Key words
interventional procedures - physics - radiation effects - radiation safety - safety
Introduction/background
On November 8, 1895, the physicist Wilhelm Conrad Röntgen discovered X-rays. The diagnostic and therapeutic possibilities were quickly identified and further developed. The first acute radiation injuries were seen in the year after the discovery of X-rays and their initial clinical application, primarily in the form of injury to the skin, such as hair loss and dermatitis. Eye irritation was also reported [1]. The radiation injuries were deterministic in nature, i. e., tissue injury occurred after a threshold dose was exceeded. It was shown for the first time in 1902 that ongoing radiation exposure can cause carcinoma of the skin [2] in the form of a stochastic radiation injury that occurs randomly and is due to a change in DNA. Increasing radiation exposure increases the probability of radiation injury approximately linearly. Radiation dermatitis experienced by radiologists and radiographers due to chronic radiation exposure was reported for the first time in 1904 [3]. The first radiation protection measures in the form of shielding of the X-ray tube were presented in 1898 [4]. The first means of personal radiation protection in the form of protective gloves, lead jackets, beard covers, protective caps, and lead glasses were recommended in 1905 [5]. Leaded protective booths for operating personnel were also constructed. A regulation regarding radiation protection and the corresponding dosimetry was established when the German Radiological Society was founded on May 2, 1905 and was legally adopted the following year. The first general radiation protection recommendations were published by the German Radiological Society in 1913. Radiation protection was further developed in all areas in the following years primarily due to the constantly improving measurement technology and the growing experience, particularly with respect to long-term damage [6].
Today, X-rays have a broad range of applications in medicine. With the trend toward minimally invasive interventions, the number of procedures and, due to increasing complexity, the examination time are increasing particularly with respect to radiological, neuroradiological, cardiological, orthopedic and vascular interventions using X-ray fluoroscopy [7]
[8]. Most studies regarding personal radiation protection focus on this area but CT-guided interventions are also increasing in frequency and currently cover a broad application spectrum [9]. This trend also entails an increase in the radiation exposure of medical personnel.
The consequences of long-term exposure to X-rays with a low effective dose is still the subject of current studies and continues to be a topic of controversy. While several current studies were not able to show an increased risk for a malignant disease in radiologic technologists [10]
[11], other studies show double the risk for a brain tumor and a moderately elevated risk for melanoma and a breast tumor [12]. A much less controversial consequence of long-term radiation exposure is the formation of a cataract. The results of Seals et al. indicate that cataractogenesis tends to be a stochastic and not a deterministic effect as was long assumed [13].
This was taken into account in the new guidelines of the European Atomic Energy Community (EURATOM) (directive 2013/59/Euratom) and is intended to help further improve medical radiation protection. The new guidelines are to become national law in 2018 and will enter into force on 12/31/2018. The new limit for eye lenses, which was reduced from 150 mSv/year to 20 mSv/year, is of particular note here. A comparison of the dose limits of the currently valid X-Ray Ordinance and the new Radiation Protection Act is provided in [Table 1].
Table 1
Comparison of the occupational dose values of the “X-Ray Ordinance” and the new “Radiation Protection Act” of category A.
|
X-ray ordinance, limit value
|
new radiation protection act, limit value
|
|
total body dose
|
20 mSv per year
exception:
50 mSv per year (in 5 successive years not > 100 mSv)
|
20 mSv per year
exception:
50 mSv per year (in 5 successive years not > 100 mSv)
|
|
eye lens
|
150 mSv per year
|
20 mSv per year
|
|
local skin dose
|
500 mSv per year
|
500 mSv per year (averaged over any skin surface of one square centimeter)
|
|
hands, lower arms, feet, ankles
|
500 mSv per year
|
500 mSv per year
|
|
gonads, uterus, bone marrow
|
50 mSv per year
|
no longer specified
|
|
thyroid, bone surface
|
300 mSv per year
|
no longer specified
|
|
large intestine, lung, stomach, bladder, breast, liver, esophagus
|
150 mSv per year
|
no longer specified
|
|
lifetime occupational dose (authorities can allow additional exposure with written consent of the person being exposed to radiation)
|
400 mSv
exception after the lifetime occupational dose has been reached: maximum additional 10 mSv per year
|
400 mSv
exception after the lifetime occupational dose has been reached: maximum additional 10 mSv per year
|
Radiation protection
General principles
The “ALARA” (as low as reasonably achievable) principle, i. e., ionizing radiation must be kept as low as reasonably possible, is a fundamental rule in radiation protection. A further principle of radiation protection is the inverse square law which states that the dose rate per surface area decreases in inverse proportion to the square of the distance. This means that the dose rate is reduced by one-fourth when the distance to the radiation source doubles. For all interventions involving X-rays, it must be ensured that the examiner is not exposed to the primary beam. The majority of an examiner’s personal dose is the result of the scatter radiation primarily emitted by the patient ([Fig. 1]).
Fig. 1 a Simulation of scatter radiation during a CT scan (top view). b Simulation of the scatter radiation during a fluoroscopy-guided intervention (f.l.t.r: top view, axial view and lateral view). The software EGS-Ray (C. Kleinschmidt, University of Cologne) was used for the simulations with the following main parameters: 80 kV X-ray spectrum (photons); data sets from ICRU report 521.
Apart from that, radiation protection covers a broad range and can be generally divided into three main categories:
-
Equipment-based radiation protection
-
Structural radiation protection
-
Personal radiation protection
This article is intended to provide an overview ([Table 2]) of the available means of personal radiation protection, their effectiveness, and a look at new developments and future trends.
Table 2
Overview of different radiation protection means and their efficacy.
|
modality
|
study
|
body region
|
dose reduction [%]
|
|
mobile lead glass screen
|
angiography
|
14, 15, 16
|
head, neck, and eye lens
|
50.0 – 60.0
|
|
angiography
|
16, 17, 18, 19, 20, 21, 22, 23
|
eye lens
|
50.0 – 96.7
|
|
angiography
|
24
|
neck
|
52.6 (15.4 µSv to 7.3 µSv)
|
|
under-table shielding
|
angiography
|
16, 25, 26
|
lower extremities
|
64.0 (5.54 mSv to 1.98 mSv)
|
|
computed tomography
|
27
|
lower extremities
|
38.2
|
|
+ shielding at the gantry
|
computed tomography
|
28
|
upper body
|
85.6
|
|
|
|
gonads
|
93.3 (25.4 µGy to 1.7 µGy)
|
|
|
|
hands
|
85.1
|
|
mobile radiation protection barrier
|
angiography
|
15
|
abdomen
|
96.1 (0° angle)
|
|
|
|
|
88.0 (lateral angle)
|
|
+ radiation protection placed on the patient
|
|
|
|
98.9
|
|
computed tomography
|
29
|
|
84.0
|
|
scatter radiation protection placed on the patient
|
angiography
|
16, 30, 31
|
eye
|
91.7
|
|
|
|
thyroid
|
96.0
|
|
|
|
hands
|
96.6
|
|
angiography
|
32
|
thorax
|
56.9 (20.9 µSv to 9.0 µSv)
|
|
radiation protection vest
|
general
|
34
|
|
80.0 (wraparound apron vs. front apron)
|
|
thyroid protection
|
general
|
16, 40, 41
|
thyroid
|
90.7 (alternative materials)
|
|
|
|
|
72.4 (lead-based)
|
|
free-hanging radiation protection system
|
angiography
|
44
|
head-neck region
|
94.0 (in contrast to radiation protection apron)
|
|
radiation protection glasses
|
angiography
|
17, 18, 19
|
eye
|
66.7 – 96.0
|
|
angiography
|
22, 46
|
eye
|
50.0
|
|
+ mobile lead glass screen
|
|
|
|
82.5
|
|
lead glass visors
|
angiography
|
17
|
eye
|
85.0 – 90.0
|
|
radiation protection cap
|
angiography
|
40
|
head
|
85.4 (224 µSv to 48 µSv)
|
|
angiography
|
45, 46
|
head
|
3.3
|
|
radiation protection gloves
|
computed tomography
|
28
|
hand
|
97.1 (1792 µGy to 52 µGy)
|
|
angiography
|
48
|
hand
|
42.6
|
|
in the beam path
|
|
48
|
hand
|
increase to 64.5
|
Equipment-based radiation protection for medical personnel
Equipment-based radiation protection for medical personnel
Mobile lead glass screen
Lead glass screens have different shapes depending on their intended use and are usually made of acrylic glass and lead oxide. They usually have a lead equivalent of 0.5 mm. This means that the acrylic glass screen in connection with the lead oxide blocks X-rays as well as lead shielding with a thickness of 0.5 mm. Such a mobile, usually ceiling-mounted, lead glass screen ([Fig. 2]), which protects the examiner from additional radiation exposure particularly in the area of the upper body, can achieve a reduction of the local dose of 50 – 60 % in the region of the head-neck, particularly the eye lenses [14]
[15]
[16]. Depending on the angle of the X-ray tube, the radiation exposure can even be reduced by 90 – 98 %. This is important particularly when the X-ray tube is on the same side as the examiner since a high local dose is reached in the region of the examiner’s upper body due to the geometry of the scatter radiation. In relation to the eye lenses, a reduction of the local dose of 50.0 – 96.7 % with exclusive use of the mobile lead glass screen could be shown in phantom experiments and simulations [16]
[17]
[18]
[19]
[20]
[21]
[22]
[23]. This system can be further improved by enlarging the effective surface of the screen and additionally attaching lead strips to the bottom. In this way Gilligan et al. were able to achieve a reduction of the local dose with respect to the examiner’s neck from 15.4 µSv to 7.3 µSv (52.6 %) per examination [24].
Fig. 2 Leaded vest and skirt with thyroid protection, radiation protection glasses and radiation protection cap. The mobile lead glass screen and the under-table shielding are shown in the background.
Under-table shielding
Shielding attached to the underside of the patient table protects the examiner primarily in the region of the lower extremities ([Fig. 2]). This shielding is made either of a continuous material or of strips which ensure better fitting to the examiner. Moreover, the shielding usually extends up beyond the edge of patient table to block scatter radiation emitted laterally by the patient. These materials typically have a lead equivalent of 0.5 mm. Some studies were able to show a reduction of the local dose in the region of the examiner’s lower extremities of up to 64 % (from 5.54 mSv to 1.98 mSv on average) [16]
[25]
[26].
A reduction in the local dose to the lower extremities of 38.2 % using experimental under-table shielding in interventional CT examinations was also able to be shown [27]. Neeman et al. were able to show that a maximum local dose reduction of 85.6 % for the upper body, 93.3 % (from 25.4 µGy to 1.7 µGy on average) for the gonads, and 85.1 % for the hands can be achieved by using shielding in the region of the gantry in addition to the under-table shielding [28].
Mobile radiation protection barrier
Mobile radiation protection barriers are available in a wide range of sizes, shapes, and designs. They essentially come as half-height barriers that protect the examiner from scatter radiation up to the abdomen and full-size barriers that usually have a window or are made entirely of a transparent material. These mobile radiation protection barriers usually have a lead equivalent of 0.5 mm and can reduce the dose rate by 96.1 % (converted averages from air kerma: 245.6 µGy/h to 9.5 µGy/h) when an X-ray tube angle of 0° is used. In the case of lateral angling to the left (X-ray tube on the side facing the measurement chamber), the dose rate reduction is only 88 % (converted averages from air kerma: 160.5 µGy/h to 19.3 µGy/h). If such a mobile radiation protection barrier is combined with radiation protection directly on the patient, the dose rate can even be reduced by up to 98.9 % (converted averages from air kerma: 245.6 µGy/h to 3 µGy/h) [15]. An average dose rate reduction of 84 % can be achieved in CT-guided interventions when a radiation protection barrier is used. However, this greatly limits direct access to the patient [29].
Scatter radiation protection to be placed on the patient
A further approach to reducing scatter radiation is to shield it directly at the source, namely the patient. This can range from sterile drapes coated, for example, with bismuth to lead-based radiation protection mats ([Fig. 4]). Moreover, there is a wide range of designs ranging from an extension of the mobile lead glass screen or the lateral shielding facing the examiner to complete shielding of the patient as shown in [Fig. 4]. Shields made of bismuth with a lead equivalent of 0.1 mm reduce the radiation dose up to 91 % for the eyes, 96 % for the thyroid, and 96 % for the hands [16]
[30]
[31]. In their study Lange et al. were able to show an average personal dose reduction from 20.9 µSv to 9.0 µSv (56.9 %) by using a radiation protection mat with a lead equivalent of 0.5 mm on the patient [32]. However, it must be ensured that such shields are outside the primary X-ray beam when automatic dose control is activated since this would otherwise result in an increase in the radiation exposure for the patient as well as the medical staff thereby negating the benefit. Automatic dose control can usually be deactivated.
Fig. 3 Free-hanging radiation protection system with integrated lead glass screen. The mobile lead glass screen and under-table shielding are shown in the background.
Fig. 4 Patient shielding with a femoral notch for intervention access.
Personal radiation protection for medical staff
Personal radiation protection for medical staff
Radiation protection apron and thyroid protection
Conventional radiation protection for medical personnel is usually comprised of an apron that is lead-based, has reduced lead, or is lead-free, or a vest and a skirt, and thyroid protection ([Fig. 2]) with varying lead equivalents. In a survey Lynskey et al. confirmed that 99.4 % of participating interventional radiologists wear a protective vest and 94 % use thyroid protection [33].
In a comparison of various lead-based aprons, Toossi et al. were able to show that one-piece aprons with an overlap in the front and a lead equivalent of 0.35 mm (thus effectively 0.7 mm in the front) provide the best protection. In addition, a wraparound apron provides 5 times better radiation protection than a front apron. Thyroid protection should have a lead equivalent of 0.5 mm and cover a surface that is as large as possible [34]. Since lead aprons are heavy and brittle and can cause physical symptoms particularly in the back and hips [35]
[36]
[37] when used daily, lighter aprons made of alternative materials are available. These are usually made of a combination of bismuth, gadolinium and/or barium sulfate and are approximately one-fourth to one-third lighter than conventional lead aprons. In a simulation, Kazempour et al. were able to show that lead aprons are most effective at energies of 40 kVp, while the combination W-Sn-Cd-EPVC provides the best protection at 60 and 90 kVp and W-Sn-Ba-EPVC at energies of 120 kVp (Pb-lead; Si-silicon; W-tungsten; Sn-tin; Cd-cadmium; Ba-barium; EPVC-emulsion polyvinyl chloride) [38]. The absorption edges, i. e., energy ranges in which absorption increases erratically, of the various materials play a decisive role. This shows that lead and other materials are capable of ensuring adequate radiation protection with a simultaneous weight reduction. However, the latter depends on the energy being used [39], i. e., the effectiveness of a means of radiation protection depends on the tube voltage and cannot be necessarily specified based exclusively on the lead equivalent. Therefore, there are alternative materials for thyroid protection. In their clinical studies, Uthoff et al. show that the alternative materials made of barium sulfate and bismuth oxide ensure on average the same radiation protection as lead thyroid protection. If these materials are used as a double layer, they achieve a dose reduction of 90 % (120 µSv to 11 µSv on average) compared to no radiation protection in contrast to normal thyroid protection which provides a reduction of 72.4 % (from 190 µSv to 52 µSv on average) [16]
[40]
[41].
Free-hanging radiation protection system
Another commercially available system which supports its own weight is a free-hanging radiation protection system with an integrated lead glass screen for protecting the head-neck region ([Fig. 3]). Multiple studies were able to show that this system ensures significantly better radiation protection particularly in the head-neck region than conventional systems [42]
[43]. As an example, Savage et al. report a 94 % reduction (from 2.4 µSv/min to 0.14 µSv/min) in the local dose for the head-neck region compared to the conventional radiation protection system including a mobile lead glass screen and under-table protection [44].
Radiation protection glasses and visors
Multiple systems, such as protective glasses, visors and headgear, were developed to compensate for the disadvantage of conventional radiation protection particularly in the head-neck region. In particular the development of protective glasses, in part due to the new eye lens limit of 20 mSv per year, has become increasingly important in recent years. However, the wearing of radiation protection glasses is a current topic of discussion as reflected in the study by Lynskey et al. in which only 54.2 % of all surveyed radiologists stated that they wear protective glasses during an intervention [33]. Phantom experiments were able to show that the eye lens local dose can be reduced from 66.7 % to 96.0 % (from 0.32 mSv/h to 0.04 mSv/h as an example [18]) with a favorable X-ray tube angle and head position [17]
[19]. However, this reduction is not the same for both eyes. In their study Fetterly et al. were able to show that the eye facing away from the scatter radiation is not protected at all in an experimental test setup of an angiographic examination [45]. The main reasons for these results are the orientation of the examiner’s head in relation to the source of the scatter radiation and the fit of the glasses [17]. In their clinical studies, Van Rooijen und Merce et al. show that a radiation reduction for the eye lenses of 50 % can be achieved by wearing radiation protection glasses or of 82.5 % when used in combination with a mobile lead glass screen [22]
[46]. It was shown that a lead equivalent of the glasses of 0.35 mm, 0.5 mm or greater does not result in a significant additional radiation protection effect. In the case of light models with a lead equivalent of 0.07 mm, the radiotransparency is three times higher in relation to glasses with a lead equivalent of 0.75 mm [16]. Moreover, there are different models ranging from standard glasses to glasses with additional shielding on the sides to visors ([Fig. 5]). It was able to be shown that enlarging the lenses of the glasses does not affect the level of radiation protection. Only additional lateral shielding can result in further radiation protection since scatter radiation usually comes laterally from below. Galster et al. were able to show that glasses and visors achieve a lens dose reduction of approximately 85 – 90 % [17] although visors only have a lead equivalent of 0.1 mm in contrast to 0.5 mm or even 0.75 mm in the case of glasses. This is because visors have a greater surface area and thus reduce the exposure of personnel to scatter radiation in the region of the head by providing better shielding ([Fig. 5]). Moreover, special radiation protection visors have the advantage that they also serve as a splash guard, particularly in the case of infectious patients.
Fig. 5 a Various radiation protection glasses. b Various radiation protection visors.
Radiation protection cap
Current cohort studies show an incidence of increased cranial tumors in long-term radiation exposure [12]. Therefore, radiation protection of the head has again become a main focus and is a current topic of research ([Fig. 2]). The equivalent dose directly beneath a radiation protection cap can be lowered on average by 85.4 % (from 224 µSv to 48 µSv on average) [40]. This should also lower the eye lens organ dose since approximately 21 % of eye lens radiation exposure is the result of scatter radiation from the examiner [16]. Other studies were able to show no or only a slight reduction in the equivalent dose of 3.3 % for the neurocranium [45]
[46]. These measurements mainly relate to the brain surface. Therefore, there is a need for both development and research.
Radiation protection gloves
The dose limit for the hands is 500 mSv per year (directive 2013/59/Euratom). Since the hands are unprotected and are thus directly exposed to scatter radiation, the radiation exposure is very high here [47]. In addition, there is a risk of the hands entering the primary beam. Neeman et al. were able to show that the use of lead-free radiation protection gloves resulted in a reduction of the absorbed dose of 97.1 % (from 1792 µGy to 52 µGy on average) in CT-guided treatments [28]. However, if the radiation protection equipment is located in the primary beam, the automatic fluoroscopy system causes the X-ray tube output and thus the radiation exposure to increase. Therefore, radiation protection for the hands is particularly difficult to implement. A current phantom study was able to show that a reduction of the equivalent dose of 42.6 % can be achieved by using radiation protection gloves consisting of rubber and metal oxides (e. g. bismuth) with almost the same comfort level as conventional gloves. However, use of these gloves in the primary beam results in an increase in the equivalent dose for the hands of 64.5 % [48]. To avoid this risk, tools such as needle holders are regularly used. The longer the needle holder the better the hands are protected but control of the needle decreases as the needle length increases [49]
[50].
Personal dosimetry
Dosimetry and monitoring of medical staff
Dosimetry is intended to increase awareness of personal radiation exposure and to provide various dose limits measured and documented by the authorities for different organs and body regions. The new Radiation Protection Act requires the use of a personal identification number for the radiation protection register for persons working with ionizing radiation to ensure consistent documentation even in the case of a change of employment or name [51]. There are various options for measuring and monitoring these limit values. The film badge was one of the most widely available and most widely used systems as early as the 1960s. In 1962 the International Atomic Energy Agency published a paper regarding the use of film badges for personal monitoring. The operating principle remains unchanged and is shown in [Fig. 6a] [52]. These dosimeters are cost-effective, highly responsive, and can be easily worn on a daily basis. The disadvantage of this system is the low accuracy at low energies and that the dose values are determined on a monthly basis so that it is not possible to draw conclusions about the cause of an increase in radiation exposure. An alternative dosimeter that has been available for approximately 10 years uses luminescent crystals (optically stimulated luminescence from beryllium oxide, BeOSL) that can be read out by optical excitation and otherwise correspond to the use of a film badge ([Fig. 6b]). It was able to be shown that these dosimeters have a low response at energies between 60 and 100 keV which can however be compensated by a corresponding design and use of a linear algorithm for evaluation. Moreover, these dosimeters are also cost-effective which is due among other things to the fact that they can be read out multiple times. These dosimeters are therefore also suitable for the daily routine [53]
[54].
Fig. 6 a Badge meter with various shielding materials (f.l.t.r.: X-ray film, bottom with copper and apron, cover with copper and apron). b BeOSL dosimeter. c Electronic personal dosimeter (EPD).
Electronic personal dosimeter (EPD)
Electronic personal dosimeters (EPDs) which can display the momentary radiation exposure and optionally emit an acoustic or optical warning are available for monitoring current radiation exposure. [Fig. 6c] shows an example of an electronic personal dosimeter. Semiconductor materials with a good sensitivity in the range between 70 and 110 keV are used for this purpose [55]. In a study Clairand et al. compared 5 EPDs with one another and were able to show that these display correct values both at low energies and in pulsed examinations. 4 of the 5 examined dosimeters were even able to measure the local dose of an individual pulse [56]. New systems are comprised of monitoring units that can display dose values of up to 5 dosimeters at the same time. Thus, the entire medical staff can be monitored with one central monitoring unit during an examination. The advantage of this system is that every person in the examination room is measured in real time and immediate action can be take in the case of increased radiation exposure [57]
[58]. Sailer et al. were able to show in a current study that this not only increases the feeling of safety of medical personnel but also results in a significant reduction in the personal dose for technical personnel (from 0.12 µSv/Gy cm2 to 0.08 µSv/Gy cm2) [59].
Dosimeter position
Apart from the selection of a suitable dosimeter, the position and use play a decisive role. Rigatelli et al. were able to show that radiologists with a body size < 165 cm have higher dose values on their dosimeters than radiologists with a body size > 165 cm provided that the dosimeter is worn in the same body region. This can be explained by the distribution of scatter radiation. Therefore, it is important for dosimeters to always be worn in the same representative position, e. g. on the breast pocket [60]. As shown in [Table 1], there are different dose limits for different organs and body regions. Since not all body regions can be measured individually, the dose for these can be estimated with the help of reference measurements. In their study Fetterly et al. use a dosimeter on the left collar and obtain an equivalent dose exposure of 8.4 % of the total measured dose value for the brain, 72 % for the left carotid, 28 % for the right carotid, 25 % for the left eye lens, and 9.2 % for the right eye lens from reference measurements [45]. Neto et al. continue to recommend the use of two dosimeters, one beneath the lead apron and one on top of the apron to determine the correct body dose [61]. If individual body regions are to be measured or monitored in certain applications, special dosimeters such as the ring dosimeter for the finger as is typically used in nuclear medicine can be used.
Summary and current trends
Summary and current trends
Optimal radiation protection always includes a combination of various means of radiation protection and methods. In their study Adamus et al. show successive dose reduction with use of additional radiation protection means for the average equivalent dose for the eye lenses based on the example of TIPPS placement (transjugular intrahepatic portosystemic shunt). If only one under-table shield is used, an average eye lens dose of 466 mSv is achieved. This value decreases to 55 mSv when a lateral patient shield (upwardly extendable under-table shield) and a mobile lead glass screen are additionally used. A further reduction of the eye lens dose to 9.5 mSv can be achieved by using radiation protection glasses [62].
It is mandatory to use a radiation protection apron which should cover at least 60 % of the body surface according to the current DIN Standards Committee Radiology (based on IEC 61331–3:2014–05, subitem 5.4), thyroid protection and radiation protection systems mounted to the patient table or ceiling. Radiation protection of the head-neck region, particularly the eye lens, is expected to become increasingly important. However, there continues to be a need for further development primarily with respect to eye lens dose and monitoring. New radiation protection glasses with integrated dosimeters are expected here so that the exact equivalent dose can be determined and thus the cataract risk can be reduced. In general, dosimetry plays an important role and an EPD should be added to the mandatory monthly dosimeter readouts when possible in order to directly identify dose values and optimize courses of action. This major advantage was able be shown in a current study. Not only the feeling of safety of medical personnel could be increased but also the radiation exposure of medical personnel could be significantly reduced.
Therefore, the correct combination of radiation protection equipment and corresponding dosimetry increases safety when working with X-rays.
