The LSO/APD array as a possible detector for in-beam PET in hadron therapy

Kapusta, M.; Crespo, Paulo; Wolski, D.; Heidel, K.; Heinrich, L.; Hutsch, J.; Pawelke, Jörg; Sobiella, M.; Trzcińska, A.; Moszyński, M.; Enghardt, W.

doi:10.1109/tns.2004.832318

Cited by 10 publications

(5 citation statements)

References 14 publications

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“…This was a major achievement, since it demonstrated: 1) the in-beam imaging capability of this detector type and 2) the sufficient radiation hardness of such detectors to be operated at a radiotherapy treatment site. For completeness, we mention that an activation of LSO in therapeutical irradiations can be ruled out according to the experiments outlined in [9]. In summary, the obtained results indicate that LSO is a scintillator material suitable for in-beam PET.…”

Section: Discussionmentioning

confidence: 71%

“…Each detector consists of 32 LSO crystals (2.15 2.15 15 mm each) coupled individually to the 4 8 pixels of an S8550 Hamamatsu APDA with silicon glue [9]. For every detected coincidence, all 64 energy channels were read, together with the coincidence time between the two detectors and, in addition, one channel containing a digital signal provided by the synchrotron (high for spill on, i.e., beam extraction, s, low for spill off, i.e., pause between extractions, s).…”

Section: Methodsmentioning

confidence: 99%

“…For every detected coincidence, all 64 energy channels were read, together with the coincidence time between the two detectors and, in addition, one channel containing a digital signal provided by the synchrotron (high for spill on, i.e., beam extraction, s, low for spill off, i.e., pause between extractions, s). This synchrotron signal allows, as necessary during in-beam imaging, to select only the data acquired during the pauses between the extractions, hence reducing the background caused by random coincidences of prompt -rays from nuclear reactions as the beam penetrates the target [9], [10]. The reconstructed images presented here took into account only data acquired between beam extractions.…”

Section: Methodsmentioning

confidence: 99%

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First in-beam PET imaging with LSO/APD array detectors

Crespo

Kapusta

Pawelke

et al. 2004

IEEE Trans. Nucl. Sci.

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The performance and in-beam imaging capabilities of two position-sensitive -ray detectors consisting of Hamamatsu avalanche photodiode arrays (S8550) individually coupled to crystals of cerium-doped lutetium oxyorthosilicate (LSO) are presented. The two detectors were operated in coincidence at the medical beam line of the Gesellschaft für Schwerionenforschung, in Darmstadt, Germany. In a first set of experiments, their imaging performance was tested before, during, and after the irradiation of phantoms of polymethylmethacrylate with carbon ion beams with fluences equivalent to 1000 typical daily therapeutic fractions. Only minor energy, time, and spatial resolution deterioration was observed, with the initial values being recovered after stopping the irradiation. A second set of experiments successfully imaged the depth distribution of positron emitter radionuclides created in a phantom that stopped the high-energy carbon ion beam. The particular details for the in-beam PET acquisition are shortly outlined. The obtained results show that LSO is a suitable material for in-beam PET and that its coupling with avalanche photodiode arrays is feasible for a PET system dedicated to in-beam monitoring of ion therapy.Index Terms-Avalanche photodiode (APD), ion therapy, lutetium oxyorthosilicate (LSO), positron emission tomography (PET), proton therapy.

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Section: Discussionmentioning

confidence: 71%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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First in-beam PET imaging with LSO/APD array detectors

Crespo

Kapusta

Pawelke

et al. 2004

IEEE Trans. Nucl. Sci.

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“…12. The coincidence timing histogram obtained with software CFD (4) and with the DiSER method (3). The FWHM of timing histogram obtained by using software CFD was 601 ps, and the FWHM obtained by using the DiSER method was 692 ps.…”

Section: B Timing Determinationmentioning

confidence: 99%

Advantages of Digitally Sampling Scintillation Pulses in Pileup Processing in PET

Wang

Xie

Chen

et al. 2012

IEEE Trans. Nucl. Sci.

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A novel digital signal processing method called digital-single-event-reconstruction (DiSER) is proposed to detect pileups, and to recover the timing and the energy information of each single event from a pileup. For each digitized waveform, the DiSER method can distinguish multi-event pileups from single-event pulses by counting the leading edges in a scintillation's duration. Leading edges are identified from the derivative of the waveform. Each leading edge and its following tail are utilized to reconstruct the scintillation pulses in a pileup. Two or more reconstructed single-event pulses can be retrieved from a detected pileup. Consequently, the timing and the energy information of the single event could be derived from the reconstructed pulse. Compared to the conventional pulse processing method, the DiSER method significantly increases the counts of coincidence events in high count rate cases. The energy spectrums, coincidence timing histograms and flood maps obtained by the DiSER method and the conventional method are compared. The effect of sampling rate on the DiSER performance is investigated as well. The experimental results suggest that the DiSER method is a promising digitally sampling scintillation pulses technique for pileup processing in PET.Index Terms-Digital signal processing, pileup, positron emission tomography (PET), scintillation pulse.

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“…These requirements are a high detection efficiency for annihilation radiation, a fast scintillator enabling a narrow coincidence time window for the suppression of random coincidences (Enghardt et al 2005, good energy resolution for rejecting Compton-scattered photons, insensitivity against influences from the therapy beam, hardness against hadronic radiation, magnetic field resistance in the case of in-beam PET at rotating beam deliveries, and small volume due to integration reasons and in order to provide flexibility for patient positioning. The combination of crystals of LSO (cerium-doped lutetium oxyorthosilicate, Lu 2 SiO 5 :Ce 3+ ), a fast scintillator with a fluorescence decay constant of 41 ns (Melcher and Schweitzer 1992), coupled to avalanche photodiode arrays (APDA) solves, for imaging small tumours in the head-and-neck region, all the requisites mentioned (Kapusta et al 2004, Crespo et al 2004, Crespo 2005 provided that the implementation of a closed-ring tomograph, or a dual-head tomograph with small gaps, is feasible (Crespo et al 2006a). In addition, the natural background activity of LSO, amounting to approximately 240 Bq cm −3 due to the presence of the isotope 176 Lu (Huber et al 2002), in combination with the very low β +activity densities typically measured during in-beam PET (Enghardt et al 2004a), requires a coincidence time resolution equal or better than 1 ns full width at half maximum (FWHM) at the detector level (Crespo et al 2006b).…”

Section: Bastei and Trends In Pet Scintillator And Detector Technologymentioning

confidence: 99%

Direct time-of-flight for quantitative, real-time in-beam PET: a concept and feasibility study

Crespo¹,

Shakirin²,

Fiedler³

et al. 2007

Phys. Med. Biol.

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We extrapolate the impact of recent detector and scintillator developments, enabling sub-nanosecond coincidence timing resolution (tau), onto in-beam positron emission tomography (in-beam PET) for monitoring charged-hadron radiation therapy. For tau < or = 200 ps full width at half maximum, the information given by the time-of-flight (TOF) difference between the two opposing gamma-rays enables shift-variant, artefact-free in-beam tomographic imaging by means of limited-angle, dual-head detectors. We present the corresponding fast, TOF-based and backprojection-free, 3D reconstruction algorithm that, coupled with a real-time data acquisition and a fast detector encoding scheme, allows the sampled beta+-activity to be visualized in the object during the course of the irradiation. Despite the very low statistics scenario typical of in-beam PET, real-treatment simulations show that in-beam TOF-PET enables high-precision images to be obtained in real-time, either with closed-ring or with fixed, dual-head in-beam TOF-PET systems. The latter greatly alleviates the installation of in-beam PET at radiotherapeutic sites.

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The LSO/APD array as a possible detector for in-beam PET in hadron therapy

Cited by 10 publications

References 14 publications

First in-beam PET imaging with LSO/APD array detectors

First in-beam PET imaging with LSO/APD array detectors

Advantages of Digitally Sampling Scintillation Pulses in Pileup Processing in PET

Direct time-of-flight for quantitative, real-time in-beam PET: a concept and feasibility study

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