Effect of X-ray dose rates higher than 8 Gy/min on the functioning of cardiac implantable electronic devices

Nakamura, Kazuhiko; Aoyama, Tomoo; Kaneda, Naoki; Otsuji, Masashi; Minami, Yoshitaka; Sakuragi, Ami; Nakamura, Masaru

doi:10.1093/jrr/rraa016

Cited by 11 publications

(8 citation statements)

References 22 publications

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“…The application of PLA in medical instruments potentially opens up its possibility for internal dosimetry, yet the dose levels for radiotherapy thus far are generally no more than 100 Gy [ 16 , 17 ]. However, potentials still lie in the dosimetry in X-ray facilities, where the dose rate could reach 480 Gy/h [ 18 ], and in food packaging and sterilization industries, where the dose applied could reach 10 kGy [ 5 ] and above for chem-bio agent defeat. Significantly higher levels of gamma dose must be considered when deciding on the choice of polymer materials for radiation-sterilized products [ 19 ]–for the most part through 100 kGy and even toward 4000 kGy depending on the specific polymer chosen.…”

Section: Problem Formulation-research Framework/objectives On Advanci...mentioning

confidence: 99%

PLA Renewable Bio Polymer Based Solid-State Gamma Radiation Detector-Dosimeter for Biomedical and Nuclear Industry Applications

Jiang

DiPrete²,

Taleyarkhan³

2022

Sensors

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Polylactic acid (PLA) as a “green,” renewable corn-soy based polymer resin was assessed as a novel solid-state detector for rapid-turnaround gamma radiation dosimetry in the 1–100 kGy range–of significant interest in biomedical and general nuclear industry applications. Co-60 was used as the source of gamma photons. It was found that PLA resin responds well in terms of rheology and porosity metrics with an absorbed gamma dose (Dg). In this work, rheological changes were ascertained via measuring the differential mass loss ratio (MLR) of irradiated PLA placed within PTFE-framed (40 mm × 20 mm × 0.77 mm) cavities bearing ~0.9 g of PLA resin and pressed for 12–16 min in a controlled force hot press under ~6.6 kN loading and platens heated to 227 °C for the low Dg range: 0–11 kGy; and to 193 °C for the extended Dg range: 11–120 kGy. MLR varied quadratically from 0.05 to ~0.2 (1σ ~ 0.007) in the 0–11 kGy experiments, and from 0.05 to ~0.5 (1σ ~0.01) in the 0–120 kGy experiments. Rheological changes from gamma irradiation were modeled and simultaneously correlated with void-pocket formations, which increase with Dg. A single PLA resin bead (~0.04 g) was compressed 5 min at 216 °C in 0–16 kGy experiments, and compressed 2 min at 232 °C in the 16–110 kGy experiments, to form sturdy ~100 µm thick wafers in the same press. Aggregate coupon porosity was then readily measurable with conventional optical microscope imaging and analyzed with standard image processing; this provided complementary data to MLR. Average porosity vs. dose varied quadratically from ~0 to ~15% in the 0–16 kGy range and from ~0 to ~18% over the 16–114 kGy range. These results provide evidence for utilizing “green”/renewable (under $0.01) PLA resin beads for rapid and accurate (+/−5–10%) gamma dosimetry over a wide 0–120 kGy range, using simple to deploy mass and void measuring techniques using common laboratory equipment.

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Section: Problem Formulation-research Framework/objectives On Advanci...mentioning

confidence: 99%

PLA Renewable Bio Polymer Based Solid-State Gamma Radiation Detector-Dosimeter for Biomedical and Nuclear Industry Applications

Jiang

DiPrete²,

Taleyarkhan³

2022

Sensors

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“…A recent study investigated the effects of x-ray dose rates of 4 to 24 Gy/min on CIED function and found that a dose rate >8 Gy/min would cause a temporary malfunction due to interference. 42 It had been recommended that in low-risk patients with the presence of an ICD and medium-risk patients with CIED, a weekly device check during the RT is recommended. 8 In high-risk patients, device evaluation within 24 hours after each fraction is needed.…”

Section: Management Of Commonly Seen Implanted Devices In Rt Patientsmentioning

confidence: 99%

A Review and Analysis of Managing Commonly Seen Implanted Devices for Patients Undergoing Radiation Therapy

Chan

Young

Gelblum

et al. 2021

Advances in Radiation Oncology

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Purpose This review article aims to consolidate information regarding existing and emerging implanted devices used in patients undergoing radiation therapy and to categorize levels of attention needed for each device, including which devices require monitoring throughout treatment. Methods and Materials Based on the collective information from scholar searches, manufacturers’ technical reports, and institutional experiences in the past years, commonly present devices in patients with cancer are compiled. This work summarizes cardiac pacemaker, implanted cardiac defibrillator, hepatic pump, intrathecal pain pump, neurostimulator, shunt, loop recorder, and mediport. Three different classifications of implanted devices can be made based on the potential effect of radiation: life-dependent, nonlife-dependent but with adverse effects if overdosed, and devices without electronic circuits. Implanted devices that contain electronic circuits that would be life-dependent or have adverse effects if overdosed, include cardiac pacemakers, implanted cardiac defibrillators, programmable hepatic pumps, pain pumps, neurostimulators, and loop recorders. Results Dose exposure to these devices need to be calculated or measured in vivo , especially for cardiac implanted devices, and they should be minimized to assure continued healthy functioning. Treatment planning techniques should be chosen to reduce entry, exit and internal scatter dose. Lower energy photon beams should be used to decrease potential neutron contamination. Implanted devices without electronic circuits are less of a concern. If a patient is life-dependent on the implanted device, it is not recommended to treat the patient with proton therapy. Conclusions This study reviewed the management of patients with commonly seen implanted devices and summarized a workflow for identifying and planning when a patient has implanted devices. Classifications of implanted devices could help clinicians make proper decisions in regard to patients with specific implanted devices. Lastly, the management of such devices in the era of the pandemic is also discussed in this review article.

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“…FFF beams may induce malfunction depending on the dose rate in vitro [ 14 ]. High dose-rate X-rays may induce overcurrent on the circuit, which creates a high potential risk to CIEDs even if the radiation does not generate secondary neutrons.…”

Section: Management Of Cied Patient and Radiotherapymentioning

confidence: 99%

JASTRO/JCS Guidelines for radiotherapy in patients with cardiac implantable electronic devices

Ohno

Soejima²,

Sekiguchi

et al. 2020

Journal of Radiation Research

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This publication is an English version of the Japanese Society for Radiation Oncology (JASTRO) and The Japanese Circulation Society official guidelines for patients with cardiac implantable electronic devices (CIEDs). Several radiotherapy-associated malfunctions have been reported for CIEDs such as pacemakers and implantable cardioverter-defibrillators. Accordingly, guidelines for radiotherapy in patients with CIEDs have been issued by other countries and societies. In August 2010, JASTRO published the ‘Radiotherapy Guidelines for Patients with Pacemakers and Implantable Defibrillators’ (hereafter referred to as the former guidelines). Given new findings in this decade, a multidisciplinary working group of radiation oncologists, medical physicists, radiation therapists and cardiologists jointly reviewed and revised the former guidelines.

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Effect of X-ray dose rates higher than 8 Gy/min on the functioning of cardiac implantable electronic devices

Cited by 11 publications

References 22 publications

PLA Renewable Bio Polymer Based Solid-State Gamma Radiation Detector-Dosimeter for Biomedical and Nuclear Industry Applications

PLA Renewable Bio Polymer Based Solid-State Gamma Radiation Detector-Dosimeter for Biomedical and Nuclear Industry Applications

A Review and Analysis of Managing Commonly Seen Implanted Devices for Patients Undergoing Radiation Therapy

JASTRO/JCS Guidelines for radiotherapy in patients with cardiac implantable electronic devices

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