DE1912443A1 - Method and apparatus for determining the volume of a cavity, for example the lung wing of a patient - Google Patents

Description

Keiersren and device to sesti @ sug the volume of a @ohlrenmet, for example the long hair of a patient.

The invention relates to a method for determining the volume of a cavity, in particular the volume of a patient's lung surface, as well as on devices to carry out this procedure.

With today's known methods for @uautitative determination of the volume of each lung in the human body that a tube, welehe is fine-tuned by a doctor or technician, through the air duct to the junction point the @raehea can be @@ hrt in each of the lung surfaces.

Pie introduced gases and withdrawn from each lung surface collected to be @immon the volume of each lung. The insertion of the tube through the heels of the rationten is dangerous and uncomfortable. You have earlier different radioactive gases are used to determine lung function updates, however, the techalkes and devices weren't too complicated and just yielded relative values of the pendulum functions of indeterminate parts of the lungs.

The invention aims to provide a new and improved method indicate new and improved apparatus for performing the process in which the determination of the volume of each dungon wing when viewed from the outside takes place and also the gas flow ia every lung and from the outside it @@ part from every lung will.

@@ s is therefore used to determine the volume of an @ohi space, be @@@ ielaweise the wing of a tadent, a process applied to the according to the invention a known volume of radioactive gas into this cavity hzw. is entered into the patient's lungs, then Gem knew it Volume of the cavity containing gases measured the amount of radiation emitted from the outside is then introduced an unknown volume of this gas to fill the cavity and emitted from the cavity containing the unknown volume of this gas The amount of radiation from the outside is measured and finally the volume of the cavity or the lung filled with this gas is determined by the fact that the determined Radiation amount of the cavity filled with the unknown volume of the gas with the determined amount of radiation from the pilot filled with the known volume of this gas Well-being is compared.

It is useful if the known volume of the gas ar around the Inhalation is introduced so that it enters the patient's lungs and thereby the known volume of the gas in an external orifice of the patient, which leading to the lungs.

The volume of each lung is advantageously in absolute terms Units determined by direct calculation of total counts, which of the Measurement of the radiation obtained from each lung filled with the gas, where the result is a multiple of the counts from the measurement of the radiation for pipes filled with a known volume.

It is beneficial if to determine the gas flow rate of each lung a known volume of radioactive gas in a patient's lungs of the patient and the amount of external radiation emitted by the lungs is measured so that an unknown volume of this gas is used to fill the lungs and the amount of radiation from each containing the unknown volume of gas Lung flaps at two points in time during the breathing process of auten is mesmerized. This is the volume of each lung surface filled with the gas from the measurements at two points in time, the @tmnägn sequence is over-timed in that the measured @trablungsmange from each ounge filled with the unknown volume each of the points in time with the measured amount of radiation from the lungs during precipitation is compared with the known gas volume and that the gas flow rate of each Lungs during the time between the two points in time by determining the volume differences each lung is clotted at the two times.

In order to carry out the process described above, a device that has a dispensing or dispensing system for dispensing a known volume of ludioactive gas into a patient's lungs and for filling the lungs with holds an unknown volume of the radioactive gas, the delivery system is connected between a source of the radioactive gas and the patient. According to Another feature of the invention is a measuring system for blanketing and measuring those of those containing the known volume of radioactive gas Lung outgoing radiation from the outside as well as for measuring the radiation from the with the unknown volume of radioactive gas filled lungs, amount of radiation emanating from it and to compare the measured amounts of radiation from each lung with the measured amount of radiation of the radioactive gas from the lungs, which the known Volume of the radioactive gas contained so as to be the absolute volume of each lung To determine units.

It is advisable if this device contains a measuring device which measures the radiation from each lung and a pulse signal to the data processing device outputs, and if a data processing system is provided that the data over the amount of radiation from each of the with the unknown Volume of the radioactive gas-filled lung collects and stores and with the data about compares the amount of radiation from the lungs containing the known gas volume, Let us determine the volume of each of the lung surfaces in absolute sinuses.

In addition, it is favorable if the departure system is a me @@ and a with the Hef @@ connected means of regulation, the Melgefa a well-known volume of the radioactive gas and the control means as well as the known volume as also that unconscious volume of this gas is released into the lungs.

Forner has proven to be advantageous when dispensing a known gas volume in a cavity before a vessel with calibrated volume is, a first valve is attached to one of the two ends of these vessels and the one end of the vessel is connected to a gas source and a second valve at the other end of the calibration vessel, which is the calibrated gas volume can flow out of the lending vessel, woun the first valve a connection to the Andoreu Gas nelle manufactures.

In the case of a delayed embodiment, the framework contains this one Data processing systems for direct digital meter determination from a drupulseingeng from a measuring device, for direct digital drawing of the measuring arrangement and for direct digital @@@ abe of the result, a Saumler connected to the signal condition to the gathering of a number of ven Biugans - @@@ isen during a bestinate time from one known amount of the test items for the accounting of the data processing device, @ohei the collecting device to sum a number of input pulses from one unknown height of the examination object is used, furthermore a comparison circuit to compare the amount of input pulses from the known amount and the input pulses from the unknown measurement, the comparison circuit au the collecting device connected is, and finally through to the comparison circuit Connected display means for displaying the size of the unknown quantity.

Collecting devices are useful for direct digital zeroing of the system to collect a set of input pulses for a known time from a set of gauzes of the object to be measured and switching devices for adjusting the Collected sets of input pulses from the external or unknown set of the objects to be measured for the purpose of zeroing the input pulses in the data processing system.

The following is the basic in connection with the one embodiment descriptive figures, but for the sake of better clarity, everything is here omitted, which is not necessary for an understanding of the invention.

Linauder corresponding parts are in all figures with the same Provided with reference numerals.

It shows: FIG. 1 a schematic representation of the device for Gas delivery and measurement, Fig. 2 is a block diagram to explain the mode of operation of the device, in particular with regard to the processing of the background radiation, Fig. 3 is a block diagram showing the formation of the formation of the element, Fig. 4 is a block diagram to explain the formation of the formation of the volume value, FIG. 5 is a block diagram to explain the formation of the formation of the vertex of the gas number, 6 shows a more detailed sheet metal image of the measuring direction.

The one shown in detail in the drawings and especially in FIG Embodiment of the invention consists essentially of a volummeter, which a gas delivery system 2 contains. The gas delivery system is used to deliver a homogeneous Mixing radioactive and non-radioactive gases to the outer inlet channel to the windpipe that leads to the lungs. A patient's lungs are denoted by 4 and 4 in the figure. The measuring system 5 checks the radiation from each lung of the vertebrate or human and determines the volume and the Gas flow number or the rate of flow of the gas in each lung.

A known volume of the mixture is used to perform the procedure from the calibrated measuring vessel 6 in the gas delivery system to the outer inlet channel delivered to the trachea at the beginning of a patient's breathing period so as to to bring the known total volume of the mixture into the lungs. The known Volume of the mixture moves / moves as a button of a gas flow deep into the lungs, followed by a non-radioactive gas such as air. The external radiation from these known volume of the mixture in each lung surface is measured, the me @ values or information values are processed and stored in the operator system 5. The known volume of the radioactive gas is exhaled from the mixture the lungs removed. The gas delivery system then delivers a volume of the mixture through the mouth to the trachea and lungs of the tationte during inhalation. This unskilled volume of the mixture fills both lungs. The external radiation the unknown volume of the mixture in each lung is again measured and the relevant information or data group is collected. The collected and saved Information is then processed according to a scheme to be described below, to determine the volume of the lungs in absolute units. A second volume the two lungs is determined during a different phase of exhalation. the changing volumes of both Lungs are in the Detektersgstem 5 processed, in order to determine the gas flow rate in each lung surface.

The gas delivery system 2 is a source of betrayal of misery.

a tank vessel 7 connected. A homogeneous mixture of the radioactive Gases Kenon 133 and air can be used for this. The tank vessel 7, which containing the mixture under pressure is connected to the gas delivery system via a pipe 8. A withdrawal valve 7 is provided between the pipe 8 and another pipe 10, which releases the mixture from the tank 7 when there is a pressure decrease in the pipe 10.

The hat removal valve 9 contains a button d for the cleaning control, where the mixture can also be drained from the tank 7. If the button "No clearance control" is pressed by an operator, the dispensing system is filled with the mixture and all other gases are flushed out of the system. The Rein 10 is with a two-way valve 12 yerbunden.

The calibrated Heßgefäß 6 is with the level of the gas mixture over the valve 18 connected. This valve includes a rotatable part 13 with a L-shaped opening. When the rotatable part is actuated, a connection between the measuring vessel 6 via the passage 14 to the source of the radioactive mixture be made, as shown in Fig. 1, or a connection of the measuring vessel 6 via passage 15 to a source of non-radioactive gas. Finally can the valve 12 is brought into a position to block the passages 14 and 15, so that gas is retained in the measuring vessel 6. The distal mouth of the pipe 17 is open to the atmosphere.

The measuring vessel 6 has a calibrated volume. It is used to be a Measure the known volume of the radioactive mixture, insert it into the surface of the lungs 3 and 4 is submitted. The calibrated volume includes the volume of the tube 8 and the L-shaped one Opening in the Iifleken of the valve 12. The calibration also includes the volume between deill passage 14 and the distal end of the Tube 18, which is shown in FIG.

A dispensing valve 19 is excluded from the distal end of the measuring tube 18. The radioactive mixture can be removed into this valve 19 through the passage 20 on Entering the end of the tubes 18 when the pressure in dcii valve 19 is lower than the Pressure in the measuring vessel 6 is. The passage 20 is closed by a one-way valve 21, which has a valve body 22 and spacers 25 which are connected to the pipe 18 are connected. The one-way valve 21 allows gas to pass through from the MoS vessel 6 into the valve 19, each prevents a gas flow from the valve 19 into the measuring vessel 6th

The valve 19 ent i ': lt a connection or outlet port 24. This connects the valve 19 to the patient's mouth.

The mouthpiece 25 directs the gas into the mouth, the windpipe and the Lungs of @ationten. Nose clips, which are not shown, can be used to block the patient's nostrils.

The valve 19 also contains an inlet opening 26 for non-radioactive substances Gas and an outlet opening 27. Din pipe 28 is connected to the inlet opening 26, to allow air, a non-radioactive gas, to enter the fuel valve 19. The air can enter through the opening 29, the pipe 28 and the opening 27 if the patient's lungs are to be cleaned of the radioactive mixture. A one-way valve 30, similar to valve 21, is attached to tube 28 near the port 26 connected to allow the gas to enter the dispensing valve 19, wibb the opening 29 free and the pressure in the dispensing valve 19 is lower than atmospheric pressure is. A one-way valve 30 prevents gas from passing the spacer 23 through the Opening 76 can flow out. Another one-way valve 31, Sulich the valve 21 is connected next to the outlet port 27, se that the exhaled Gases in the dispensing valve 19 can flow out of this when the patient is out breathes.

A filter device 32 is connected to the outlet opening 27, to trap water, coblene dioxide and the radioactive gas in the exhaled air. The filter catches the radioactive gas for possible re-use and prevents ah a contamination: the ambient air by the radioactive gas. The filter contains a filter tube 33 and coolant 23. Known absorbents for water and Carbon dioxide 35 and 36 are contained in tube 33.

Lin filter for radioactive gas 37 is located in the tube between the absorbents 35 and 36.

3 if radioactive xenon 155 is used as radioactive gas as filter material activated carbon in a part of the tube 55 attached, which of a "coolant 34. The coolant may, for example, be a freezer or be a Küblbad. The coolant 34 is used to Tomporetur the activated carbon to improve the absorption of the radionic kenon gas.

In the device shown in Fig. 1, signal triggers 38 and 39 in the gas delivery system "can be provided for various actions in the detection system 5 trigger.

The signaling devices 38 and 39 are provided to prevent the opening or to monitor the closing of a one-way valve 31. When the valve 31 opens or closes, a light beam between the light source 38 and the photosensitive Element 39 interrupted or restored.

The light-sensitive element 39 transmits a signal to the detector system 5. This signal is used to trigger various ions in the detector system 9 loosen.

The radiation from the lungs 3 and 4 of a pationte is from tested externally with the aid of measuring devices 40 and 41. The means are radioactive radiation counters.

The field monitored by each menu device is through lead shields denoted by 42. These @shields surrounded a path between the left long wing 3 and the left measuring device 41 and the right wing 4 and the right measuring device 40 and prevent the penetration of scattered radiation. The measuring devices 40 and 41 are at a certain distance from the lungs of the Patients attached to mitigate a possible error arising therefrom could be that different parts of the radioactive material in the lungs in different Distances from the measuring device.

Since the radioactive material generates detectable radiation that in relation to the distance between these parts and the measuring means, so becomes the possible measurement error by moving the measuring device at a distance from the -bunge reduced.

Each measuring device measures the radiation from one of the pationee's lungs. The information obtained is transmitted in the form of electrical impulses, which get to the data processing device 43, with iodem Strahlteileechen a pulse is equivalent to. The amount of radiation is determined by the number of pulses which la can be collected in the data processing system for a set time.

For a further explanation of the procedure, reference will now be made to the JIiigtl: en 2, 3, 4. and 5 reference genomlin. The data processing system serves to initially determine the background radiation for each lung in a specified time. The background radiation is measured, stored and in pulse numbers or counts stored in accordance with FIG. 2. The data processing device is used in a second step to collect the e pulses or counts determined in a counter, which arise after the known volume of radioactive mixture in the lungs is introduced and the radiation of each lung is measured for a fixed time, like this in Pig. 3 is shown. The one in this second step from each lung measured data are initially stored with the underground censuses each Lungs compared. If the data obtained from each lung of the second step are equal to the stored subsurface counts for each lung, the counter becomes reset to zero. The measured values from each lung are then stored, added and the sum of the counts of both lungs is used as a calibration factor in a calibration factor counter, saved. The calibration factor value is a size of stored counts, which is equal to the known volume of the radioactive mixture in the lungs.

In the third step, the counters are reset to zero after the known volume of radioactive mixture has been removed from the lungs; the lung cavities are now filled with an unknown volume of the radioactive mixture filled and the radiation of each lung measured for a certain time interval, like this in Pig. 4 is shown. The values obtained from each lung in the fourth Step will first be with the stored value of the background radiation for each Lungs compared. If the reading obtained from each lung in the fourth step is equal to the stored underground count, the counter is reset to zero posed. Now the saved Values which of everyone Lung measurements were compared with the stored and collected calibration factor data.

Every time the incoming values are from the unknown volume of the radioactive material in one of the lungs is equal to the calibration factor a pulse is transmitted, collected and stored in two registers.

Each stored pulse or each bit corresponds to a volume, which is equal to the volume of the calibrated measuring vessel. The total number of bits and the percentage of a bit, if there are more than one, is in one register each saved. A register of each register pair shows the volume of a young visually, which is filled with the unknown volume of the radioactive mixture became. The second register of each register pair is used to store data for the flow rate as explained below.

In the fourth step, a second volume is determined after the Volume of each individual boy is determined as described above and the counter is up ull have been set. This second volume is subtracted from the first volume in order to to determine a value for the gas flow number, d. H. a number for changing the volume each lung during a specific time interval. After a certain expiry The radiation of each lung is given for the given time from the beginning of exhalation Time interval measured as shown in FIG. The determined data of this Lungs are first stored with the counts of the background radiation for each hange compared. If the measured data of each lung at the fifth step are equal to the counts of the background radiations, so Wirt. the counter to zero deferred. The values collected from each lung are then combined with the stored values Calibration factor values compared. Whenever the entering values of dom are unknown volume of radioactive material in each dungeon is equal to the elk factor a negative pulse to a second register in each register couple transferred to subtract a bit. The second register subtracts automatically the second volume from the stored first volume and provides an optical Representation of the volume of gas removed from the lungs during exhalation. That exhaled gas volume during a certain time is the gas flow number.

Fig. 6 now shows the detector system, which the measuring means 40 and 41 and shows the data processing system in connection with these measuring means. the Measuring means or radiation detectors 40 and 41 are equipped with switching devices 50 and 51 connected. The radiation detectors are used to measure the radiation from the lung surfaces during operation of the volumeter to increase the volume of each half of the lung and determine the flow rate data for each lung of a patient. the Radiation detectors can either be activated manually by the operator or automatically by a Triggerein direction in the gas delivery system. the Radiation detectors determine the radiation for a preset period of time, æ. B.

half a second. The information determined is sent to the i) data processing device transmitted in the form of electrical impulses.

These pulses or counts from the pulse counter are converted to digital Processed to the volume in the lungs and the flow rate of the shape Gas from each lung in absolute units.

The data processing often comprises: holding means 50 51; register 52 and 53 for background radiation, connected to corresponding switching devices ; Counters 54 and 55, with corresponding switching devices and also with the registers 52 and 53 for the background radiation are connected. As connecting links serve comparison circuits, which are identified by 56 and 57; Calibration factor counter 58 and 59 associated with both switch devices and with counters 54 and 55 respectively Comparison circuits are connected; the latter are denoted by 60 and 61; Switch 62 and 63 in conjunction with respective counters 54 and 55; and two registers 64, 66 and 65, 67, which with corresponding switches 6 ?. and 63 are connected.

When starting up, the volumeter is used in the following way. The patient is seated in front of the gas delivery device. The measuring means 41 and 40 and the Shields 42 are adjusted at the correct spacing with respect to the patient. The measuring equipment and the data processing system are now switched on.

To determine the background radiation, as in FIGS. 2 and 6, the measuring devices 40 and 41 operated so that the background radiation for a set time interval. The measured information is in Form electrical pulses via switches 50 and 51 to the background register 52 and 53 transferred. There the electrical impulses are collected and in them Lying registers 52 and 53 are stored.

Then the calibration factor is determined. The calibration factor is a representation the known volume of the radioactive mixture in the patient's lungs in Values of the stored pulses or counts of the detected radiation. The gas delivery system is operated for this purpose in order to obtain a calibrated volume of the reactive mixture released into the patient's lungs. The two-way valve in Fig. 1 is set so that it connects passage 14 with passage 16, the flush button 11 of the dispensing valve 9 is actuated to the measuring vessel 6 with the homogeneous mixture of radioactive and dee to fill the non-radioactive gas. The valve 12 is used to cut off the entrance path to the measuring vessel 6 actuated, so that a pressure decrease in the valve has no effect the calibrated volume of the mixture of the mixing tube 6 has. The valve 19 is flushed, to remove all radioactive gas residues from moving air through valve 19 into the filter device 32 to remove. Then the patient puts his lips over that Mouthpiece 25. The patient breathes through the mouth, inhaling air through the opening 26 and exhaled through port 27. While the patient is still breathing his mouth pushes out, the valve 12 is actuated again, so that passage 15 with passage 16 and port 29 in tube 28 is closed, the patient begins inhale now, the low pressure in valve 19 opens valve 21, and the known volume of the mixture in the measuring vessel 6 moves through the valve 19 deep in the patient's tongue.

The measuring devices 40 and 41 take the radiation from each half of the lung for the preset time interval, which can be seen in more detail in FIG and is shown in FIG. The detected information is the counters 54 and 55 forwarded. It is stored by comparison circuits 56 and 57 with the Background information in registers 52 and 53 are compared while the counters 54 and 55 receive the measured information.

When the counts registered in each counter are equal to the counts of the stored background, the counters 54 and 55 are reset to zero. The measured data for each half of the lung are then transmitted via switching means 50 and 51 transferred directly to the calibration factor counter 58. The values of both tongues will be collected, added and stored in the self-factor counter 58 as a calibration factor.

If an additional reading of the background radiation is required after the calibration factor has been determined, the background registers 52 and 53 reset to zero. The new measurement for underground radiation is obtained after the radioactive mixture has been flushed from the tongues is what in the same way as in the original identification of the subsoil radiation occurs; this has already been explained and described with reference to FIG. if the operator of the device does the original underground count during the Dimensioning to want to use, the sub-registers 52 uno 53 not zeroed.

The known volume is used to determine the volume of the two lungs the radioactive mixture removed from the lungs dadurcii that the patient through the opening 27 in the filter 32 exhales, with moisture, carbon dioxide and the radioactive gas is removed from the exhaled gas volume. The patient breathes Air is normally admitted through port 26 during the purge action. after this the valve 12 has been actuated to connect the openings 14.- and 16, the Control button 11 on the extraction valve 19 pressed so that the air from the measuring vessel 6 is removed and the measuring vessel is filled with radioactive mixture the gas delivery system is operated in such a way that the patient's mouths with the mixture of the radioactive gas.

The operator of the device closes the opening 29 in the supply line 28 when the patient exhales. If the patient now inhales, the pressure drop causes the pressure drop in the valve 19 an opening of the valve 21 and thus causes a drop in pressure in the ear 10 which actuates the dispensing valve 9. The mixture is taken from the tank jar 7 and fills the patient's lungs with the radioactive mixture, ref Except for the residual volume of air in the lungs and that in the trachea, the mouth and air remaining in valve 19. If the volume of each lung is immediate, i.e. H.

between full exhalation and full inhalation is determined, so shows the volumeter indicates the volume of radioactive gas in the lungs, namely the Absorption capacity of each lung minus the volume of the trachea, mouth and Valve 19 (because of the air remaining there). After filling the lungs with radioactive mixture, each lung is measured and the measured radiation in pulse form to counters 54 and 55 via switches 50 and 51.

The counts originally collected in counters 54 and 55 become via comparison circuits 56 and 57 with the counts of the stored background radiation in .Register 52 and 53 respectively. When the initially collected counts in counters 5 and 55 equal to the counts of the background radiation in the registers 52 and 53, the counters 54 and 55 are reset to liull. Be on it the stored counts via comparison circuits 60 and 61 with the counts compared that in that. Calibration factor counters are stored. Every time the accumulated Counts in each counter 54 and 55 equal to those stored in the calibration factor counter Are counts, a pulse through switches 62 and 63 becomes the register pairs 64, 66 and 65, 67 fed. The number of pulses and the percentage of a pulse, if any impulses are present, the volume of the right lung is shown optically Register 64 and that of the left lung at register 65. The volume measurement described above is maintained while the patient is holding his breath.

Because of this, the maximum or minimum volume of each Lungs can be easily identified. When the lungs for a set time interval are measured while the patient is exhaling or inhaling, the obtained Volume that of the lungs at an intermediate stage during the set Be measuring time.

The gas flow rate of each lung can be determined after that first volume of each lung is measured as set out above. The first Volume of each of the patient's lungs was determined after the lung cavities were filled with an unknown volume of the radioactive mixture. The lungs were measured while the patient was holding his breath.

A second volume can be determined after counting the counters 54 and 55 are reset to zero under patient with the exhalation the radioactive mixture begins. This second volume results after a specific time after the start of exhalation of the radioactive mixture. The signalers 38 and 39 identify the start of the patient's exhalation cycle. A temporally delayed trigger signal is transmitted to the data processing device to there initiate the lungs of the patient's lungs for the specified time interval.

The meter detects and transmits the radiation from each lung the counts to counters 54 and 55. The original counts recorded in Counters 54 and 55 are stored with the counts of the background radiation in registers 52 and 53 compared. The comparison is made by the comparison circuits 56 and 57. If the initially stored counts equal the counts in the underground register are, the counters 54 and 55 are reset to zero. Then the collected data measured from each tongue with the stored and collected data of the calibration factor via comparison circuits o ° and 61 compared. Every time the incoming pulses or counts equal the counts in the calibration factor counter 58, a negative pulse is applied via switches 62 and 63 to registers 66 and 67 supplied for the gas flow rate. The negative impulses and the percentage of an impulse, if some are present, are collected from the and stored Subtracts counts representing the former volume. The rest is the same the volume of exhaled gases. The remainder divided by the specific time lapse is equal to the gas constant flow rate of each lung.

The gas flow rate can be shown optically on a chart recorder will. The digital counts of the information in registers 66 and 67 become for this purpose converted into analog values and recorded as a signal on the tape recorder, which changes continuously over time.

Lead shields of symmetrical selected shape can also be used are placed over selected parts of both lungs, -to only the radiation measure from parts of each lung.

These numbers can be used for diagnosis, although they are exact Dimensions of the uncovered parts of the lungs are of unknown volume.

The data processing system allows with relatively simple Devices a relatively simple direct digital measurement of a parameter, which is taken from a pulse input from a measuring system. Ms is also possible herewith a direct digital calibration and - if desired - a zero position: and read the measurement directly digitally. The result can be in absolute terms Lines can be read. The measurement by the; System determined size can either be the radioactivity of a radioactive gas or it can be others Quantities are determined, such as the weight, the pressure, the brightness variations or other similar metrics from other sources. If the established Relate input signals to weights, pressures or similar quantities, so transformed the detector system converts the input data into a pulsating output value. Through this the - described data processing system becomes an uncomplicated processing system, which includes a calibration and zero setting for each measurement of the magnitudes to be measured and Allowed for any measurement of different size. The measure of the zero position is used to create a net worth.

The zero value means e.g. the background radiation, as described above, or the blank value or the tare weight; he is determined to proceed in the system the determination of the sizes of the objects to be measured using certain data disguise the system. The present invention has been completed based on those embodiment illustrated and described, considered to be the most practical and beneficial will. However, this embodiment can deviate within the scope of the invention and therefore the invention is not intended to be limited to that illustrated and described Hinzelhelten be limited.

Claims (16)

@@ n @@ l 1. Procedure for determining the volume of a cavity, for example the wing of a patient's wing, d u r c h ek e n n z e i c h n e t that a known volume of radioactive gas in this @onlraum or in the lungs of the patient it is reported that they were aware of this Volume of the cavity containing the gas, emitted radiation levels measured from the outside It becomes apparent that an unknown volume of this gas is then introduced into the cavity that the cavity containing the known volume of this gas emitted amount of radiation is measured from the outside and that the volume of the cavity or the lung filled with this gas is determined by determining the Radiation amount of the cavity precipitated with the unknown volume of the gas with the determined @trsldan s amount of the filled with the known volume of this gas Cavity is compared. 2. Procedure for equalizing the volume of each of the brackets of a Patients after the statement @@ d, d u r c h e k e n n n n e i c h n e t that the known volumes of the gas at the beginning of the linatment is introduced so that it is in the pationt's lungs. 3. Method of measuring the volume of each of the lungs of a lung Patients according to claim 2, d u r c h e k e n n n e i c h n e t that the known @ volume of the gas into an @ outside body opening of the satient, which leads to the lungs is entered. 4. Method of determining the volume of a patient's lung area according to Napruch 3, that the radiation wchrend a known time interval is measured and the @@ e @@ eite of this radiation be collected in the form of counts. 5. @experienced in determining the volume of the sungflag of a stient according to claim 4, d u r c h g e k e n n n z e i c h n e t that the volume of each Lung wings in absolute pages by direct calculation of the total counts is determined by the measurement of the radiation from each with the gas The result is a multiple of the counts results from the measurement of the radiation with lungs filled with known @ em @ volume. 6. The method according to claim, d a d u r c h g e k e n n z e i c h n e t that for determining the gas flow rate of each of the lung surfaces in a patient a known volume of radioactive gas is introduced into the patient's lungs, emitted by the compounds containing this known volume of gas Beam amount measured from the outside that an unknown volume of this gas to the Filling the lungs entered the amount of radiation from each the unknowable volume of the gas absorbing wing at two points in time during the breathing process Measured from the outside, @@@@ the volume of each annealing surface precipitated with the gas the measurements at the two points in time of the respiration decrease thereby determined e @ rd, d @ the measured amount of beam from each filled with the puffed volume Dunge at each of the times with the measured amount of radiation from the lungs is compared when filled with the known gas volume and that the gas flow number each lung during the time between the two points in time by determining the Volume differences of each lung at the two points in time will be determined. 7. Apparatus for performing the method according to claim 1, characterized through a dispensing or dispensing system for dispensing a known volume of radioactive material Gas into a patient's lungs and dropping the lungs with an unknown Volume of the radionive gas, with the delivery system between a source of radioactive gas is connected to the patient, furthermore through a measuring system to discover and that of which the known volume of the radionic active Gas containing harmful radiation from outside, as well as to measure the amount of the filled with the unknown volume of the radoactive gas The amount of radiation emanating from the lungs and to compare the amounts of radiation emitted by the lungs of each lung with the measured amounts of radiation of the radioactive gas from the lungs containing the known volume of radioactive gas in this way to determine the volume of each @ lung in absolute units. 8. Apparatus according to claim 7, d a d u r c h g e k e n n z e i c h n e t that the exhaust system has the known volume of the radioactive mixture on beige inhalation enters a patient's body opening, ucl the well-known Volume of the gas delivered to the lungs. 9. Gorät according to claim 8, d a d u r c h g e k e n n z e i c h n e t that the detection system has one measuring device and one connected to the measuring device Data processing device comprises that the measuring device the location of each Lung with and emits a pulse signal to the data processing device and that the Data processing system the data about the amount of radiation from each of the with the unknown volume of radioactive gas valid length @@@@@ old and storage type and with the data on the amount of radiation from the known volume of gas Containing lungs compares the volume of each of the lungs in absolute terms To determine Einhoiten. 10. Apparatus according to claim 9, d a d u r c h g e k e n n z e i c h n e t that the delivery system has a measuring vessel and a control means connected to the vessel contains that the measuring vessel has a known volume of the radioactive Gas absorbs and that the control means both the known volume and the releases unknown volumes of this gas to the lungs. 11. Device according to claim 10, d u r c h g e n n n z e i c h n e t that the measuring device measures the radiation of each of the with an unknown volume of the radioactive gas-filled lung at a second point in time during of the breathing process, the processing system detects the amount of radiation generated collects, stores and in a second stage during the breathing process, these radiation data are shared with each other compares data obtained from the lung filled with a known volume, so as to increase the gas flow rate of each dungeon over the course of time between dn two Measurements to be determined by determining the volume differences in the two lungs. 12. Apparatus according to claim 7, d a d u r c h g e k e n n z e i c h n e t that for the delivery of a known volume of gas into a cavity a vessel with a calibrated Volume is provided that a first valve at one of the two ends of the vessel is attached and one end of the vessel is connected to a gas source and a second valve is provided at the other end of the calibration vessel, which the calibrated volume of gas can flow out of the calibration vessel if the first valve has a Establishes connection to the other gas source. 13. Gerdt according to claim 7 with a data processing system for direct digital parameter determination from an impulse input from a menu device, for direct digital measurement of the measuring arrangement and for direct digital result indication through a signal input, a collector connected to the signal input for Collection of a number of input pulses during a certain time from a known amount of the object of investigation to use the data processing device, wherein the collecting means is for collecting a number of input pulses from one unknown quantity of the object under investigation by means of a pre-adjustment circuit to compare the amount of input impulses from the known lung and the input impulses from the unknown set, the comparison circuit to the collecting device is connected, and by aneigenmittel connected to the comparison circuit to display the size of the unknown amount of the object. 4. Gorät according to claim 13, d a d u r c h g e k e n n z e i c h n e t that the Sa @ mler contains a first Seameleiurrichtung for collection and Speieher @@ A lot of input impulses, which are horrific from the amount of knowledge of the object and a second collecting device for collecting that amount of input pulses, which originate from the unknown quantity of the object. 15. Apparatus according to claim 14, d a d u r c h g e k e n n z e i c h n e t that the first and z @@@@ te @@@@ give away loreinrichtung with tax provisions are which for the new direction of the system for each measurement of the pulse input to serve. 16. Device according to claim 15 for direct digital resetting of the System characterized by collecting devices for collecting a set of input pulses for a known time from a zero quantity of the object to be measured and through switches for adjusting the collected amounts of bing eye impulses from the known or unknown quantity of the measurement object for the purpose of zeroing the input pulses in the patent processing system.