Abstracts

ORIGINAL ARTICLE

Sudy of the effect of using a collimator on a gamma probe in radioguided surgery^* * Study developed at Real Hospital Português de Pernambuco, Recife, PE, Brazil.

Iran José Oliveira da Silva^I; Helen Jamil Khoury^II; Márcia Rosana Leite de Lemos^III; Paulo José de Almeida Filho^III; Maria Inês Calil Cury Guimarães^IV

^IMaster Degree in Energetic and Nuclear Technologies

^IIDoctorate in Dosimetry and Nuclear Instrumentation

^IIISpecialists in Nuclear Medicine

^IVDoctorate in Dosimetry and Nuclear Medicine

^{Mailing address} Mailing address: Dr. Iran José Oliveira da Silva Universidade Federal de Pernambuco Departamento de Energia Nuclear Avenida Professor Luiz Freire, 1000 Recife, PE, Brazil 50740-540 E-mail: i.jose@bol.com.br

ABSTRACT

OBJECTIVE: The aim of the present study is to evaluate the performance of the Europrobe gamma probe spatial resolution in radioguided surgery.

MATERIALS AND METHODS: In the radioguided surgery technique, after a radiotracer injection into the primary tumor, a gamma detector probe is utilized to determine the localization of the sentinel lymph node. In order to simulate the region of the radiotracer injection the sentinel lymph node, two Tc-99m sources, with 20.42 MBq and 0.70 MBq, were positioned in a water-filled tank. With a collimator cap attached to the probe, scans over the water surface were made. So, the count rate was measured by means of lateral displacement of the probe in relation to the both sources with distances ranging between 30 mm and 60 mm.

RESULTS: Results showed that the use of the collimator contributes to improve the spatial resolution of the probe allowing the identification of a sentinel lymph node within a distance up to 30 mm from the radiotracer injection point.

CONCLUSION: The utilization of a collimator cap with a 3.5 mm diameter central orifice on a Europrobe gamma probe, allows the identification of a sentinel lymph node within a distance up to 30 mm from the radiotracer injection point.

Keywords: Intraoperative probe; Radioguided surgery; Sentinel lymph node localization; Spatial resolution.

INTRODUCTION

Neoplasms or cancers may disseminate throughout the body, basically by two ways: by the blood, through veins and arteries, or by the lymphatic system. This allows the cancer, from a determined site (primary tumor), to generate tumors of the same type in other distant organs (metastasis).

Usually, when a cancer is detected, an evaluation is performed for the presence, or not, of tumor cells dissemination to some lymphatic basin proximal to the primary tumor. If this has occurred, it is necessary to evaluate the degree of involvement of this lymph node basin, since the tumor cells may migrate to other lymph nodes and other parts of the body. The traditional approach involves the removal for analysis of all (10 to 20) lymph nodes in the tumor-draining area⁽¹⁾. However, a technique allowing a higher accuracy in the evaluation of the suspected lymphatic basin involvement degree is based on the identification and removal for analysis of the key lymph node, also known as sentinel lymph node (SLN), which may include cells from the primary tumor.

For an accurate SLN localization, there is a technique consisting in injecting a radiotracer — gamma radiation emitter — into the primary tumor region, and, following a determined time interval during the surgical act, to utilize a gamma ray detector probe (gamma probe) to perform a slow survey throughout the suspected lymphatic basin, aiming at localizing the region where there is a significant increase in the counting-rate in relation to the background radiation counting rate. Studies have shown that, in more than 90% of cases, this region is where the SLN is located⁽²⁾.

This procedure, known as radioguided surgery, requires the best of a surgeon's ability, since it is necessary to handle the probe in search of regions where there is a high enhancement in relation to the measured counting rates, i.e., regions for which a little change in the probe positioning or inclination may cause abrupt variations in counting rates.

Since in the radioguided surgery technique the major difficulty consists in localizing the SLN in sites near the primary tumor, the objective of the present study is to analyze the effect in the probe spatial resolution with the use of a collimator, as well as the variation of the distance between the SLN and the radiotracer injection site.

GAMMA PROBE OPERATING PRINCIPLES

Gamma probes are compact devices basically constituted of two components: a gamma radiation detection system, usually conceived as the probe itself that may be scintillator crystal-based or semiconductor-based, and an electronic system, where the signal is amplified, processed and visualized by means of an analogical or digital display⁽³⁾.

Scintillator crystal-based probe

This type of probe operates basically in the same way of conventional scintillation-detectors, and in this case, for a detection system to acquire small dimensions, a light guide or a optical fiber beam is coupled between the scintillator crystal and the photomultiplier tube, so that the light produced in the crystal due to the interaction with the radiation is transmitted through the light guide to the photomultiplier tube where it is converted into an electrical signal.

Some scintillator crystal-based probes utilize the crystal coupled with a Si photodiode replacing the photomultiplier tube. A critical point in this type of probe is the choice of a high input impedance, low-noise preamplifier, since photodiodes have not an internal signal amplifier device.

Usually, gamma probes scintillator crystals are NaI(Tl), CsI(Tl), Bi₄Ge₃O₁₂ or CdWO₄-based, the two first elements being the most frequently utilized. These crystals present the advantage of an increased atomic number and high specific mass, which contributes to the increase of the gamma radiation absorption coefficient.

Semiconductor crystal-based probe

In the semiconductor crystal, the radiation-sensitive volume corresponds to the depletion region formed by the junction of two types of semiconductor materials: one of P-type, and another of N-type⁽⁴⁾.

The majority of gamma probes utilize HgI₂, CdTe or CdZnTe-based semiconductor crystals. These materials have not only a high gamma radiation absorption coefficient, but also a prohibited wideband range. This latest feature allows the probe to be utilized at the human body temperature (37°C), with less interference of noise resulting from thermal generation by pairs of electron-vacancies in the crystal.

However, differently from Ge or Si semiconductors, in these crystals, because of the low electrons-vacancies mobility, the charge carriers collection is strongly affected by the presence of defects or impurities (Cd, Au, Zn atoms, etc.) in the crystalline net. This contributes to limit the construction of probes utilizing highly thick semiconductor detectors necessary for the detection of high and intermediate energy gamma rays.

PARAMETERS AFFECTING GAMMA PROBES PERFORMANCE

Detection sensitivity and efficiency

The sensitivity is defined as the relation between number of photons depositing all the energy into the probe detector sensitive volume and the amount of photons emitted by the source. Therefore, the sensitivity is heavily affected by the source-detector geometry, besides being directly proportional to the sensitive area of the detector, and inversely proportional to the squared distance between source and detector, if the source is punctual.

The total radiation energy absorption by the detector is dependent on its physical characteristics such as dimensions, effective atomic number, and mass density. One may observe that, for example, in the graphic on Figure 1, for photons with energy higher than 150 keV, the energy fraction absorbed, in the case of a CdTe (3 mm thick) semiconductor detector, decreases considerably in relation to the absorbed energy fraction in the CsI (10 mm thick) scintillator detector⁽⁵⁾. Therefore, the scintillator crystal-based probes present higher sensitivity for high energies than semiconductor-based probes.

Resolution in energy

Since the pulse height produced in the probe output is proportional to the incident radiation energy deposited in the crystal, the radiation energies spectrum is transformed into a pulse-height spectrum which is recorded by the electronic system. However, it is important to note that a little fluctuation may occur in the pulse-height, corresponding to the same energy deposited, basically because of two factors: the statistical fluctuation of the number of the semiconductor detector charge carriers, or the number of the scintillator detector photons produced by radiation, as well as the influence from noise of the electronic detection system components (detector, preamplifier, filters, etc.). As a result, the energies distribution spectrum obtained with the probe from a monoenergetic source, acquires a Gaussian shape⁽⁴⁾. So, the resolution in energy of the detection system is defined as the photopeak FWHM — full width at half maximum.

Therefore, when the probe is utilized to localize a small radiation source, it is necessary to select a window in the pulse discrimination system, so that the probe detects just the pulses corresponding to the photons emitted directly from the source, and rejects the photons scattered by the source region.

As the radiation incident on the semiconductor detector produces a number of charge carriers interaction about ten times superior to that produced in the scintillator crystal, the statistical fluctuation in the number of carriers is lower, the reason for which a better resolution in energy is obtained with the semiconductor detector, according to the scheme presented on Figure 2⁽⁶⁾.

Spatial resolution

The probe spatial resolution is expressed as the FWHM of the point spread function (PSF), correspondent to the graphic relating the counting rate detected in a punctual source as a function of the lateral distance from the detector central axis, as shown in Figure 3.

So, when the probe is utilized for surveying the region of interest, the spatial resolution reflects the ability of the probe to separately identify the radiation emitted by two punctual sources very close to each other, i.e., in the case of a radioguided surgery, this parameter reflects the ability of the probe to differentiate the SLN activity from the activity in the region of the radiotracer injection site, as per Figure 4. Consequently, amongst all the mentioned parameters, the spatial resolution is a critical parameter for the gamma probe in the task of localizing the SLN.

For determining the differentiation between measures and countings obtained, i.e., the node identification, Britten⁽⁷⁾, based on the probe response as per Figure 4, has determined that the percent value of the difference between the PSF peak value corresponding to the node P, and a point in this curve base, M, which is known as peak reduction value (PRV), where (P–M) / P × 100%, is a value reflecting the probe ability to localize the SLN. Based on laboratory data, Britten has determined that the smallest distance between the injection site and SLN allowing differentiation from countings corresponds to a 25% peak reduction.

MATERIALS AND METHODS

In the present study we have utilized an Europrobe gamma probe, whose characteristics are shown in Table 1. In this probe, the light generated in the CsI(Tl) crystal, due to the interaction with radiation, is converted into electrical pulses in the Si photodiode coupled with the electronic system by means of a low-noise and high input impedance preamplifier.

For studying the probe spatial resolution, we have utilized an experimental arrangement, as per Figure 5. The gamma probe was connected to an also Europrobe electronic system which allows the visualization of the counting rates on a digital display. For studying the sources in an environment similar to that of the human body, we have utilized a phantom constituted of a water thank measuring 250 mm in diameter, and 110 mm in height. On the borders of this thank an acrylic guide was positioned, with a millimetric scale on it, allowing the probe to scan the water surface, identifying the probe central axis lateral distance in relation to the source.

According to the Figure 6, the source of Tc-99m (the radioisotope usually utilized for SLN localization) was placed inside two small acrylic cylinders measuring 7 mm in diameter × 5 mm in height, fixed on acrylic supports which allowed the variation of the source depth in relation to the water surface. Therefore, for studying the probe ability to separately identify the SLN and the injection site region activities, one of the sources (20.42 MBq activity) was utilized to represent the injection sites on the primary tumor, and the other (0.70 MBq activity), to represent the SLN.

Initially, we have studied the variation of the probe spatial resolution as a function of the type of environment (air or water) and distance between the source and the probe window. For this purpose, setting the electronic system of the probe for the rater meter mode, we have measured the counting rates with the probe scanning the water surface, the lateral distance varying at each 5 mm from a Tc-99m (20.42 MBq) source positioned at 15 mm from the probe window. These measurements were performed with the source in the air, and following, with the source in the water. Then, with the source still submerged, measurements were performed with the source at 25 mm from the probe window.

Latter, for studying the variation of the probe spatial resolution power as a result of the use of a collimator on the detector window, we have utilized a lead cylinder with a 1.5 mm-thick wall and a central hole. In this case, besides performing the measurements with the probe without the collimator, we have also performed measurements with the probe utilizing both a collimator with a 2.5 mm-hole, and another with a 3.5 mm-hole. These measurements of counting rates were performed with the probe scanning the water surface, the lateral distance varying at each 5 mm between the probe central axis and the radiotracer injection site, whose positioning was considered as the landmark on the guide, as per Figure 7. In all of the measurements performed, the radiotracer injection site and the SLN, respectively, were placed at 10 mm and 20 mm from the water surface, with a 60 mm gap between them.

Finally, aiming at studying the probe spatial resolution variation as a function of the distance between the radiotracer injection site and the SLN, measurements were performed with the same experimental arrangement previously described, for the injection site and the SLN separated by 30 mm, 40 mm, 50 mm and 60 mm distances, and with the probe utilizing a 3.5 mm-thick collimator.

RESULTS AND DISCUSSION

The results of the study of the probe spatial resolution variation as a function of the type of environment (air or water), as well as the distance between the source and the probe window, are shown in the graphics on Figure 8. This Figure presents the PSF obtained for different environments and distances between the source and the probe window. Based on each curve, the FWHM was determined, as per Table 2. The results analysis demonstrates that a change in the type of environment where the source is localized, i.e., from air to water, implies a strong deterioration of the FWHM, that is to say, the resolution worsens, increasing about 48%. This increase in the FWHM value is a result of the radiation photons scattering in the water. On the other hand, the results also demonstrate that a 10 mm increase in the distance between the source and the probe window, even in the water, causes little deterioration in the FWHM value (about 1% increase) when compared with the result obtained with the change in the source environment.

The results of the study of the probe spatial resolution power variation as a function of the collimation on the detector window are shown in the graphics included on Figure 9 and Table 3. The results analysis demonstrates that the utilization of collimators with 3.5 mm- and 2.5 mm-holes results in an increase in PRP of respectively 283% and 376%, in comparison with the PRP determined with the probe without collimator. This demonstrates that the use of a collimator on the probe window contributes to an accurate SLN identification.

The results of the study of the probe spatial resolution variation as a function of the distance between the radiotracer injection site and the SLN, with a 3.5 mm-hole collimator on the probe, are shown in the graphics included on Figure 10 and Table 4. The analysis of these results demonstrates that as the distance between the injection site and the SLN is reduced from 60 mm to 30 mm, there is a 45% decrease in the spatial resolution power as a result of the counting rates superposition. However, it is important to note that, even for a 30 mm distance between the injection site and the SLN, a precise localization of the SLN is feasible, according to Britten⁽⁷⁾.

An accurate localization of the SLN in the radioguided surgery is essential for a precise determination of the degree of involvement of the lymphatic basin near the primary tumor. Therefore, the study of the gamma probe spatial resolution allows the evaluation of the actual probe potential in the task of localizing the SLN.

The present study demonstrates that the radiation scattering in the environment has a great influence on the probe spatial resolution power, difficulting the localization of the SLN in deeper regions. Additionally, one may also conclude that the utilization of a collimator on the probe window increases its resolution power, contributing to an accurate identification of the SLN, in spite of causing a decrease in the probe detection efficiency. Finally, it was shown that the Europrobe probe can identify a SLN localized at up to 30 mm from the radiotracer injection sites.

REFERENCES

Received January 11, 2006.

Accepted after revision March 15, 2006.

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