Background – Posterior subcapsular cataract is a tissue reaction commonly found among professionals exposed to ionizing radiation.

Objective – To assess the prevalence of cataract in professionals working in hemodynamics in Brazil.

Methods – Professionals exposed to ionizing radiation (group 1, G1) underwent slit lamp examination with a biomicroscope for lens examination and compared with non-exposed subjects (group 2, G2). Ophthalmologic findings were described and classified by opacity degree and localization using the Lens Opacities Classification System III. Both groups answered a questionnaire on work and health conditions to investigate the presence of risk factors for cataract. The level of significance was set at 5% (p < 0.05).

Results – A total of 112 volunteers of G1, mean age of 44.95 (±10.23) years, and 88 volunteers of G2, mean age of 48.07 (±12.18) years were evaluated; 75.2% of G1 and 85.2% of G2 were physicians. Statistical analysis between G1 and G2 showed a prevalence of posterior subcapsular cataract of 13% and 2% in G1 and G2, respectively (0.0081). Considering physicians only, 38% of G1 and 15% of G2 had cataract, with the prevalence of posterior subcapsular cataract of 13% and 3%, respectively (p = 0.0176). Among non-physicians, no difference was found in the prevalence of cataract (by types).

Conclusions – Cataract was more prevalent in professionals exposed to ionizing radiation, with posterior subcapsular cataract the most frequent finding.

Barbosa, A., Medeiros, R., Corpa, A., Higa, F., Souza, M., Barbosa, P., … Cantarelli, M. (2019). Prevalence of Lens Opacity in Interventional Cardiologists and Professional Working in the Hemodynamics in Brazil. Arquivos Brasileiros de Cardiologia, 112(4), 392–399. https://doi.org/10.5935/abc.20190028 

Purpose – The International Commission on Radiological Protection (ICRP) recently recommended reducing the occupational equivalent dose limit for the lens of the eye. Based primarily on a review of epidemiological data, the absorbed dose threshold is now considered to be 0.5 Gy independent of dose-rate and severity of opacification, reduced from the previous threshold of 2 Gy. However, direct mechanistic evidence to support an understanding of the underlying molecular mechanisms of damage is still lacking. To this end, we explored the effects of a broad dose-range of ionizing radiation exposure on gene expression changes in a human lens epithelial (HLE) cell-line in order to better understand the shape of the dose–response relationship and identify transcriptional thresholds of effects.

Methods – HLE cells were exposed to doses of 0, 0.01, 0.05, 0.25, 0.5, 2, and 5 Gy of X-ray radiation at two dose rates (1.62 cGy/min and 38.2 cGy/min). Cell culture lysates were collected 20 h post-exposure and analyzed using whole-genome RNA-sequencing. Pathways and dose-thresholds of biological effects were identified using benchmark dose (BMD) modeling.

Results – Transcriptional responses were minimal at doses less than 2 Gy. At higher doses, there were a significant number of differentially expressed genes (DEGs) (p≤.05, fold change≥|1.5|) at both dose rates, with 1308 DEGs for the low dose rate (LDR) and 840 DEGs for the high dose rate (HDR) exposure. Dose–response modeling showed that a number of genes exhibited non-linear bi-phasic responses, which was verified by digital droplet PCR. BMD analysis showed the majority of the pathways responded at BMD median values in the dose range of 1.5–2.5 Gy, with the lowest BMD median value being 0.6 Gy for the HDR exposure. The minimum pathway BMD median value for LDR exposure, however, was 2.5 Gy. Although the LDR and HDR exposures shared pathways involved in extracellular matrix reorganization and collagen production with BMD median value of 2.9 Gy, HDR exposures were more effective in activating pathways associated with DNA damage response, apoptosis, and cell cycling relative to LDR exposure.

Conclusions – Overall, the results suggest that radiation induces complex non-linear transcriptional dose–response relationships that are dose-rate dependent. Pathways shared between the two dose rates may be important contributors to radiation-induced cataractogenesis. BMD analysis suggests that the majority of pathways are activated above 0.6 Gy, which supports current ICRP identified dose thresholds for deterministic effects to the lens of the eye of 0.5 Gy.

Chauhan, V., Rowan-Carroll, A., Gagné, R., Kuo, B., Williams, A., & Yauk, C. (2019). The use of in vitro transcriptional data to identify thresholds of effects in a human lens epithelial cell-line exposed to ionizing radiation. International Journal of Radiation Biology, 95(2), 156–169. https://doi.org/10.1080/09553002.2019.1539883

Highlights

• A new type of RP glasses with 0.5 mm lead equivalent protection is introduced.
• A BeOSL eye lens dosemeter for photon radiation is characterized.
• A TLD eye lens dosemeter for photon and beta radiation is introduced.
• Dosemeters are integrated in the frame of the glasses behind the lead shielding.

A standardized mechanical interface between dosemeter and RP glasses was introduced.

With the annual dose limit for the lens of the eye being lowered to 20 mSv from 2019, both new efforts to improve radiation protection for this part of the body and new approved dosemeters for official dose monitoring are required. The individual monitoring services at the Helmholtz Zentrum München and Dosilab AG, together with MAVIG, have developed a mechanical interface to integrate eye lens dosemeters into radiation protection glasses. MAVIG has designed a new type of radiation protection glasses featuring this dosemeter interface. The two individual monitoring services have independently developed two new types of eye lens dosemeters for the interface. The Munich solution for the eye lens dosemeter is a BeOSL dosemeter for photon radiation with a new detector element introduced by Dosimetrics GmbH in 2018. The Dosilab approach is based on a TLD dosemeter for photon and beta radiation. This work describes the concepts for radiation protection glasses and interface, the new dosemeters, and presents the performance characteristics of the dosemeters in accordance with IEC requirements.

Hoedlmoser, H., Greiter, M., Bandalo, V., Mende, E., Brönner, J., Kleinau, P., … Figel, M. (2019). New eye lens dosemeters for integration in radiation protection glasses. Radiation Measurements, 125, 106–115. https://doi.org/10.1016/j.radmeas.2019.05.002

Ionizing radiation (IR) damages DNA and other macromolecules, including proteins and lipids. Most cell typescan repair DNA damage and cycle continuously their macromolecules as a mechanism to remove defectiveproteins and lipids. In those cells that lack nuclei and other organelles, such as lensfiber cells and mammalianerythrocytes, IR-induced damage to macromolecules is retained because they cannot be easily replenished.Whilst the life span for an erythrocyte is several months, the life span of a human lens is decades. There is verylimited turnover in lens macromolecules, therefore the aging process greatly impacts lens structure and functionover its lifetime. The lens is a tissue where biomolecular longevity, lifelong retention of its components andcontinued growth are integral to its homeostasis. These characteristics make the lens an excellent model to studythe contribution of retained macromolecular damage over time. Epidemiological data have revealed a significantassociation between exposure to IR, the loss of lens optical function and the formation of cataracts (catar-actogenesis) later in life. Lifestyle, genetic and environmental factors all contribute to cataractogenesis due totheir effect on the aging process. Cataract is an iconic age-related disease in humans. IR is a recognised cause ofcataract and the occupational lens dose limit is reduced from 150 to 20 mGy / year averaged over 5 years (ICRPPublication 118). Understanding the effects of low dose IR on the lens and its role in cataractogenesis is thereforevery important. So we redefine“cataractogenic load”as a term to account for the combined lifestyle, genetic andenvironmental processes that increase biomolecular damage to lens macromolecules leading to cataract for-mation. These processes weaken metabolic defenses, increase post-translational protein modifications, and alterthe lipid structure and content of the lens. IR exposure is a significant insult to the lens because of free radicalgeneration and the ensuing oxidative stress. We support the concept that damage caused by IR compounds theaging process by increasing the cataractogenic load, hereby accelerating lens aging and its loss of function.

Uwineza, A., Kalligeraki, A. A., Hamada, N., Jarrin, M., & Quinlan, R. A. (2019). Cataractogenic load – A concept to study the contribution of ionizing radiation to accelerated aging in the eye lens. Mutation Research-Reviews in Mutation Research, 779, 68-81. doi:10.1016/j.mrrev.2019.02.004

Full text

Objectives – To assess radiation exposure-related work history and risk of cataract and cataract surgery among radiologic technologists assisting with fluoroscopically guided interventional procedures (FGIP).

Methods – This retrospective study included 35 751 radiologic technologists who reported being cataract-free at baseline (1994–1998) and completed a follow-up questionnaire (2013–2014). Frequencies of assisting with 21 types of FGIP and use of radiation protection equipment during five time periods (before 1970, 1970–1979, 1980–1989, 1990–1999, 2000–2009) were derived from an additional self-administered questionnaire in 2013–2014. Multivariable-adjusted relative risks (RRs) for self-reported cataract diagnosis and cataract surgery were estimated according to FGIP work history.

Results – During follow-up, 9372 technologists reported incident physician-diagnosed cataract; 4278 of incident cases reported undergoing cataract surgery. Technologists who ever assisted with FGIP had increased risk for cataract compared with those who never assisted with FGIP (RR: 1.18, 95% CI 1.11 to 1.25). Risk increased with increasing cumulative number of FGIP; the RR for technologists who assisted with >5000 FGIP compared with those who never assisted was 1.38 (95% CI 1.24 to 1.53; p trend <0.001). These associations were more pronounced for FGIP when technologists were located ≤3 feet (≤0.9 m) from the patient compared with >3 feet (>0.9 m) (RRs for >5000 at ≤3 feet vs never FGIP were 1.48, 95% CI 1.27 to 1.74 and 1.15, 95% CI 0.98 to 1.35, respectively; pdifference=0.04). Similar risks, although not statistically significant, were observed for cataract surgery.

Conclusion – Technologists who reported assisting with FGIP, particularly high-volume FGIP within 3 feet of the patient, had increased risk of incident cataract. Additional investigation should evaluate estimated dose response and medically validated cataract type.

Velazquez-Kronen, R., Borrego, D., Gilbert, E., Miller, D., Moysich, K., Freudenheim, J., … Kitahara, C. (2019). Cataract risk in US radiologic technologists assisting with fluoroscopically guided interventional procedures: a retrospective cohort study. Occupational and Environmental Medicine, 76(5), 317–325. https://doi.org/10.1136/oemed-2018-105360

Purpose – To quantify the effects of operator head posture and different types of protective eyewear on the eye lens dose to operators in interventional radiology (IR).

Methods – A deformable computational human phantom, Rensselaer Polytechnic Institute (RPI) Adult Male, consisting of a high‐resolution eye model, was used to simulate a radiologist who is performing an interventional radiology procedure. The radiologist phantom was deformed to a set of different head postures. Three different protective eyewear models were incorporated into the posture‐deformed radiologist phantom. The eye lens dose of the radiologist was calculated using the Monte Carlo code, MCNP. Effects of the radiologist’s head posture and different types of protective eyewear on eye lens doses were studied. The relationship between efficacy of protective eyewear and the radiologist’s head posture was investigated. Effects of other parameters on efficacy of protective eyewear were also studied, including the angular position of the radiologist, the gap between the eyewear and the face of the radiologist, and the lead equivalent thickness.

Results – The dose to both lenses decreased by 80% as the head posture moved from looking downward to looking upward. Sports wrap glasses were found to reduce doses further than the other two studied models. The efficacy of eyewear was found to be related to radiologist’s head posture as well. When the radiologist was looking up, the protective eyewear almost provided no protection to both lenses. Other factors such as the face‐to‐eyewear distance and the lead equivalent thickness were also found to have an impact on the efficacy of protective eyewear. The dose reduction factor (DRF), defined as the ratio of the dose to the lens without protection to that with protection, decreased from 4.25 to 1.07 as the face‐to‐eyewear distance increased. The DRF almost doubled when the lead equivalent thickness increased from 0.07 to 0.35 mm. However, further increase in lead equivalent thickness showed little improvement in dose reduction.

Conclusion – The radiologist’s head posture has a significant influence on the eye lens dose in IR. Sports wrap protective eyewear which conforms to the curve of the face is essential for the radiation protection of the eye lens. However, the radiologist’s head posture and other exposure parameters should be considered when evaluating the protection of the radiologist’s eyes.

Mao, L., Liu, T., Caracappa, P., Lin, H., Gao, Y., Dauer, L., & Xu, X. (2019). Influences of operator head posture and protective eyewear on eye lens doses in interventional radiology: A Monte Carlo Study. Medical Physics, 46(6), 2744–2751. https://doi.org/10.1002/mp.13528

ndi, totam, facilis laudantium cum accusamus ullam voluptatibus commodi numquam, error, est. Ea, consequatur.

The main effect of ionizing radiation on the eyes is the onset of posterior cortical and subcapsular cataracts. Recent studies have raised questions about the mechanism of ocular damage and the threshold dose for the onset of such effects. Currently, operators may be exposed to ionizing radiation during surgical procedures. It has been estimated that urologists can be exposed to an annual dose close to or above 20 mSv/year. The aim of our study was to evaluate the frequency of cataracts in a group of professional radiological operators to verify their possible association with the radiation dose to the crystalline lens and the tasks performed. The records of 73 health workers exposed to ionizing radiation were reviewed. The average annual dose to the crystalline lens, the number of years of exposure, and the presence of radiation-compatible opacities were assessed for all operators. Lenticular opacities were observed in 16.4% of subjects. The presence of alterations was associated with exposure doses below 10 mSv and > 10 years’ experience in fluoroscopically guided procedures. Based on our results, protection of the crystalline lens against exposure to ionizing radiation by means of goggles is recommended. In addition, examination of the lens via slit lamp examination is recommended for all operators involved in interventional procedures with the current levels of radiation exposure.

Coppeta, L., Pietroiusti, A., Neri, A., Spataro, A., De Angelis, E., Perrone, S., & Magrini, A. (2019). Risk of radiation-induced lens opacities among surgeons and interventional medical staff. Radiological Physics and Technology, 12(1), 26–29. https://doi.org/10.1007/s12194-018-0487-9