DE2751907A1 - Low dosage dental X=ray diagnostic appts. - monitors and records signal from TV camera sensing image on fluorescent layer due to transmitted rays (NL 5.12.78) - Google Patents

Abstract

The dental X-ray tube/television camera chain employs only 1/100 of the X-ray dose used in conventional apparatus. After passing through the object being examined, the X-rays impinge on a fluorescent layer (5) at the input of an optical system (6-8). A highly-sensitive imager (10), e.g. a television camera, picks up the image formed on the fluorescent layer. The imager's electrical output can be switched either to a tv monitor (15) or to a memory (14) coupled to a video recorder. The exposure control (3) is connected to the X-ray tube (1, 2) and to the camera's control circuitry (13).

Description

X-ray diagnostic apparatus

The present invention relates to an aid of X-ray imaging diagnostic apparatus with a low dose of X-ray radiation and particularly to an X-ray diagnostic apparatus in which an X-ray dose from an x-ray generating source for x-ray examination of Dental disease or the like limited to less than 2/100 of the x-ray dose is used for conventional X-ray imaging of a photographic film is required and an X-ray image of a The object is focused into an image by means of a fluorescent substance is arranged in front of an optical system so that the image of a highly sensitive Imaging device photographed or recorded or through a screen or the like can be observed.

At present, X-ray examination for dental ailments is performed by that an X-ray image is produced directly on a highly sensitive X-ray film, which is inserted into an oral cavity in such a way that the necessary diagnostic Information is obtained. This method is widely used in Japan, and it is assumed that the total number of pictures taken in 1974 89,000,000. The x-ray dose required for an x-ray of a molar region of an adult = is required, is 310 mrad for a single X-ray. This value is considerably higher than the radiation dose of about 60 mrad in the case a chest x-ray. Although the conventional X-ray system partially has been improved to reduce this radiation dose achieves this improvement no more than a certain degree.

While in the case of a general hospital a television system, which uses an image intensifier has recently become popular and the exposure dose at the time of the diagnostic X-ray examination or fluoroscopy in a diseased section that has been greatly diminished will be for the purpose highly accurate information confirmation conventional radiography and development used.

An object of the present invention is to provide an X-ray diagnostic apparatus with a low dose of X-rays, in which an intraoral image, that is different from the image produced by a conventional image intensifier or an X-ray image storage device for a general clinic, by radiography using a highly sensitive imaging device that is in a television system is used, and in which the obtained Image stored in a memory circuit for storing the image and sent to a Screen is reproduced, such as a Cathode ray tube, so that the film development time is off, and that the diseased area can be seen immediately and instantly for diagnosis.

Another object of the present invention is to provide an X-ray diagnostic apparatus to provide with a low X-ray dose, a control unit for Has lowering the dose of X-rays that radiated to the diseased area to at least 2/100 of the X-ray dose of the conventional one Systems.

Another object of the present invention is to provide an X-ray diagnostic apparatus to provide with a low X-ray dose, an X-ray diagnosis with a X-ray dose of 1/100 of the dose can carry out that for the conventional Radiography is required.

An X-ray diagnostic machine with a low dose of X-rays in accordance with the present invention comprises a source for generating x-rays for exposing an object in a diseased area, using an optical system a fluorescent substance for receiving the X-ray radiation on the diaphragm portion of the optical system, a highly sensitive imaging device such as a highly sensitive image pick-up tube with silicon photocathode (SIT), which is directly amoptical System is coupled and an X-ray image of the fluorescent substance is sent Producing a radiography from the x-ray image receives a control unit for amplifying the output from the high sensitivity imaging device and to control the exposure time of the X-rays emitted by the generating source for the X-ray radiation goes out, an image storage memory circuit that on connected to the control unit for storing an image signal from the control unit is, and a screen or monitor circuit for displaying the image signal, wherein the exposure time of the x-ray generating source from the control unit so controlled becomes that its maximum value is still below 1/100 of a second, and wherein an inadequate image of an object by the fluorescent substance is obtained, so imaged with high resolution and high sensitivity is that the image obtained can be used for recording and observation can.

The object of the invention will be based on the accompanying drawing for example, described in more detail; 1 shows a block diagram that shows a sketch of the X-ray diagnostic apparatus according to the invention with a low X-ray dose Figure 2 shows a detailed circuit diagram showing a high sensitivity imaging device Fig. 3 shows a detailed one used in the present invention Circuit diagram that uses a control unit to control the x-ray time, which is used in the present invention, Fig. 4 is a waveform diagram, which shows different waveforms at different parts of the control circuit and is used to explain the principle of the present invention, and Fig. 5 is an explanatory, schematic drawing of an embodiment of a conventional dental diagnostic system in which a television system is used in such a way that an image obtained by an X-ray can be seen.

To explain preferred exemplary embodiments of the invention first the prior art is discussed below.

A proposal was made in which an X-ray image is taken from a picture tube is scanned so that an image thus picked up is displayed on a cathode ray tube is displayed in a television receiver for diagnosis (e.g. Cahier D'Odonto-Stomatologie, Vol. 7, No. 3, 1975).

In such a system, as shown in Fig. 5, an X-ray beam 54 radiated from an X-ray tube 53 against an object 55 such as a tooth. An X-ray beam that passes through the object is generated by a photocathode 57 recorded, which is an image recording primary plane of an image intensifier 56 with a electronic converging lens 58 forms. An image that comes from this X-ray radiation is photoelectrically converted into an electron beam image. This Electron beam image is generated by an electronic converging lens or

Converging lens 58 brought to converge in such a way that a secondary image, obtained from the converging lens 58 is projected onto a projection plate 59 which is arranged in front of an optical system of a vidicon picture tube 62.

Secondary light becomes a bright image, that of the projection screen 59 is removed, transmitted via an optical system 60 to a photocathode 61, which is arranged on an image pickup portion of the picture tube 62. An electronic one Charge image (or an electronic charge distribution) on the image cathode 61 is scanned by a beam generated by an electron gun from the camera tube so that a television signal is obtained. This television signal is resolved amplified, transmitted and reproduced to form a radiological scan image on a Picture tube 64 to represent. However, this system is a theoretical suggestion and is practically unusable because of the resolving power of this system is much smaller than that according to the present invention. If any use is made by an image intensifier of this type, then dimensions and shape the image intensifier is too big for it to be in a mouth instead of a conventional photographic film, making it impossible is to put this system into practical use. At the state of the art an excessively highly sensitive picture tube cannot be used, so that a present a bright optical image on a projection screen in an optical system the picture tube should be projected by taking an X-ray image using of an electronic converging system amplified after the x-ray image photoelectrically converted into an electron beam.

The present invention uses one with a fine grain and high resolution fluorescent material coated film that is in the mouth in a manner similar to X-ray sensitive photographic film Dental diagnosis can be introduced in such a way that an X-ray image that is of a minor X-ray dose obtained is resolved. An optical system that interrupting another light source is like this in front of a highly sensitive picture tube arranged that the X-ray image from the photocathode of the highly sensitive picture tube is picked up by the optical system and that a photoelectric conversion is carried out by the photocathode. Thereupon the exposure time of the X-ray radiation limited to a short time (1/100 to 1/1000 second) so that a highly sensitive Picture tube such as the picture tube of a night vision device can be used. on this type becomes the exposure time of the X-ray according to the present invention limited to as short a period of time as possible so that an X-ray dose, that is exerted on a human body is reduced, and that of the human Body is less exposed to X-rays. The objects of the present invention can be achieved by having a control or regulating system for controlling and regulating a time period for a scanning beam and a time period for the same X-rays for developed an extremely highly sensitive picture tube.

That is, the present invention proposes the following in order to achieve the Decrease X-ray dose for a diagnostic exposure.

To get a fluorescent image on a fluorescent screen To convert it into an electrical signal as efficiently as possible, it becomes scanning the television camera (picture tube) interrupted while the screen is lit, and the picture is fully stored on the light-receiving surface of the picture tube.

Accordingly, an afterglow time (a few milliseconds) of the fluorescent screen taken into account in determining a picture blanking time, and the frame blanking time is determined to be 10 milliseconds (or one pulse) is longer than the X-ray time.

Light energy that is stored in the picture tube is fully converted into one electrical signal converted by the light receiving surface twice from an electron beam is scanned. The electrical signal is also in a Image storage device such as a scan converter is stored.

Structure and mode of operation of the control circuit for controlling the exposure time of the X-ray radiation is as follows: 1. From a conventional alternating current of 100 V (50 to 60 Hz) turns an input signal A into a square wave B by means of the zero bias of a transistor or one responsive to the absence of a voltage Transistor formed. This square wave B forms a time base for the control circuit. It is also a pulse that comes from a power source with a commercial frequency results in 10 milliseconds.

2. The number of these square waves B is counted to make a signal to generate, which is required in an X-ray television system, the following is described. The signal is sent to a television camera control and an x-ray tube transfer.

A trigger signal C is formed so that a time interval between the trigger signal and the blanking signal from a reset signal in one The kinescope control circuit and the image memory memory circuit are set so that that it is 200 milliseconds.

The image blanking signal D is a signal for adjusting the scanning the television camera. There is a 10 millisecond delay between this blanking signal and the origin of the X-ray signal.

A sampling output is a signal that is sampled twice the television camera triggers and a delay of 10 milliseconds from termination the X-ray radiation until the start of the beam scan.

A signal F is an X-ray signal, where the exposure time the X-ray tube of this at its discretion after the step of 10 milliseconds 10 to 990 milliseconds can be controlled. The actual exposure time is shown on a two-digit digital display.

3. A sequence of activities in the diagnostic system according to the invention is performed by depressing a push button switch. If the Switch is depressed again during the sequence of activities, then will brought all activities to their starting point immediately. Furthermore can every activity can be brought back to its starting point by the Turns off the power supply to the control circuit (by means of a power supply switch).

4. A triac is used to switch the X-ray tube, so that a time delay does not occur. It is also used to operate the triac and also for isolating the power supply circuits between the control unit and the TV camera control and the X-ray tube used photo coupling.

An X-ray diagnostic apparatus according to the present invention is used with reference to the accompanying drawings. In Fig. 1 designated a reference numeral 1 is an X-ray tube, 2 is an X-ray generating source, which is connected to the X-ray tube 1, 3 is an exposure time control circuit with a logic circuit created by the combination of counter circuits and formed to determine the exposure time of the X-ray radiation of the X-ray tube is. The control circuit 3 is connected to the source 2 which generates X-rays. A reference numeral 4 denotes a diagnosis object such as a tooth or a tooth Jawbone, 5 is a fluorescent substance covering the anterior opening of a optical system is arranged covering and interrupts the light, 6 and 7 are Prisms placed on the back of the fluorescent substance are, 8 is a lens system, 9 is an image receiving portion such as a Silicon plate in front of a highly sensitive image recording device 10 is provided, 11 is a picture tube, 12 is an amplification unit with a Preamplifier circuit, a deflection circuit, a high voltage circuit, a Cathode circuit, etc., 13 is a television control circuit with an image intensifier, a synchronization circuit, a sequence circuit, a circuit for power supply constant voltage, etc., 14 is an image memory memory device which is connected to the television camera control circuit 13, 15 is a screen or monitor connected to the television control circuit 13, 16 is one Recording device such as a magnetic recording and reproducing device with a magnetic tape or a magnetic card and 17 is a camera for recording of an image displayed on the monitor 15.

The operation of the X-ray diagnostic apparatus according to the present The invention will now be described with reference to FIG. 1, the diagnosis object such as a tooth or a jawbone between the X-ray tube 1 and the fluorescent one Substance 5 is inserted. When the X-ray tube is brought to radiation, then the X-ray image of the diagnosis object 4 is on the fluorescent substance 5 pictured. The image is generated by the prisms 6 and 7 and the lens system 8 the image receiving portion 9 such as a silicon plate is projected to the the front surface of the highly sensitive picture tube is provided. The highly sensitive Image recording device 10 uses the highly sensitive picture tube 11 such as for example a highly sensitive image pick-up tube with silicon photocathode (SIT) or a calnicon, and the image receiving portion 9 thereof uses the silicon plate or the like to which a high voltage is applied. If any light on this Section 9 hits a charge proportional to the amount of the received light. When this silicon plate from the electron beam the picture tube 11 is scanned, then a current flow is obtained which is proportional to the charge image is. Because this silicon plate extremely high sensitivity burn-out damage will occur if too much light is received will.

As a result, there is an excessive charge on the image receiving device Area 9 accumulated, so that the elements of the silicon plate are damaged. In view of this fact, it is necessary that the exposure time of the X-ray is limited by the X-ray tube 1 to less than 1/100 seconds. Therefore it is necessary that the picture tube be a highly sensitive picture tube such as the SIT picture tube which has a highly sensitive amplifying effect. Used accordingly the present invention provides a highly sensitive picture tube such as the SIT picture tube, to the image memory memory device 14 such as a scan converter the television camera control circuit 13 is connected. A changeover switch 15a is between the television camera control circuit 13 and the image memory memory device 14 for switching the memory device 14 to the monitor 15 or vice versa switched on. That is, the image is stored in the image storage memory device 14 is stored or is on the image receiving surface of the cathode ray tube displayed in the monitor 15 as a fixed still image, depending on the manual or automatic switching of the changeover switch 15a. While the fixed Still picture is observed for the purpose of diagnosis, this picture can be different from a conventional one Still camera, if necessary, can be captured and recorded. When a Disk storage apparatus or the like on the image memory memory circuit instead of the video tape recorder 16 is connected, then the recording a diagnosis can be recorded on a slide of a magnetic disk. This Recording method is convenient and beneficial for diagnostic purposes. Instead of An analog / digital converter can be connected to the video tape recorder and the output of this analog / digital converter is sent to a computer circuit to analyze the output.

According to the present invention, an X-ray image with a good Image quality are recorded on the screen of the monitor cathode ray tube, when a fluorescent image is obtained by using a highly sensitive SIT kinescope, of the calnicon or the like in the one shown in Fig.

1 shown X-ray diagnostic apparatus is mapped.

To record the image, a video tape recorder or A polaroid camera or instant camera can be used to get a clear surveillance picture to obtain.

Fig. 2 shows a detail of the high sensitivity imaging device 10 and the television camera control circuit 13 for controlling the imaging device 10. In the high-sensitivity imaging device, 11DV denotes a vertical baffle, 11DH is a horizontal baffle, 11G is an electron gun, 43 is a preamplifier circuit, 44 a cathode synchronization circuit, 45 a High voltage circuit and 46 a deflection circuit. In the television camera control circuit 13, reference numeral 47 denotes an image enhancement circuit, 48 is a circuit for generating a synchronization signal, 49 is a sequence circuit, 50 is a constant voltage power source, 40, 41 and 42 are terminals that connect to the exposure time control circuit 3 are connected, 50, 51 are terminals, the corresponding on the monitor or screen 15 and the image storage memory device 14 are connected and 15a is a contact of a changeover switch. This television camera control circuit 13 is essential for operating the picture tube 11. As for the picture tube, is the SIT-super high-sensitivity picture tube, which has a silicon plate or silicon photocathode used, most preferable.

The television camera tube using a calnicon can be used will. The specific sensitivity between the calnicon and the SIT picture tube is 1: 100-1000 so that an X-ray dose is less than 1/100 that of the conventional one X-ray photographic facility can be limited.

Fig. 3 shows a detailed circuit diagram of the control circuit 3 for Controlling the exposure time for the X-ray radiation.

In Fig. 3, reference numeral 18 denotes a strater button for starting the operation of the entire circuit of the control circuit 3. A reference numeral 19 indicates a connection for a power supply source of 50 Hz and sinusoidal Waveform. A reference numeral 20 denotes a circuit for preventing vibration or flutter or power surges, in which circuit an input wave is formed and then supplied to a trigger / flip-flop circuit 21, an output of which is fed to the end connection 40 as a start signal via the differentiating circuit 22. The sinusoidal wave applied from the terminal 19 is triggered by a Schmitt trigger circuit 23 changed to a rectangular trigger waveform.

This trigger signal is fed to a decimal counter circuit 24, a delayed flip-flop circuit 32 and an AND circuit 27.

When an output from the trigger / flip-flop circuit 21 is a reset terminal 24R is supplied to the decimal counter circuit 24, then it is reset and starts counting them. Then the decimal counter circuit 24 generates an output signal as a picture blanking signal after ten trigger signals from the Schmitt trigger circuit 23 were counted. This blanking signal is sent to a delayed flip-flop circuit 25 and a terminal 41 supplied. When the output from the decimal counter circuit 24 of the delayed flip-flop circuit 25 is supplied and when the reset signal is supplied to the reset terminal 25R of the delayed flip-flop circuit 25, then the flip-flop circuit transmits an output signal to a subsequent resetting one Flip-flop circuit 26 after a delay corresponding to a timing signal, which is a trigger signal of 20 milliseconds duration that a trigger connection 25t is fed to the flip-flop circuit 25 from the Schmitt trigger circuit 23 will. The output from the reset flip-flop circuit 26 becomes an input terminal the AND circuit 36 is supplied. The other terminal of the AND circuit 36 has one positive voltage, so that this AND circuit 36 generates an AND output signal, that the X-ray tube 1 via a photo coupling circuit 37 and a triac circuit 38 triggers. Then the emission of the X-ray tube begins. The output of the reset flip-flop Circuit 26 also becomes the AND circuit 27 supplied. The other input terminal of the AND circuit 27 receives the output signal from the Schmitt trigger circuit 23 so that both input terminals of the AND circuit 27 record positive voltages and that the AND circuit 27 has an AND output signal which is applied to a decimal counter circuit 28. An output port the decimal counter circuit 28 generates an output signal with each counting operation, which is fed to an exposure time setting switch 34.

The other output terminal of the decimal counter circuit 28 is generated a different output signal for every ten counting processes, that of the following Decimal counter circuit 29 is supplied. When the decimal counter circuit 28 is on Receives an input signal with a duration of 10 milliseconds, then becomes a Output signal with a duration of 100 milliseconds from the decimal counter circuit 29 and a circuit 34 which switches the exposure time. If the AND circuit 36 generates an output signal, then a signal from the X-ray tube 1 is supplied from a terminal 39, and then the X-ray tube 1 starts emitting. If AND circuit 36 subsequently produces a negative output, then produce the trigger flip-flop circuit 21 and the delayed flip-flop circuit 32 are negative Outputs, so that the trigger flip-flop 21 is reset and interrupted. As the delayed flip-flop circuit 32 receives the output from the Schmitt trigger circuit 23, the decimal counters 28 and 29 are reset after 10 milliseconds. When the reset flip-flop 26 is reset, it becomes an input signal the AND circuit 27 negative. The delayed flip-flop circuit 32 counts a trigger signal from the Schmitt trigger circuit 23 after the interruption of the output signal was detected by the AND circuit 36. The decimal counter circuits 28 and 29 are reset by an output signal, which by one counting process (10 Milliseconds) and taken from an output terminal 32Q. While this delay time are the output signals of the decimal number circuits 28 and 29 of an LED display device 31 (display device with light emitting Diodes) fed through a latching circuit 30 to reduce the exposure time to display. Once the self-holding circuit 30 provides the interruption of the AND circuit 36, then the AND circuit 36 maintains its operating state. In view of this, the decimal counter circuits 28 and 29 become after a counting operation stopped. In this way, the LED display device 31 can display its Maintain exposure time.

This relationship is shown in FIG. In Fig. 4 shows a Waveform A is the input signal with a commercially available frequency of 50 to 60 Hz. A waveform B shows the output signal (rectangular waveform) from the Schmitt trigger circuit 23. A waveform C shows a start signal waveform from terminal 40, D is a waveform of a picture blanking signal output from terminal 41, E is the waveform of a scanning start signal sent from the terminal 42 was obtained, F is an adjustment signal for the exposure time, which at the the X-ray generating circuit 2 is applied, G is a vertical one synchronizing signal waveform generated by the synchronizing signal generating Circuit has been generated in the television control circuit, and H is a signal to the Interrupting a signal from the synchronizing signal generating circuit 48 to a deflection circuit 47. The aforementioned interruption is made by the sequential circuit 49 made. The start signal C is immediately after the push button switch 18 was actuated, generated. The image blanking signal D becomes a predetermined time issued after the generation of the start signal C. This time period is assumed to be t2, and this t2 is 200 milliseconds. This start signal C is generated by the television camera control circuit 13 of the image memory memory device 14 supplied, the in a storable state is set. About this receptive state to achieve a delay time of 200 milliseconds for the image blanking signal D required. This delayed image blanking signal D becomes the television camera control circuit 13, in which a beam interruption signal H is generated from an instant to which the first vertical synchronization signal G for the camera is applied. The signal H to interrupt the beam interrupts a cathode ray circuit 45 in the highly sensitive picture tube 11, so that the scanning for reading the picture tube 11 is interrupted. The optical system connected to this picture tube 11 is covered in place of the fluorescent substance 5, and the light image is only transmitted when the X-ray beam hits the fluorescent substance 5. When the vertical sync signal G of the television camera is recorded first then the signal H is generated to interrupt the beam. The reason one such interrupting action for the beam follows. When the beam that on the silicon plate for use in the cathode of the picture tube is not suitable for one The time that corresponds to the X-ray exposure time is interrupted is not a sufficient one Storage time provided for a sufficient amount of electrical charge in the silicon plate of the image-receiving section 9 of the picture tube 11 to be stored. This relationship can be given by a relationship between the X-ray exposure time t3 and the period of time can be set out in t4 for interrupting the beam. The period from the front Edge of the image blanking signal to the leading edge of the X-ray exposure signal F is chosen to be 20 milliseconds.

The reason for these 20 milliseconds follows. During the blanking signal D is in sync with the input signal A and the trigger signal B, that is vertical synchronizing signal G of the picture tube not at all synchronous with these signals, so that when the image blanking signal D is synchronous with the X-ray exposure signal F is to take it can that the generation of the first vertical Synchronization signal G is delayed from a moment at which the X-ray exposure signal F is generated. As a result, the generation of the signal H interrupting the beam is delayed, so that there is the possibility of that there is not a sufficient amount of charge to record a light image in the silicon plate is stored. The X-ray exposure time t3 is set by the circuit 34 for setting of the exposure time switching process and can easily be adjusted to a suitable length can be set. Furthermore, the time period t4 begins a few milliseconds earlier than time period t3. The start signal E for the scan is with some Delay formed after the moment at which the period t3 has ended. This The start signal E for scanning is fed to the television camera control circuit 13, in which the first synchronization signal G is received and the one interrupting the beam Signal H is interrupted under the control by means of the sequential circuit 49. Further r is a time difference of about 10 milliseconds between the time of termination of the period t3 and the moment at which the period t4 ends, to capture a weak beam of light that is fluorescent in an afterglow period Substance 5 is generated by the X-rays.

The following results are obtained when using the X-ray diagnostic apparatus according to the present invention is used for diagnosis.

1. The image field size was 22 mm #. This dimension could be sufficient cover a multi-root molar tooth, its X-ray image on the screen at the same time appeared with the actuation of the device. Accordingly, there was no development necessary.

2. The image recorded in this way has changed over the course of an hour Endurance tests not deteriorated.

3. According to data on a mandibular water phantom, which are in a state equivalent to a state in use is in the human body, is the exposure dose from the apparatus of the invention each time about 1/60 to 1/120 of the dose in the case of the fluoroscopic apparatus according to the state of the art Technique or about 2.6 mrad to 5.2 mrad.

4. Either a positive or a negative image can be used for detailed Examination of an image selected by operating a toggle switch will. If an enlarged image is required for examination, a Enlargement and conversion of the object position by means of a zoom activity below Use a magnifying lens.

5. To get a continuous recording, a screen with a conventional still camera or a Polaroid camera (trade name) or an instant camera photographed. In other words, the present invention provides a new television system for an X-ray fluoroscopic apparatus, with an intraoral fluorescent Image can be imaged immediately with only a low dose of X-ray radiation can and wherein the following advantageous effects can be obtained.

a) The information about the results of the X-ray diagnosis is immediate obtain.

b) The same digestive effect is obtained even with an exposure dose reduced to 1/60 to 1/100 of the dose required in conventional radiography is, and c) the amount of information absorption, in relation to a conventional one X-ray film seen, strong expanded by reinforcement level or magnification and brightness of the monitor can be adjusted so that the resolution this television system is particularly large.

Table 1 conventional improved the present plant plant Invention of radiation 310 mrad 1/5 to 1/6 1/60 to 1/100 dose (250 mrad (2.6 mrad up to 280 mrad) 5.2 mrad) While in general use with a television system is made from a video tape as a recording medium, there is the disadvantage here that a reproductive activity is rather complicated. In view of this fact the present invention employs an image memory memory circuit that uses an output circuit of a picture tube is connected so that a television picture for diagnosis is made available by holding the picture for about 1 hour up Is held or saved for 3 hours.

While in the above-mentioned embodiment of the present invention the optical system comprising a prism, lens, mirror, etc. in Fig. 1 is used, it is convenient to use an optical system for dental diagnostic purposes to use which has optical fibers. In this case it is pointed out that the optical system should shield outside light.

According to the present invention there is an absorbent X-ray dose to less than 2/100 of the dose in the case of a conventional one X-ray radiography decreased by highly sensitive radiographic film, and the fluorescent one Image thus obtained by such X-ray radiation is of the optical system and then imaged by the highly sensitive television camera. As a result, it is possible to display a television picture for diagnosis Can be used under daylight conditions by having a highly sensitive TV picture tube used, such as an oversensitive picture tube (SIT), itself when the light emission energy of the fluorescent image is weak. This picture can only be achieved within a very short X-ray exposure time (less than 1/100 second) exist, so that the picture in the picture memory circuit that was inserted into the TV camera control unit to save the Image on the screen of the cathode ray tube in the monitor circuit for about 30 Record minutes for diagnostic purposes. Accordingly, the development is one Image not required, in contrast to prior art radiography. In other words, the diagnosis can be made immediately after taking a television picture that can be easily recorded, so that an accurate and rapid diagnosis can be realized.

In the case of dental diagnosis in particular, there is an X-ray source placed near a human body on a patient, and it is necessary to take a picture of a tooth or chin bone or jaw area, so it is absolutely necessary to reduce the x-ray dose to less than 1/100 Second. The present invention can meet this need or need Shortening the time to x-ray exposure or exposure to the X-rays by means of a highly sensitive picture tube for recording a fluorescent Offspring, that is converted into a television signal that is then stored on a magnetic disk or the like such that an image seen directly on the screen of the monitoring cathode ray tube can be. Thus, the present invention is very advantageous in that an accurate and rapid diagnosis is realized.

Further, the beam interruption signal for the picture tube becomes on generated little before the generation of the X-ray signal and is generated shortly after the termination of the X-ray signal terminated. To this end is the most logical Circuit in the present invention arranged so that the beginning and end of the synchronizing signals of the beam interrupt signal from the image blanking signal and the start signal for scanning. As a result, there is the silicon plate for use in the image receiving section of the hypersensitive picture tube not subjected to image burn-in. Although the x-ray exposure time to less than 1/100 second by controlling the sync signals to control the sampling period the picture tube is limited, and although the X-ray exposure period is the fluorescent Substance by means of the image blanking signal or the start signal for the scanning is limited, it is possible to realize highly sensitive imaging. In addition, the image, which is used for the dental diagnosis, can be placed on a magnetic disk or magnetic tape and, if necessary, can be recorded on the Screen of the cathode ray tube serving as a monitor are displayed. Accordingly the present invention provides a very useful image diagnostic apparatus of these Kind before.

In accordance with the present invention, a patient's skin takes one Absorption dose of about 5 millirem when the X-rays have an exposure time of 2/100 seconds. In the case of the exposure time of 1/100 of a second the absorption dose about 2.5 millirem, and in the case an exposure time of 1/1000 of a second the absorption dose is 0.5 millirem. The radiation dose is less than about 1/60 compared to the case where the same skin tissue of an existing film that is highly sensitive, or the radiation dose is less than about one hundredth in the case of the same skin tissue is imaged from a conventional radiographic film. Thus, the present requires Invention only a small amount of an absorption dose, so that the dose of radiation can be remarkably decreased on a human body.

In addition, according to the present invention, it is possible the level required when exposure to radiation is about 1/9 of the conventional one To reduce the extent, so that the total absorption dose can be significantly reduced can.

At present, this is the whitening dose in dental radiography strong that 15 people in 100,000,000 are exposed to cancer when the 100th 000,000 people are X-rayed once a year, and that 0.08 people of these 100,000,000 are subject to a similar risk.

This means that it is very important that the exposure dose or radiation dose to decrease on a human body.

In view of this, it is desirable to reduce the exposure or reduce the radiation dose as much as possible in order to suppress radiation risks, even if dental radiography is very useful for diagnosis and treatment. According to the present invention, the required exposure dose becomes less than 1/100 of the exposure dose in conventional radiography, so that the risk in radiography can be substantially suppressed.

Furthermore, the present invention can be sufficient or precise Realize image analysis compared to an image obtained from radiography according to Prior art is obtained, in addition to the lack of the development process. The image according to the present invention can be enlarged in its contrast can be changed or solarized or

reversed by pressing a push button switch.

Claims (3)

Claims 1. X-ray diagnostic apparatus with low X-ray dose, e k e k e n n n z e i c h n e t by: a source (1, 2) for generating X-rays for exposing an object (4) in a diseased area, an optical system (6, 7, 8) with a fluorescent substance (5) to absorb the X-rays on the object side of the optical system, a highly sensitive imaging device (10), which is directly connected to the optical system, and an X-ray image of the fluorescent substance to form a radiograph of the X-ray image receives, a control unit (3, 13) for amplifying the output from the highly sensitive Imaging device and for controlling the exposure time of the X-ray emission from the source of X-rays, an image storage memory circuit (14), that on the control circuit for storing an image signal from the control circuit is connected, and a monitor circuit (15) for displaying the image signal, where the exposure time of the source for X-rays from the Control unit is controlled such that the exposure time is at most one value occupies less than 1/100 of a second, and that a faint object image that appears on the fluorescent substance is obtained, with high resolving power and high Sensitivity is mapped so that the obtained image for recording and monitoring can serve. 2. X-ray diagnostic apparatus with low X-ray dose, it is noted that the control unit consists of a time control circuit (3) for X-ray exposure and a television camera control circuit (13) is. 3. X-ray diagnostic apparatus with low X-ray dose, not shown by: - a source (1, 2) for generating X-rays for exposing an object (4) in a diseased area, - an optical system (6, 7, 8) with a fluorescent substance (5) to absorb the X-rays on the object side of the optical system, - a highly sensitive imaging device (10), which is directly connected to the optical system, and an X-ray image of the fluorescent substance to form a radiograph of the X-ray image - a control unit (3, 13) for amplifying the output from the highly sensitive Imaging device and for controlling the bleaching time of the X-ray emission from the source of X-rays, - an image storage memory circuit (14), that on the control circuit for storing an image signal from the control circuit is connected, and - a monitor circuit (15) for displaying the image signal, whereby the control unit has a logic circuit which is made up of counter circuits (24, 28, 29), and with synchronization signals corresponding to the beginning and terminating a beam interrupt signal from an image erase signal (D) or a scanning start signal (E) can be controlled so that the beam interruption signal generated a little before the generation of an X-ray exposure signal (F) and a is terminated little after the termination of the X-ray exposure signal.