Changing Patterns in the Performance of Fluoroscopically Guided Interventional Procedures and Adherence to Radiation Safety Practices in a U.S. Cohort of Radiologic Technologists

Hyeyeun Lim; Martha S Linet; Miriam E Van Dyke; Donald L Miller; Steven L Simon; Alice J Sigurdson; Cari M Kitahara

doi:10.2214/AJR.15.15979

. Author manuscript; available in PMC: 2021 Jun 10.

Published in final edited form as: AJR Am J Roentgenol. 2016 Aug 30;207(6):1350–1359. doi: 10.2214/AJR.15.15979

Changing Patterns in the Performance of Fluoroscopically Guided Interventional Procedures and Adherence to Radiation Safety Practices in a U.S. Cohort of Radiologic Technologists

Hyeyeun Lim ¹, Martha S Linet ¹, Miriam E Van Dyke ², Donald L Miller ³, Steven L Simon ¹, Alice J Sigurdson ¹, Cari M Kitahara ¹

PMCID: PMC8190773 NIHMSID: NIHMS1033682 PMID: 27575031

Abstract

BACKGROUND:

Historical information is limited on changes in procedures performed radiation safety practices by radiologic technologists during Fluoroscopically-guided interventional procedures (FGIPs).

METHODS:

Our study included 12,571 U.S. radiologic technologists who were certified for at least two years in 1926 – 1982 and reported in a 2012–13 survey that they ever performed or assisted with FGIPs and completed a mailed questionnaire in 2013–14 describing their detailed work practices for 21 FGIPs and associated radiation safety practices from the 1950’s through 2009.

RESULTS:

Overall, the proportion of technologists who reported working with therapeutic FGIPs, including percutaneous coronary interventions (PCI), increased over time, while the proportion of technologists who worked with diagnostic FGIPs, including diagnostic cardiovascular catheterization and neuroangiographic procedures, decreased. We also observed substantial increases in the median number of times per month that technologists worked with diagnostic cardiovascular catheterizations and PCI. In each time period, the majority of technologists reported consistently (≥ 75% of work time) wearing radiation monitoring badges and lead aprons during FGIPs. However, less than 50% of the technologists reported consistent use of thyroid shields, lead glasses and room shields during FGIPs, even in more recent time periods.

CONCLUSIONS:

This study provides a detailed historical assessment of FGIPs carried out and radiation safety practices employed by radiologic technologists from the 1950s through 2009. Results can be used in conjunction with badge dose data to estimate organ radiation dose for studies of radiation-related health risks in radiologic technologists who have worked with FGIPs.

Introduction

Fluoroscopically-guided interventional (FGI) procedures involve guidance of catheters and other small devices through blood vessels or other pathways (e.g. biliary or urinary tracts) with fluoroscopic imaging to localize and treat lesions [1–3]. Since the late 1970s, new devices including noncompliant balloon catheters, vascular stents, microcatheters and new guide wires have been developed and widely adapted for FGI procedures [1, 4, 5]. These technologies have allowed for smaller incisions, faster recovery and fewer complications than open surgical techniques [3]. As a result, an increasing number of diagnostic and therapeutic FGI procedures have been performed over last 30 years in the United States and elsewhere [6–13].

Although FGI procedures have provided benefits to patients, operators and those who assist the operators are potentially exposed to the primary x-ray beam or scattered radiation from the patient, as they are positioned close to the patient during the procedure [1, 2, 14]. Radiation exposure can be substantial over the career of medical radiation workers and place them at increased risk for radiation-related diseases [15–21].

Previous clinical reports have described the occurrence of brain tumors, breast cancers [15–17], and cataracts [18, 19] in medical workers who reported working with FGI procedures. However, these clinical reports were based on small numbers of workers and did not compare risks to medical radiation workers who did not perform FGI procedures. The studies also did not include historical information about changes in these work history practices over time. Data from the large U.S. Radiologic Technologists (USRT) cohort study suggested possible elevated risks of brain tumor, breast cancer, melanoma and cerebrovascular disease [20–22] in technologists who performed or assisted with FGI procedures in the mid - 1990s and follow-up of the technologists through 2008.

The USRT cohort study group did not collect substantial work history information about FGI procedures until 2013–14, when a detailed FGI work history survey was administered to a subset of the cohort who had previously reported having ever performed or assisted with FGI procedures. This survey inquired about a wide range of FGI procedures and radiation safety practices that technologists may have worked with or used since the 1950s.

To our knowledge, this is the first comprehensive historical assessment of FGI work practices among radiologic technologists.

Methods

Study overview

The USRT study of 146,022 radiologic technologists is a nationwide cohort study and described in detail elsewhere [23]. Eligible for inclusion in the nationwide cohort were technologists certified for at least 2 years by the American Registry of Radiologic Technologists between 1926 and 1982. Briefly, during follow- up which began in 1982, four different questionnaires were administered (during the periods 1983 – 89, 1994 – 98, 2003 – 05, and 2012 – 13) to collect information on health outcomes including specific types of cancer and benign tumors, circulatory diseases and other disorders, work history, demographic and lifestyle characteristics, medical history (e.g., history of personal medical diagnostic radiologic examinations and radiotherapy), reproductive characteristics, and other cancer risk factors.

Study population

In 2013 – 14, a detailed FGI work history survey was sent to technologists who responded positively to at least one of two screening questions in 2012–13 (response rate of 63%).

Of those who received the detailed FGI survey in 2013–14, 12,571 technologists reported that they ever performed or assisted with FGI procedures and were included in the current analytic study population.

Data collection

The screening question of the detailed FGI work history survey asked participants “Did you ever perform or assist with fluoroscopically-guided procedures such as those listed above at least once a month for a year or more?” FGI procedures were defined in the survey as “fluoroscopically-guided diagnostic or interventional procedures (cardiac, cardiac electrophysiology, interventional radiology endovascular, interventional neurosurgery, and GI/GU endoscopic procedures with fluoroscopy guidance for diagnosis or intervention)”, and participants were asked not to report on routine fluoroscopy exams (e.g., upper GI series, esophagram, barium enema). Participants were asked about 21 specific types of FGI procedures (see Supplementary Table 1) at the beginning of the survey. The term “perform or assist” was not specifically defined. The intent of the survey was to capture all activities conducted by radiologic technologists during the performance of FGI procedures. Radiologic technologists who responded positively to the screening question were asked how many years they performed or assisted with FGI procedures for five separate time periods (before 1970, 1970–79, 1980–89, 1990–99, and 2000–09), how many times per month for a year or more they had performed or assisted with 21 types of FGI procedures and the average percentage of time during each procedure that they were within three feet of the patient. For each time period, the technologist was also asked about the percentage of the time he or she wore radiation monitoring badges at specific anatomic locations (i.e. neck or chest, waist, and finger) or employed specific radiation protection practices while performing or assisting with FGI procedures.

The research protocol for the USRT cohort study of cancer risks has been approved annually by the National Cancer Institute Special Studies Institution Review Board (SSIRB Protocol OH97-C-N053) and the University of Minnesota Human Research Protection Program Institution Review Board (Federal Wide Assurance number 8005M02489).

Statistical Analyses

For each time period, we determined the proportion of technologists who performed or assisted with each specific FGI procedure. The denominators for this proportion were technologists who reported they performed or assisted with any FGI procedures during that period. Of those who reported that they ever performed or assisted with a specific procedure in a given time period, we calculated the median number of times per month the technologist performed or assisted with that procedure and the percentage of the time that the technologist was working within three feet of the patient. We further examined in each time period the proportion of technologists who consistently (75 – 100% of the time) employed specific radiation protection practices while performing or assisting with FGI procedures in that period. Again, the denominators for this proportion were technologists who reported they performed or assisted with any FGI procedures during that period.

All analyses were performed using the statistical software package SAS (release 9.3, SAS Institute, Cary, NC).

Results

Demographic characteristics of the 12,571 technologists who reported that they ever performed or assisted with FGI procedures are shown in Table 1. Of the technologists, 74% were female and 96% were Caucasian. At the completion of the fourth survey, two thirds (67%) of technologists were aged 60 or over, more than half were born in 1950 – 59 and a third in 1940 – 49. More than half of the technologists never smoked (55%), more than one-third (37%) completed a 2- year radiologic technologists program and one third (37%) completed college. These demographic characteristics were largely similar to those of the entire population of fourth survey responders (data not shown).

Table 1.

Demographic characteristics among radiologic technologists who ever performed or assisted with fluoroscopically guided interventional (FGI) procedures from before 1970 to 2009, US Radiologic Technologists Study

	Ever performed or assisted with FGI procedures (N=12, 571)

Characteristic	N	%

Gender
Male	3167	25.2
Female	9393	74.7
Unknown	11	0.1
Race
Caucasian	12059	96.0
African American	256	2.0
Asian/Pacific Islander	93	0.7
American Indian/Alaska Native	37	0.3
Others	115	0.9
Unknown	11	0.1
Age at follow - up at fourth survey completion (yrs)
< 60	4097	32.6
60 – 69	6112	48.6
≥ 70	2351	18.7
Unknown	11	0.1
Birth cohort (yrs)
< 1940	1175	9.4
1940 – 49	4325	34.4
1950 – 59	6935	55.2
≥ 1960	125	1.0
Unknown	11	0.1
Cigarette smoking status at fourth survey completion
Never smoker	6909	55.0
Former smoker	4562	36.3
Current smoker	898	7.1
Unknown	202	1.6
Education
Grade school	-	-
High school	38	0.3
2 years radiologic technologist program	4754	37.8
College	4751	37.8
Graduate school	878	7.0
Others (e.g. vocational)	335	2.7
Unknown	1815	14.4
Body Mass Index (kg/m2) at fourth survey completion
<25	4131	32.9
25 – 29	4466	35.5
≥ 30	3730	29.7
Unknown	244	1.9
Parity at fourth survey completion^a
Nulliparous	2061	22.3
1	1422	15.4
2	3543	38.4
≥3	2200	23.9
Menopausal status at fourth survey completion ^a
Premenopausal	246	2.7
Postmenopausal	8746	96.1
Menstrual are irregular or using hormones	112	1.2

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: Only included female radiologic technologists

- : Not available

Shown in Table 2 is the frequency of selected work history characteristics of the 12,571 technologists. Most of the technologists (60%) became certified between 1970 and 1980. More than half of the technologists (53%) had worked with FGI procedures for more than 10 years, and most technologists (86%) were retired at survey completion. Of those completing the detailed FGI procedures survey, most technologists (86%) reported having ever performed or assisted with therapeutic FGI procedures, while a lower proportion (53%) had ever performed or assisted with diagnostic FGI procedures.

Table 2.

Work history characteristics among radiologic technologists who ever performed or assisted with fluoroscopically-guided interventional (FGI) procedures from before 1970 to 2009,US Radiologic Technologists Study

	Ever performed or assisted with FGI procedures (N=12,571)

Characteristic	N	%

Certification year as a technologist
< 1960	678	5.4
1960 – 1970	3417	27.2
1970 – 1980	7592	60.4
> 1980	873	6.9
Unknown	11	0.1
Year first worked as a technologist
< 1960	1096	8.7
1960 – 1969	3873	30.8
1970 – 1979	7092	56.4
≥ 1980	275	2.2
Unknown	235	1.9
Duration of working as a technologist
< 5	409	3.3
5 – 10	1169	9.3
10 – 20	2585	20.6
≥ 20	7598	60.4
Unknown	810	6.4
Years of performing or assisting FGI procedures
< 5	1644	13.1
5 – 10	2484	19.8
10 – 15	1807	14.4
≥ 20	4928	39.2
Unknown	1708	13.6
Working status as a FGI procedure technologist
Retired when they completed the survey	10824	86.1
Currently working as rad tech	1397	11.1
Unknown	350	2.8
Working with
Diagnostic FG procedure	6608	52.7
Therapeutic FG procedures	10726	85.6
Both	5907	47.1

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- : Not available

In general, among the 12,571 respondents the proportion performing or assisting with any FGI therapeutic procedures increased from 68% before 1970 to 85% in 1990 – 99 and then plateaued (Figure 1). This pattern was similar for technologists performing or assisting with embolizations (Figure 2b), endovascular therapeutic procedures (Figure 2b), peripheral vascular interventions (Figure 2c), inferior vena cava filter placement (Figure 2d), nephrostomy (Figure 2e), percutaneous nephrolithotomy (Figure 2e), transjugular intrahepatic portosystemic shunts (Figure 2e), and biliary tract procedures (Figure 2e). In contrast, the proportion of 12,571 technologists assisting with any diagnostic procedures in a given period increased from 30% before 1970 to 50% in 1970 – 79 but subsequently declined in later periods (Supplementary Table 1; Figure 1). This pattern was evident for technologists who performed or assisted with diagnostic cardiovascular catheterizations (Figure 2a) and diagnostic neuroangiography (Figure 2b).

Fig. 1- — Proportion of radiologic technologists who performed or assisted with therapeutic or diagnostic fluoroscopically guided interventional (FGI) procedures from before 1970 to 2009, U.S. Radiologic Technologists Study. Supplementary Table 1 shows types of specific diagnostic and therapeutic FGI procedures.

Fig. 2- — Proportion of radiologic technologists who performed or assisted with fluoroscopically guided interventional (FGI) procedures from before 1970 to 2009, U.S. Radiologic Technologists Study.

There was a steady increase over time in the proportion of technologists performing or assisting with electrophysiology diagnostic procedures (2% before 1970 to 7% in 2000 – 09; Figure 2a), peripherally inserted central catheter placement (14% in 1970 – 79 to 34% in 2000 – 09; Figure 2c), dialysis interventions (1% before 1970 – 79 to 17% in 2000 – 09; Figure 2c), port placement (8% in 1970 – 79 to 37% in 2000 – 09; Figure 2d), aortic stent grafts (2% in 1970 – 79 to 12% in 2000 – 09; Figure 2d), and vertebroplasty (5% in 1980 – 89 to 25% in 2000 – 09; Figure 2e) among those performing or assisting with FGI procedures in each time period. Among the technologists performing or assisting with any FGI procedure in a given period, the proportion of technologists performing or assisting with percutaneous coronary interventions decreased from 9% before 1970 to 7% in 1970 – 79 then increased (from 10% in 1980 – 89 to 14% in 2000 – 09; Figure 2a). A notable increase for pacemaker/intracardiac defibrillator implantation was observed from before 1970 through the 1990s followed by a decline in the 2000s (19% before 1970 to 40% in 1980 – 89 to 37% in 2000 – 09; Figure 2a) and endoscopic retrograde cholangipancreatography (13% before 1970 to 34% in 1980 – 89 to 38% in 1990 – 99 to 33% in 2000 – 09; Figure 2e). The proportion of technologists performing or assisting with orthopedic extremity nailing remained at a consistently high level of 45% to 50% throughout all time periods (Figure 2e).

The median number of times per month that technologists performing or assisted with any FGI procedure rose consistently from 9 before 1970, to 15 in 1970 – 79, 20 in 1980 – 89, 24 in 1990 – 99, and to 26 in 2000 – 09 (data not shown). The median number of times per month that technologists performed or assisted with diagnostic cardiovascular catheterizations increased from 10 in 1970 – 79 to 30 in 2000 – 09 (Figure 3a) and similarly, percutaneous coronary interventions increased from a median of 5 per month before 1970 to 20 per month in 2000 – 09 (Figure 3a). The median number of times per month that technologists performed or assisted with diagnostic neuroangiography doubled from 5 before 1970 to 10 in 1970 – 79, but then decreased from 1990 – 99 onward (Figure 3b). The median number of peripheral vascular interventions that technologists carried out increased from 5 per month before the 1980s to 10 per month beginning in the 1990s (Figure 3c). The number of dialysis interventions that technologists performed or assisted with initially decreased slightly from 5 to 4 between before 1970 and 1970 – 79, but subsequently doubled from 1980 onward (from 5 to 10 between 1980 – 89 and 2000 – 09) (Figure 3c). Other procedures remained fairly constant with regard to frequency of performance (Figure 3).

Fig. 3- — Median frequency of fluoroscopically guided interventional (FGI) procedures performed or assisted per month, among radiologic technologists who reported ever performing or assisting with the specific FGI procedure, before 1970 to 2009, US Radiologic Technologists Study. (ERCP: Endoscopic retrograde cholangiopancreatography, PCNL: Percutaneous nephrolithotomy, TIP: Transjugular intrahepatic portosystemic shunts)

The proportion of working time spent within three feet of the patients when performing or assisting with diagnostic cardiovascular catheterizations was 40 – 50% in each time period. After the 1970s, time spent within three feet of patients during percutaneous coronary interventions, endovascular therapeutic procedures, diagnostic neuroangiography, dialysis interventions, peripheral vascular interventions, and nephrostomy was also 40% - 50% (Table 3). For most other procedures, the median time spent within three feet of the patients was less than 40%.

Table 3.

Median percent of time technologists who performed or assisted with fluoroscopically guided interventional (FGI) procedures were located within three feet of the patient in five time periods from before 1970 to 2009, US Radiologic Technologists Study

	Before 1970	1970 – 79	1980 – 89	1990 – 99	2000 – 09

Cardiovascular procedures
Diagnostic cardiovascular catheterizations	-	45	50	50	50
Percutaneous coronary interventions (PCI)	40	30	40	50	50
Electrophysiology (EP) diagnostic studies	55	20	15	10	20
Electrophysiology (EP) ablations	-	-	-	9	10
Pacemaker or intracardiac defibrillator implantations	20	25	20	20	15
Neurovascular procedures
Embolizations	10	34	30	40	35
Endovascular therapeutic procedures	20	30	40	40	40
Diagnostic neuroangiography	25	40	50	50	50
Peripheral vascular procedures
Peripherally inserted central catheter (PICC) placement	-	25	25	30	34
Dialysis interventions	17	20	50	50	50
Peripheral vascular interventions	20	40	50	50	40
Other vascular procedures
Port placement	-	20	15	15	20
Inferior Vena Cava (IVC) filter placement	-	20	30	25	25
Aortic stent grafts	-	10	20	20	15
Urologic procedures
Percutaneous nephrolithotomy (PCNL)	20	15	20	25	20
Nephrostomy	20	25	40	50	40
Biliary/gastric procedures
Biliary tract procedures	-	25	30	30	20
Endoscopic retrograde cholangiopancreatography (ERCP)	20	20	25	25	22
Transjugular intrahepatic portosystemic shunts (TIPS)	-	-	20	31	30
Orthopedic procedures
Vertebroplasty	-	-	10	20	16
Orthopedic extremity nailing	20	20	20	20	12

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- : Procedure not usually performed during the time period

Consistent use (75% - 100% of the time) of radiation monitoring badges increased over time (Figure 4a). Technologists were substantially more likely to wear monitoring badges at the neck or chest than at the waist or on their fingers (Figure 4a). Only about 20% of technologists performing or assisting with FGI procedures consistently wore monitoring badges underneath their lead aprons at either the waist or neck/chest during each time period (Figure 4b). Most technologists (about 90%) consistently wore lead aprons in each time period (Figure 4c). Technologists were less likely to wear wrap- around lead aprons than other types of lead aprons in each time period, but the proportion of technologists who consistently wore wrap - around lead aprons rose somewhat over time from 42% before 1970 to 50% from 1990 onward (Figure 4c). The proportion of technologists who consistently used thyroid shields increased dramatically over time (from 2% before 1970 to 43% in 2000 – 09; Figure 4c).Only about 5% of technologists wore lead glasses consistently in each time period. The consistent use of room shields increased over time from 2 – 14% before 1970 to 8 – 29% in 2000 – 09, but remained less than 30% in each time period (Figure 4d).

Fig. 4- — Proportion of radiologic technologists who consistently (75 – 100% of the time) used protective measurements during fluoroscopically guided interventional (FGI) procedures from before 1970 to 2009, US Radiologic Technologists Study.

Female technologists were more likely to wear monitoring badges at the waist over lead aprons than male technologists (females: 28%, males: 18% in 2000 – 09), and were slightly less likely to wear thyroid shields before 2000 (females: 26%, males: 28% in 1990 – 99). However, in 2000 – 09, use of thyroid shields in female technologists increased nearly two - fold and was notably higher than use of thyroid shields by male technologists (females: 56%, males: 41% in 2000 – 09) (data not shown).

Discussion

Overall, we found that the proportion of technologists who ever performed or assisted with therapeutic FGI procedures increased over the past several decades while the proportion of technologists who ever performed or assisted with diagnostic FGI procedures decreased. The median number of times per month that technologists performed or assisted with any FGI procedure tripled over the study period, with the most notable increases seen for diagnostic cardiovascular catheterizations and percutaneous coronary interventions. The median number of times per month that technologists performed other types of procedures remained fairly constant. The incorporation of radiation safety practices among technologists performing or assisting with FGI procedures has increased over time, but less than half of technologists reported use of thyroid shields and lead glasses during FGI procedures, and less than a third reported use of room shields even in the most recent decade.

The observed trend in the proportion of technologists performing therapeutic FGI procedures may be explained by the advent of newer technologies. Between 1970 and 1990, noncompliant balloon catheters and microcatheters, new guide wires and vascular stents were introduced and widely adopted for use in therapeutic FGI procedures because they provide a number of advantages over other procedures and allow an alternative to open surgery [1, 3–5]. The declines or stabilization in diagnostic FGI procedures, gastric and urologic FGI procedures, the latter having been observed in a previous study [6], can largely be explained by the introduction of non - invasive procedures in the 1980s and 1990s, such as computed tomography, computed tomography angiography, magnetic resonance imaging or magnetic resonance angiogram that provide much of the same information [5, 24, 25]. In addition, use of extracorporeal shockwave lithotripsy introduced in the 1980s for treatment for renal or bladder stones may have also contributed to the decline or stabilization of urologic FGI procedures [26].

Studies of interventional cardiology departments reported that the number of medical staff members has not proportionally increased along with the notable increase in the number of cardiac FGI procedures performed. As a result, the workload of the medical staff has increased [27, 28]. Our study similarly demonstrated a consistent increase in procedural volume for radiologic technologists who performed or assisted with diagnostic cardiovascular catheterizations or percutaneous coronary interventions.

Our findings suggest that technologists have increasingly followed the NCRP recommendation for use of placement of monitoring badges 1) at the neck outside the lead apron if one monitoring badge is provided and 2) at the neck outside the apron and at the waist or on the chest under the lead apron when two monitoring badges are provided [1]. In contrast, studies of medical staff in interventional laboratories have reported that approximately half of FGI operators had musculoskeletal problems and thus were using lighter weight aprons with a decreased lead equivalent thickness or replacement of lead by other elements, even though these may provide less protection [30–33].

Our study showed that relatively infrequent use of lead glasses and room shields consistently (defined as using 75–100% of the time during the procedure). It is similar to findings that fewer than 15% of 504 interventional radiation workers used such protective measures [17]. Either the lead glasses and room shields were not routinely provided to the radiologic technologists as an option, or they were not used, possibly because the radiologic technologists were not close to the radiation source or in the procedure room consistently during a typical FGI procedure. We did not specifically ask about radiation safety practices used within a certain distance of the beam or patient during the procedure. Neither the previous study nor ours inquired about the reasons for non-use of eyeglasses or ceiling suspended shielding.

Per-procedure radiation doses to interventional cardiologists have increased for certain procedures, such as percutaneous coronary interventions [28]. While less information is available on radiation exposure to technologists who performed or assist with FGI procedures, a small study found similar ranges of radiation exposure levels for interventional cardiologists and other medical staff (e.g., nurses/technicians) [40]. These observations, together with our results showing an increasing workload for technologists performing or assisting with therapeutic FGI procedures, suggests that occupational radiation exposure to radiologic technologists who performed or assisted with FGI procedures could have increased over time. Additional studies tracking monitoring badge doses over time could help to determine whether occupational doses of the radiologic technologists have indeed increased.

To our knowledge, this study is the first to provide comprehensive historical information about work history practices of radiologic technologists who performed or assisted with FGI procedures. However, there are limitations to our study. Although we inquired about FGI procedure – related work history practices between 2000 and 2009, all of the radiologic technologists in our study population were first certified before 1980. Our results, therefore, may not be applicable to all radiologic technologists who are currently working with these procedures. Some of the quantitative information provided to us may have been under- or overestimated by the participants, particularly for procedures that were performed several decades in the past, other literature on workers’ questionnaire responses suggests that the technologists provided reasonably accurate information on their work history practices. To our knowledge, there are no studies about the accuracy of self-reported work history information by medical workers. Other literature on workers’ questionnaire responses suggests that the technologists likely provided reasonably accurate information on their work history practices. Data from male chemical workers showed that about 71% of workers had provided information that agreed with company records for occupational histories up to 40 years in the past [40]. Furthermore, our findings were consistent with the 2009 American Heart Association report from 500 US hospitals showed an increasing number of cardiovascular FGI procedures being performed over time [28]. Finally, although we had data on radiation safety practices over several decades, we were not able to assess the variability in the use of safety practices of technologists specific to each FGI procedure.

Conclusion

This study provides a detailed historical assessment of FGI procedures carried out and radiation safety practices employed by radiologic technologists from the 1960s through 2009. Although technologists reported an increase in adherence to radiation safety practices over time, our findings suggest that workload of technologists who performed or assisted with certain FGI procedures has increased. Our results can be used in conjunction with badge dose data to estimate organ radiation dose for studies of radiation-related health risks in radiologic technologists who have worked with FGI procedures. A comprehensive assessment is needed of more recent practices and associated organ radiation dose estimates of workers in this field.

Supplementary Material

NIHMS1033682-supplement-1.pdf^{(41.7KB, pdf)}

Acknowledgments

Funding: This work was supported by the Intramural Research Program of the Division of Cancer Epidemiology and Genetics, National Cancer Institute, National Institutes of Health, U.S. Department of Health and Human Services

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

NIHMS1033682-supplement-1.pdf^{(41.7KB, pdf)}

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PERMALINK

Changing Patterns in the Performance of Fluoroscopically Guided Interventional Procedures and Adherence to Radiation Safety Practices in a U.S. Cohort of Radiologic Technologists

Hyeyeun Lim

Martha S Linet

Miriam E Van Dyke

Donald L Miller

Steven L Simon

Alice J Sigurdson

Cari M Kitahara