated to the same extent. Errors in estimation of the relative renal function may arise if the kidneys are at different depths e.g. secondary to a pushing tumor. Geometric mean imaging from combined anterior and posterior views helps to overcome this issue. This case shows the impact of geometric mean imaging in the truthful determination of partial function in patients with retroperitoneal liposarcoma.

(99m)Tc-DMSA absolute and relative renal uptake in cats: procedure and normal values

In this study we investigated the influence of technical factors (positioning, background (BG) correction and attenuation correction) on qualitative and quantitative (absolute (AU) and relative (RU) uptake) assessment of feline kidneys with (99m)technetium labelled dimercaptosuccinic acid ((99m)Tc-DMSA). Eleven healthy adult cats were included. Influence of BG and depth correction on quantitative assessment was evaluated. Depth correction was based on the geometric mean method (using dorsal and ventral images) and the use of two standards placed over each individual kidney. Visual evaluation showed superiority of dorsal and ventral over lateral positioning due to increased separation of the kidneys permitting region of interest (ROI) placement without overlap. No apparent influence of BG correction was found for RU. However, AU was systematically overestimated without BG correction. Depth correction did not seem to affect RU in most cases, however, in some cats the differences were not negligible. The values for AU without depth correction were lower compared to depth corrected values.

A technique for the simulation of planar radionuclide images of the kidney

BACKGROUND

Although Tc-dimercaptosuccinic acid (DMSA) scans are routinely used to quantify relative renal function, no quantification method is universally adopted. Audits using real patient data indicate reasonable consistency but, as the true relative function is unknown, accuracy cannot be assessed. The aim was to simulate realistic DMSA images that can be used to assess accuracy.

METHODS

Anatomical models were created from computed tomography (CT) scans of a patient who had also undergone DMSA imaging. Organs that take up DMSA were outlined on CT and each assigned an activity concentration (with renal cortex and medulla modelled separately). The simulated images were visually compared to the patient's clinical images and subtracted to identify differences. Iteration was used on the posterior image to find the organ activities that produced the most realistic simulated image. The optimal activity distribution was then used to also simulate an anterior image. To assess the simulations, the percentage difference was calculated between the counts in each kidney on the real and simulated images.

RESULTS

Visually, the clinical and simulated images appear similar and the subtracted images indicate only small differences. The percentage difference in kidney counts between the images was less than 1% for both kidneys on the posterior image and less than 5% on the anterior image. The cortex and medulla activity concentrations were approximately equal.

CONCLUSION

A technique for realistic simulation of DMSA images has been devised and should prove useful for evaluating image analysis software.

A technique for analysis of geometric mean renography

BACKGROUND AND OBJECTIVES

Renography is used routinely to assess relative right to left renal function. Quantification is usually carried out using posterior images. Errors in relative renal function may occur if the kidneys are at different depths. Geometric mean images from combined anterior and posterior views are much less affected by kidney depth and offer the opportunity of more accurate and precise quantification. Background subtraction is a key part of the analysis process and validated protocols for geometric mean imaging have not been devised. This study aims to derive a suitable background subtraction protocol for geometric mean imaging.

METHODS

Simultaneous anterior and posterior renography using Tc mercaptoacetyltriglycine (MAG3) was performed on 16 adults. Analysis was carried out using both geometric mean and posterior images. The geometric mean background subtraction protocol was modified to give the same results as a posterior method, which had previously been validated by correlation with measurements of glomerular filtration rate. Absolute and relative uptakes were then obtained from both geometric mean and posterior analyses. For each analysis values were obtained both with and without depth correction.

RESULTS

A revised background subtraction protocol for geometric mean renography was devised which operated successfully on all studies. Both absolute renal uptake and relative function values obtained from geometric mean analysis were not systematically different from those obtained using posterior analysis with depth correction. Values of the relative renal function from posterior analysis after depth correction were closer to the geometric mean values than estimates obtained before correction.

CONCLUSION

A technique for analysing geometric mean renography data has been developed which gives results consistent with a previously validated posterior-only method.

WDP, Okamoto MRY, Garcez AT, Watanabe T, Costa PLA, Buchpiguel CA. Padronização do método para cálculo da captação renal absoluta do99mTc-DMSA em cria

OBJETIVO: O trabalho teve por objetivo padronizar o método e estabelecer valores normais da captação renal absoluta do99mTc-DMSA em crianças. MATERIAIS E MÉTODOS: Vinte e duas crianças (idade de 7 meses a 10 anos; média de 4,5 anos) sem doença renal prévia foram submetidas a cintilografia renal estática com 99mTc-DMSA. Dezoito apresentavam ultra-sonografia, uretrocistografia miccional, "clearance" de creatinina e padrão visual da cintilografia renal estática normais. Quatro crianças foram excluídas por não terem completado ou por apresentarem redução do "clearance" de creatinina. A captação absoluta de DMSA (DMSA-Abs) foi calculada como a porcentagem da atividade administrada retida em cada rim após seis horas da administração do radiofármaco. RESULTADOS: Os valores de DMSA-Abs foram de 21,8% ± 3,2% para o rim direito e de 23,1% ± 3,3% para o rim esquerdo. Os valores da captação absoluta não mostraram correlação com a idade dos pacientes estudados, apesar da tendência de aumento do "clearance" de creatinina com a idade. CONCLUSÃO: A definição de valores normais da DMSA-Abs permite o emprego deste parâmetro na avaliação inicial e acompanhamento de doenças renais, principalmente em pacientes com acometimento bilateral ou com rim único (nos quais a função diferencial direita X esquerda tem valor limitado).

Individual renal function based on 99mTc dimercaptosuccinic acid uptake corrected for renal size

BACKGROUND

Decreased relative 99mTc dimercaptosuccinic acid (99mTc-DMSA) uptake can be a consequence of abnormal kidney size, associated with normal or impaired function. When there is a small kidney, relative 99mTc-DMSA uptake is decreased, and it is sometimes difficult to distinguish a small, normal kidney from a hypofunctioning kidney. Here, relative renal function was studied by quantifying the relative 99mTc-DMSA uptake corrected for renal size (RCU).

METHODS

Five hundred and fifty-five consecutive patients (184 adults) aged 1 month to 82 years (mean, 14.8 years) underwent a 99mTc-DMSA study for various renal diseases. Results were compared with the relative 99mTc-DMSA uptake without size correction (RUU). Visual evaluation of images was also performed.

RESULTS

In 288 patients (52%) the relative 99mTc-DMSA uptake was normal, either uncorrected or corrected, for renal size; in 184 (33%) it was abnormal by both quantification methods; and in 83 (15%) it was abnormal only by one method. Two hundred and fifty-seven patients (46%) presented with decreased RUU in one kidney, associated with a small kidney in 73 patients (13%). RCU was normal in all of these 73 patients (100%, P<0.0001). The sensitivity and specificity of RCU for evaluating renal function in relation to small renal size and with respect to RUU were 72% and 97%, with positive and negative predictive values of 95% and 80%, and an accuracy of 85%. Visual analysis of the 73 studies with decreased RUU and normal RCU showed a small, normal kidney on 55 occasions (75%), cortical scars in eight (11%), and impaired bilateral function in 10 (14%). Visual analysis of 10 studies with normal RUU and decreased RCU showed dilated pyelocalyceal system in seven occasions (70%) and normal kidneys in three (P<0.0001).

CONCLUSION

It is concluded that relative 99mTc-DMSA uptake corrected for renal size is a more accurate method for assessing individual renal function. When there is a small kidney, relative 99mTc-DMSA uptake corrected for renal size can distinguish between a normal and a hypofunctioning kidney.

Assessment of the optimal time interval and background region of interest in the measurement of differential renal function in Tc-99m-EC renography

BACKGROUND

Differential renal function (DRF) measurements are routinely corrected for background, which mainly affects the reproducibility and accuracy of the measurement. The present study was conducted to identify the most appropriate background ROI and optimal time interval in the calculation of DRF for EC renography.

MATERIALS AND METHODS

Nineteen patients were studied. For determination of DRF in EC renography, the selected time intervals were 0.5-1.5; 0.5-2; 1-2; 1.5-2.5; 2-3 min, and the background ROI types were inferolateral crescent, lateral crescent, and perirenal shaped. The reference DRF was obtained through DMSA study. For low functioning kidney of each patient, relative uptake differences between the DMSA and EC scans were calculated. Then, the mean differences and the standard deviations were found.

RESULTS

The highest correlation was between the DRF values obtained using inferolateral background ROI in 0.5-2 minutes of EC scintigraphy and the DRF values obtained through posterior DMSA images (r = 0.9889). However, there were no statistically significant differences between the mean DRF values obtained for each time interval with each ROI type (p > 0.05). For all the time intervals and background ROIs, the mean of the differences was <0.9%. In conclusion, in obtaining comparable DRF values from EC and DMSA studies, none of the background types proved superior. Also our research for optimal time interval showed that EC scintigraphy underestimates the DRF when compared to DRF obtained from DMSA study. The DRF has a tendency to decrease as the later time intervals are used. The time intervals less than 2.5 minutes show lower underestimation of DRF values.

[Value of the use of the geometric mean to calculate the relative renal function in 99mTc-DMSA renal scintigraphy]

Determining the relationship of DMSA uptake of the left versus right kidney is theoretically one of the easiest quantitative procedures in nuclear medicine. The quantification can be performed on the posterior view, with or without a lateral view for correction of kidney depth. The geometric mean can also be determined by using both the anterior and the posterior views. This study has aimed to evaluate if there are significant differences in the quantification of the renal function percentage using only the posterior view and the geometric mean. Furthermore, we evaluated to what extent the patient's age and diagnosis influenced these differences. We have proposed a work protocol in which we indicate which cases the geometric mean should be calculated in order to minimize the possible errors occurring when only the posterior view is used.A total of 328 renal scintigraphies with 99mTc-DMSA performed at our Department in the last six months were studied. The mean and standard deviation of the differences as well as the correlation coefficient between both methods were calculated. The difference between the right renal function in posterior view and the right renal function obtained using the geometric mean was calculated for all the patients. The Student's T test was applied to determine whether the differences between both methods were statistically different from zero. Statistical differences were found in patients older than 9 years and in patients with genitourinary malformations.

Is the depth correction using the geometric mean really necessary in a 99Tcm-DMSA scan in the paediatric population?

Determination of the left to right dimercaptosuccinic acid (DMSA) uptake ratio is theoretically one of the easiest quantitative procedures in nuclear medicine. The quantification can be performed on the posterior view, with or without the lateral view for correction of kidney depth. The geometric mean can also be determined using both the anterior and the posterior views. The aim of this study was to evaluate the occurrence of remarkable differences in the results from quantification of the relative renal function using the geometric mean and those obtained using the posterior counts only. Moreover, we evaluated to what extent the patient age influenced these differences. We reviewed 328 99Tcm-DMSA scans. The difference between the relative renal function obtained using the posterior view and that obtained using the geometric mean was calculated and analysed statistically. For the purpose of evaluating the value of performing the geometric mean calculation in patients of different ages, patients were divided into four age groups (group I, < or =2 years; group II, 3-9 years; group III, 10-18 years; group IV, >18 years). Using the Student's t test, no statistical differences were found in the relative renal function obtained by the two methods (posterior projection and geometric mean) in groups I (t = 0.01, P = 0.992) and II (t = 1.43, P = 0.155), which consisted of patients younger than 10 years (77% of the patients). In groups III and IV statistical differences were found (t = 2.27, P = 0.028 and t = 2.170, P = 0.038), respectively. We conclude that for children under 10 years it is unnecessary to perform depth correction using the geometric mean except in rare cases of major malformations and position anomalies.

Inter-observer reproducibility of relative 99Tcm-DMSA uptake

99Tcm-DMSA planar images of 49 randomly selected patients (10 adults, 39 children) were sent to 15 physicians at various centres in Belgium. They were asked to calculate, using their own routine program, the relative uptake (expressed as a percentage) of each kidney. The data were sent on disks formatted so that they could be read by all participants, using their own computer systems. For each scan, the inter-observer variability was expressed using the maximum difference and the standard deviation of left renal uptake. Left renal uptake measured by the 15 observers in the 49 patients was 29.0-72.0% (mean +/- s = 49.8 +/- 6.4%). The maximum differences in left renal uptake ranged between 1.7% and 12.0% (4.5 +/- 2.6%); however, the maximum difference did not exceed 8% in about 90% of the patients. The standard deviations of the individual left renal uptake were between 0.6 and 3.9 (1.3 +/- 0.8). The standard deviations were significantly higher in adults (mean standard deviation = 2.05) than in children (mean standard deviation = 1.12) (P < 0.001); this was probably related to the high background observed in three adults with severe renal impairment. Indeed there was a significant correlation (P < 0.001) between the standard deviation and both the signal-to-noise ratio and the degree of asymmetry between the right and left kidneys. The differences between right and left kidney uptake were systematically lower for some observers, suggesting an influence of the calculation programs.

Determination of glomerular filtration rate using a dual-detector gamma camera and the geometric mean of renal activity: correlation with the Tc-99m DTPA plasma clearance method

PURPOSE

In this study, the authors studied the use of a dual-detector gamma camera to measure the glomerular filtration rate (GFR).

METHODS

Thirty-three patients with a wide range of renal function participated in this study. The GFR was measured using a dual-detector gamma camera by calculating the geometric mean of activity from each kidney and using an outline background. These results were compared with the GFR estimates obtained from Tc-99m DTPA plasma clearance using a multiple blood sample method.

RESULTS

Correlation was excellent between GFR estimated using the dual-detector gamma camera and GFR measured using the plasma clearance of Tc-99m DTPA with multiple blood samples (r = 0.89). The correlation was especially strong in children younger than 13 years (r = 0.94).

CONCLUSION

Measuring the GFR using a dual-detector gamma camera and calculating the geometric mean of renal activity yields relatively accurate results.

Quantitative planar imaging method for measurement of renal activity by using a conjugate-emission image and transmission data

We are proposing a method to accurately measure renal activity in renography using Tc-99m labeled tracers. This method uses a conjugate-view image and transmission data for attenuation correction, the triple energy window (TEW) method for scatter correction, and background correction techniques that consider the source volume for accurate background activity correction. To examine this method in planar imaging, we performed two renal phantom studies with various uniform background activity concentrations. One study used two ideal box-shaped kidney phantoms with a thickness of 2 or 4 cm in a water tank and the other study employed two real kidney-shaped phantoms in a fillable abdominal cavity. For these studies the kidney phantom-to-background activity concentration ratio (S) was changed from 5 to infinity. The transmission data were obtained with an external Tc-99m line array source. The anterior- and posterior-view emission images were acquired with a dual-headed gamma camera simultaneously and the TEW method was used to correct scatter for the emission and transmission images. The results showed that this method with both the accurate background correction and scatter correction could give depth-independent count rates and could estimate the true count rate with errors of less than 5% for all S values. However, if either accurate background correction or scatter correction was performed alone, the absolute error increased to about 50% for the smaller S values. Our proposed method allows one to accurately and simply measure the renal radioactivity by planar imaging using the conjugate-emission image and transmission data.

Consensus report on quality control of quantitative measurements of renal function obtained from the renogram: International Consensus Committee from the Scientific Committee of Radionuclides in Nephrourology

Among all the physiological indices that can be quantified using renography, measurement of renal function is the most basic. These measurements are used to make critical clinical management decisions and, as such, their reliability needs to be quality assured. This article seeks to address each aspect of the renography procedure, with particular emphasis on the effect on measurement of relative renal function. Estimation of individual kidney function is mentioned, but only briefly. A consensus approach was adopted, overseen, and directed by a chairman appointed by the Scientific Committee of the International Radionuclides in Nephro-Urology Group. The chairman selected the panel of experts from eight different countries based on their practical experience in the field. Where evidence exists to support the various recommendations it is given. Otherwise, the stated guidance represents the considered opinion of a body of experts, based on long experience and unpublished data. Some necessary compromises were made to account for the fact that renography is seldom performed solely with the purpose of measuring relative renal function. The technicalities of renography have always been a source of debate in nuclear medicine, which is reflected by the fact that a consensus could simply not be reached on a small number of issues. The structure of the report ensures that these are clearly indicated. This should serve to highlight gaps in our current knowledge, thus helping to direct future research. It is envisaged that the recommendations will be revised on a 2-year cycle to ensure that they remain up to date. An "open" process will be used to encourage participation and ownership. It is hoped that promotion of these guidelines, suitably complemented by audit processes, will raise standards in the practice of gamma camera renography.

Comparison of whole-body thallium imaging with transcutaneous PO2 in studying regional blood supply in patients with peripheral arterial occlusive disease

Quantitatively estimating functional reserve of blood supply to the legs in patients with peripheral arterial occlusive disease (PAOD) remains a clinical issue. This study was designed to investigate the regional blood supply to the legs in PAOD patients during exercise by use of thallium 201 (201Tl) whole-body imaging in comparison with transcutaneous PO2 (tcPO2) measurement. Thirty-three patients with PAOD and 10 subjects without PAOD (control) performed an incremental cycle ergometry (CE), while tcPO2 was continuously registered on the involved calf. In the last minute of exercise, 2 mCi of 201Tl was injected intravenously and the 201Tl whole-body images were taken immediately (stress) and four hours (redistribution) following stress with a dual-head camera system. Regional blood supply (RBS) (%) was calculated from the geometric mean counts of the region of interest divided by the total counts of the whole body. The performance of PAOD patients was reduced in doing CE, and tcPO2 fell distinctly in PAOD patients (from 51 to 19 mmHg) whereas it increased in controls (from 57 to 67 mmHg). The RBS in PAOD patients was obviously reduced in comparison with that of controls. While in controls the RBS of the calf (3.1%) at stress did not differ from that at redistribution (3.4%), in PAOD patients the redistribution RBS (2.8%) increased as compared with that of stress (1.5%). There was a hyperbolic relationship between stress RBS of the calf and the velocity of tcPO2 fall in PAOD patients during exercise test (velocity of tcPO2 fall = -0.032 + 0.39/RBS, r2 = 0.54, P < 0.05). In conclusion, the RBS determined by 201Tl whole-body imaging is comparable to the tcPO2 measurement in differentiating patients with PAOD from subjects without PAOD during exercise. Regional 201Tl uptake reflects regional blood supply in PAOD patients. There is a hyperbolic relationship between the RBS derived from 201Tl whole-body imaging and tcPO2 in PAOD patients during exercise, implying that in a critical ischemia the lower the RBS is, the more steeply the tcPO2 decreases.

Technetium-99m dimercaptosuccinic acid and ifosfamide tubular dysfunction in children with cancer

Quantitative 99mTc-dimercaptosuccinic acid (99mTc-DMSA) renal scintigraphy was used to asses ifosfamide-induced changes in renal function in 11 children who received chemotherapy for various malignancies. Serial measurements of absolute 99mTc-DMSA renal uptake, calculated on conjugated views, were performed during and after chemotherapy. Data of 37 studies obtained before and at different cumulative dose levels of ifosfamide were analysed in relation to clinical and biochemical parameters. A highly significant relationship between 99mTc-DMSA uptake and cumulative ifosfamide dose was found (P < 0.001). The most frequently observed abnormal pattern on scintigraphic images was decreased kidney uptake together with increased accumulation in bladder. 99mTc-DMSA uptake was more consistent than beta 2-microglobulin values in urine and more sensitive than quantitative hyperaminoaciduria and tubular resorption of phosphate for the detection of ifosfamide-induced tubular dysfunction. 99mTc-DMSA uptake was decreased in both patients with and patients without clinical toxicity. Persistently reduced 99mTc-DMSA uptake was observed in four patients during follow-up; in one of them, who was asymptomatic after ifosfamide therapy, sudden onset of Fanconi syndrome was observed when he was retreated with carboplatin 1 year later. It is concluded that 99mTc-DMSA renal scintigraphy is a suitable method to assess progressive ifosfamide-induced tubular injury whereas scintigraphic imaging is helpful for interpreting renal uptake changes. The test is able to detect subclinical injury and may potentially predict high risk at retreatment.

Renal single photon emission computed tomography: should we do it?

Although single photon emission computed tomography (SPECT) imaging has established a place for itself in clinical nuclear medicine for heart and brain studies, its place in renal imaging is not yet clear. Renal SPECT has been subject to limitations imposed by the efficiency of imaging equipment, and has been confined to use with static imaging agents such as technetium-99m (99mTc) dimercaptosuccinate (DMSA). SPECT has been used to investigate space-occupying lesions and anatomical abnormalities, and for quantitative studies of renal uptake and volume. In these areas, it has provided little advantage over conventional imaging, but it has been helpful in individual cases. High-resolution SPECT is a promising new development, which may have applications in detecting and classifying renal scarring. It deserves careful evaluation.

Methods for measuring the renal uptake rate of 99mTc-dimercaptosuccinic acid (DMSA): a comparative study

A comparative study of the renal uptake rate of 99mTc-dimercaptosuccinic acid (DMSA) was performed using a phantom study and clinical data from 100 patients (200 kidneys) with a variety of renal diseases. The measurement methods for renal uptake rate studied here include a posterior-view method, a conjugate-view method, and a method using single photon emission computed tomography (SPECT). The renal uptake rates obtained by the posterior-view method significantly (P less than 0.001) depended on kidney depth correction. With the SPECT method, the cut-off level for delineating the kidney was changed according to the background count ratio using the results of the phantom study. The renal uptake rates obtained by the SPECT method correlated significantly (P less than 0.001) with those obtained by other methods, and there were no significant differences as compared with those obtained by the conjugate-view method. An analysis of error with the above methods indicated that the error relating to the sensitivity to body thickness was smallest for the SPECT method and greatest for the posterior-view method. In terms of measurement of renal uptake rate only, the conjugate-view method is considered the most useful because it needs no kidney depth correction and requires very little additional effort or examination time.