Personnel Dosimetry is a key part of any radiation safety program. The dosimeter’s primary use is to determine doses to individuals who are exposed to radiation on the job by measuring the absorbed radiation energy. These devices are worn on the chest or abdomen, with specialized dosimeters available for other areas of the body such as the extremities.
Federal and State regulations mandate occupational exposure monitoring for a variety of reasons. These regulations can vary based on access to radiation or high radiation areas, quarterly or annual limits, or other requirements mandated by the regulating body.
There are dozens of reasons outside of these regulations why personnel dosimetry monitoring is important for the health and safety of occupationally exposed personnel, but it can be difficult to know where to begin when implementing your own program. There are regulations to navigate, staff to train on how to wear and read their badges, and the constant administrative upkeep required to monitor incoming dose reads and to ensure that your program is compliant.
Versant Physics specializes in personnel dosimetry program management, with a trained technical support team ready to tackle compliance issues and monitoring, badge administration—including initializing for new wearers, adding and removing wearers, read day reminders, and monthly reporting—and training.
“Our clients range from less than 10 badges to over 1000 badges, and include Instadose+, ring dosimeters, and TLD’s,” says Spencer Vanderweele, Versant Physics’ lead Technical Support Specialist. “It is important for our wearers to transmit readings on a regular basis to ensure each badge is functioning as expected. Regular readings also help us to confirm that each badged worker is following their ALARA practices to keep exposures as low as reasonably achievable.”
To manage the back end of dosimetry programs for all Versant Physics accounts, Vanderweele relies on the company’s proprietary software Odyssey. The cloud-based software was designed to simplify every aspect of a radiation safety program, with an entire module devoted to personnel dosimetry.
“With Odyssey we can view exact numbers at a glance, or dive deep into records if there are ever any concerns,” says Vanderweele. “I utilize the Personnel Dosimetry module to manage most accounts, and consistently find myself diving into the records through the Query Builder. This feature allows you to set your own parameters for record results based on active participants and allows you to filter out participants who required updated readings to more easily follow up.
Odyssey’s Query-builder feature.
“The new Form Generator has [also] been an incredible help. This feature allows the user to pull Form-5s, pre-sign, and even email directly to participants all from one page! This saves me or the RSO time (and their wrist!) by allowing us to pre-sign thousands of documents with the click of a button!”
The module is made up of a series of customizable widgets that allow users to visualize pre-set metrics for at-a-glance monitoring. Users can view recent logins and read activity, latest abnormal readings, and set up a User Watch List for wearers likely to exceed internal or annual dose limits. These features, including the Query-Builder and Form Generator, simplify and streamline the badge management process for the busy RSO or badge administrator.
Odyssey’s Personnel Dosimetry module dashboard.
In fact, Vanderweele says, without Odyssey, managing a single client would likely be a team effort.
“It would have a tremendous impact on the timeliness of our client response and ability to provide relevant, up-to-date information. Simply counting the number of individual badges, of all types, would be a huge task on its own without Odyssey. I know because Odyssey was not available to me when I first started at Versant Physics. But now, Odyssey allows me to put together complex and specific reports with ease, all while managing several accounts.”
The benefits of using a seasoned badge management team like Versant Physics, combined with the efficient power of Odyssey, are numerous. “Versant Physics’ background allows us to cater to our client’s specific needs,” says Vanderweele. “From our regulatory expertise to our technical support systems, Versant Physics will take the guess work out of your radiation safety program.”
Contact sales@versantphysics.com to learn more about our personnel dosimetry management process, to order badges, and pricing details.
Author Bio: Since 1981, Andrew Karam, PhD, CHP has worked primarily in areas related to radiation safety as a radiation safety professional, a scientist and professor, a consultant, or an instructor. He is currently a Fellow of the Health Physics Society and a Homeland Security Scientific Advisor for Mirion Technologies. He is also a writer, with over 200 encyclopedia articles, a variety of scientific and technical articles, several books in print, and an 8-book series (Controversies in Science, Facts on File) in the works. Learn more at www.andrewkaram.com.
After Fukushima: Training Medical Responders to Care for Contaminated Patients
In early April 2011 I got a phone call from a non-governmental organization (NGO) called NYC Medics – they were wondering if I was willing to travel to Japan to help provide training for medical and emergency responders who were working in and caring for patients coming from areas contaminated by radioactive fallout from the reactor meltdowns. It took me about two seconds to agree – a week or so later I was on an ANA flight to Tokyo, to meet up with the other two members of our group. I brought with me some of my radiation detectors and a dosimeter for each person in our group – I assumed the informal role of Radiation Safety Officer for our group while we were in the Fukushima area.
In a few phone calls (in those pre-Zoom days) with our Japanese hosts and NYC Medics we settled on a course of action when we arrived. Our mission was to provide training, but we agreed that we wanted to work from the standpoint of personal knowledge of conditions in the affected areas as opposed to simply telling attendees “This is what the International Atomic Energy Agency says” or “This is what the Japanese government says.” So we agreed to start our trip with three days in the areas that were slammed with the tsunami and subject to fallout from the reactor meltdowns. (I was hoping to visit the nuclear power station, but I suspect my colleagues (a physician and an expert in the psychosocial impacts of WMD and similar disasters) were somewhat relieved.) After returning to Tokyo, our plan was to spend a day developing our training and the last week or so of our time in Japan would be spent presenting it to a variety of audiences throughout northern Japan – as far south as Kamakura and as far north as Sapporo on the island of Hokkaido.
The time we spent in the areas affected by the tsunami and radioactive fallout was heartbreaking. Areas that had been inundated by the tsunami were devastated – acres of mud littered with debris, reefs of battered cars, and the occasional shell of a building left standing. It was sobering to realize that each car represented one or more people trying to flee the tsunami who had failed; even more sobering was the field we passed that had a line of men, each holding a bamboo pole, probing the mud for bodies. We spent three days in this area, visiting shelters, meeting with mayors, talking with physicians, and trying to wrap our minds around what had happened.
One of my objectives was to make what radiation measurements I could, and it was clear that we spent much of our time in areas where the fallout plume had settled to the ground. Not only were radiation dose rates close to 100 times higher than what’s normal in most of Japan (as high as about 0.5 mR/hr), but I was also able to identify I-131 and I-133, both with half-lives far too short to occur naturally and both produced in copious quantities by nuclear fission. I also identified Cs-137 and Cs-134, two other fission products, and a later analysis of the spectra I collected revealed a few more nuclides as well.
We returned to Tokyo on one of the first shinkansen (bullet trains) to leave Sendai after the earthquake and spent the next day figuring out what we wanted to say and how we wanted to say it. As the group’s health physicist I spoke about how to safely treat contaminated patients, our physician talked about the medical effects of radiation and contamination exposure, and our psycho-social researcher talked about those aspects of major radiological events. And, since we had some lectures that were to be one hour and some that were slated for two, we also discussed whether or not to have two separate sets of slides (we finally decided to go with a single set, just to include more details for the longer lectures). Finally, we also decided to avoid lecturing our audience but, rather, to treat our sessions more as a sort of refresher training.
For my part of the training, I focused on good radiological work practices when working with contaminated patients. Contamination control, for example – I discussed the fact that Alexander Litvenenko was shedding Po-210 with every hair shed from his head and his body, unbeknownst to any of those caring for him. In spite of that, none of the hospital staff had a significant intake of polonium because they were simply taking the normal precautions that they took with any patients suffering from an unknown ailment; that the standard precautions they already knew how to take were perfectly capable of protecting them from radioactive contamination as well as from the more common microbes. Then I’d ask them if they ever cared for nuclear medicine patients – in every group there were several – and I’d mention that the lowest diagnostic radiopharmaceutical dose carried more radioactivity than even most heavily contaminated patients. The message was that we weren’t trying to teach them anything new – just to remind them that they already knew what to do, they just might not realize it.
The trauma bay at the Fukushima Medical University, April 2011
I went through the standard time-distance-shielding explanations as well as other basics (types of radiation, health effects, natural radiation, and so forth) as well as a quick discussion of the radiological conditions we’d seen in the Fukushima area. But the main focus of my part of the lecture was a review of good radiation safety work practices that was aimed at helping them to feel comfortable caring for their patients. In large part, this was because of surveys conducted shortly after the September 11 attacks, showing that up to 30% of medical responders might decide not to go to work in the event of a radiological attack, citing fears of the health effects on them and their families – we felt it important to try to assuage any such concerns among those in our audience.
The medical discussion came next, beginning with a brief discussion of the manner in which radiation affects the body and the amount of exposure required to cause problems; our physician also reviewed the nuclides we had identified during our time in the plume area and how those affected the body. She also spent some time talking about recognizing radiation injury, the symptoms of Acute Radiation Syndrome, and a bit about radiation’s role in inducing cancers, as well as the normal latency period for such cancers. And then she closed this part with a brief discussion of the effects of radiation on pregnancy; there are estimates that, in the aftermath of Chernobyl, European women had over 100,000 unnecessary therapeutic abortions, primarily because their physicians didn’t have a good understanding of the reproductive effects of radiation exposure – given our audience, we wanted to make sure they all had a good understanding of the topic.
Finally, we closed with a discussion of the psychological effects noted in earlier radiological and nuclear accidents, helping the audience to understand what to look for in their patients as well as among their patients’ families. Here, too, we could draw on what we had seen earlier during our visits to the towns, shelters, and hospitals, as well as how people often reacted to being screened, being ordered to evacuate, and so forth. This part closed with a discussion of healthcare professionals and how they often reacted to working with patients whom they feared might pose a risk to them. After we were done, we opened the floor for any questions.
Over the course of about a week we gave 7 presentations in five different cities to groups as small as 50 and as large as 250 people – we figured we reached over 1000 people in these talks. One concrete outcome was that the organization that sponsored our time in Japan (and the one that had asked NYC Medics for our help) told us that they had authorized admitting up to 5000 patients from contaminated areas to their hospitals – this freed up needed beds closer to the accident site and elsewhere in Japan.
Dr. Andrew Karam presenting a lecture in Tokyo, Japan | April 2011
One of the biggest adjustments for all of us was working with translators – we never did decide if it was easier to work with simultaneous or sequential translation. Early on we realized that it was important to sit down with our translators before each lecture (we had different sets for each venue) to make sure they understood the scientific terminology as well as finding out their preferences and how we could make their job easier. It was an interesting experience for all of us!
When all was said and done, we’d spent 12 days in Japan, most of which we were busy for 12-16 hours. We logged over 50 aftershocks stronger than magnitude 5, with the strongest being a 6.0 our first night there (I slept through it), and we each picked up more radiation dose on the flights over and back than during our time on the ground. I’m not sure about my colleagues – I was so tired that I slept through virtually the entire flight back from Tokyo to New York. All in all it was exhausting – but we all agreed it was also one of the high points of our careers. One that we hope to never repeat.
The views, thoughts, and opinions expressed in the text belong solely to the author, and do not necessarily reflect the views and opinions of Versant Physics.
Odyssey software helps RSOs and EHS personnel manage their organization’s radiation equipment, and makes it easy to track the storage and disposal of radioactive waste. Click below to view our webinar on 4 of Odyssey software’s modules, recorded September 3rd at 2PM EST.
If you’d like to learn more, check out our webinar on the Personnel Dosimetry, Machine Management, Waste Management, and Training modules. Contact Andrew Vasquez at andrew.vasquez@versantphysics.com to schedule a demo or start your free trial!
Versant Physics own Dr. Darrell Fisher, Ph.D., and Misty D. Liverett, M.S., CNMT recently completed a white paper that supports the belief that nuclear medicine extravasation events should be assessed and characterized.
Recorded Live Monday, June 29 | Presented by Ethan Zink & Katelyn Waters
This week our team members Ethan Zink and Katelyn Waters gave a presentation on Odyssey software in an engaging and informative webinar. Their discussion highlighted four of Odyssey’s 11 modules and provided insight into attendee questions regarding everything from automated dosimetry data imports to purchasing and customer support.
If you missed it, we’ve highlighted the top 5 takeaways below:
Comprehensive & Easy-to-Use Modules Odyssey modules were designed by radiation safety experts to simplify and streamline complex processes. From Personnel Dosimetry to Machine Management, Inventory Tracking to Online Training, each module serves as a tool to help efficiently manage the ins-and-outs of radiation safety and EHS programs.
Customizable Software No matter the size and scale of your organization or radiation safety program, our team of specialists provide ongoing maintenance, email, phone, and online customer support, as well as feature customization. Odyssey can be tailor-made to your specific needs.
Cost and Time Savings Odyssey’s flexible digital platform and innovative modules provide users with valuable cost and time savings. Our clients see a reduction in overall program costs and spend less time on burdensome administrative tasks, allowing them to focus on big picture issues.
How to Buy Odyssey can be purchased on a monthly or annual basis with volume discounts available. Select the modules that fit your program needs or purchase a full license with all 11 modules.
Free Sandbox Trials Not sure if Odyssey is right for you? We offer free sandbox trials of various modules where you can input your own data and spend time working in the software.
Contact Andrew Vasquez at andrew.vasquez@versantphysics.com for more information on individual modules, pricing, or starting a sandbox trial.
11May2020
Medical Physics Jaclyn Carroll, Medical Physics Resident0 comment
This year, medical physicists around the world celebrate the first ever International Medical Physics Week (IMPW). As some of you may already know, medical physicists also celebrate an International Day of Medical Physics (IDMP) on November 7th. The International Organization for Medical Physics (IOMP) organizes and promotes both, with the intention of enhancing the field’s importance, increasing awareness about the role medical physicists play in the lives of patients, and increasing implementation of programs. In honor of the first ever IMPW there are planned activities around the world, including virtual educational sessions, social media chats and campaigns, and a daily webinar on topics ranging from diagnostic imaging and nuclear medicine to Monte Carlo modeling.
As I reflect on what it means to be a part of the global community of medical physicists, I am truly humbled by the spectrum of expertise that we have. Just by glancing at the topics covered in the webinars, it is abundantly clear that the medical physics contribution to the healthcare field is much larger than what each of us do on a daily basis. In part, this week is important because it gives us an opportunity to connect with and learn from one another. The fact that we all have a unique and valuable perspective to offer one another has been the single most important takeaway from my time as a resident medical physicist.
Cynthia McCullough, President of the AAPM, and guest speaker Amy Lynch covered this topic well in the President’s Symposium at the 2019 AAPM Annual Meeting. They both spoke about the importance of diversity, though not only in the most common ways you may expect. Amy Lynch specifically covered the topic of generational diversity, and said, “we have to step up and work with generational intelligence and intellectual humility in order to come up with the very best ideas.” Easier said than done!
Despite the challenge, I think that this concept can be applied even more broadly in the context of medical physics. Recent articles in Medical Physics and the Journal of Applied Clinical Medical Physics feature discussions among physicists who see our roles changing drastically in the coming years. Advances in automation will likely challenge us to work more closely with software engineers and IT professionals. Changes in reimbursement models have the potential to allow us to work more closely with physicians. How are we to handle this? I hope that we can take it in stride and adapt, recognizing that the collection of different perspectives will move the field of medical physics forward.
Perhaps, at the very least, this week will give us an opportunity to tell yet another family member or friend what a medical physicist does. Or, we could look at our first IMPW as a challenge to continue developing this great field we are a part of, by connecting with one another. I encourage us all to seek out a new interest in the broader discipline of medical physics, take an online course, listen to a webinar you might not usually join, or maybe simply ask for a fresh opinion on a process you’ve always done a certain way. Happy IMPW!
For more information about IMPW or a list of activities and participants, visit https://www.iomp.org/impw/.
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