CN1241395A - Digital near-infrared medical imaging and foreign body positioning unit - Google Patents
Digital near-infrared medical imaging and foreign body positioning unit Download PDFInfo
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- CN1241395A CN1241395A CN 99110835 CN99110835A CN1241395A CN 1241395 A CN1241395 A CN 1241395A CN 99110835 CN99110835 CN 99110835 CN 99110835 A CN99110835 A CN 99110835A CN 1241395 A CN1241395 A CN 1241395A
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Abstract
The present invention relates to the technology of applying image treatment in medical area. The present invention includes multichannel near infrared laser emitter circuits, multichannel laser receiver circuits and amplifier circuits corresponding to the emitter circuits, an automatic scanner unit connected between the emitter circuits and the receiver circuits, and a signal acquisition and image treating system comprising signal acquisition board, scanning control board, microprocessor and software stored in the microprocessor. The system has stable performance, high reliability and high resolution and the image after pseudo-color treatment is intuitive, understandable and clear.
Description
The invention belongs to near-infrared laser, computer, machinery, the complex art field that electronics and Flame Image Process are used in medical science.
At present, the method for existing near infrared light imaging is mainly following two kinds:
First kind is thermal infrared imager: with the planck law is theoretical foundation, utilizes the near infrared band video camera, by the infrared energy of Measuring Object, and is converted into the signal of telecommunication, thereby determines the Temperature Distribution of object, and with gray scale or pseudo-color mode imaging.Medically, thermal infrared imager is the temperature contrast by zones of different on the human body surface, judges the physiological property and the variation thereof of internal physiological tissue indirectly.It is generally acknowledged that the normal human has the height thermal symmetry, thermal infrared imager is by asymmetric the noting abnormalities of human body heat.Because the thermal infrared imager coincidence rate is low, not fogging clear, be difficult to judge whether foreign body exists.
Second kind is simple mammary gland scenograph: adopt continuous visible light or near infrared light breast one side, place the near-infrared video camera at the breast offside and receive transillumination as detector, and observe the breast variation by monitor.Domestic this instrument of most employing carries out breast examination at present.Because adopt continuous light irradiation breast to have the tissue of strong optical scattering property like this, therefore picture contrast and the resolution that forms is very low, causes this quasi-instrument misdiagnosis rate height.1991, in III quasi-instrument was listed it by food and drug administration, and thought that this instrument is not suitable for breast examination.
In sum, two above-mentioned quasi-instruments all exist some defectives, that is: position, the resolution that can't accurately locate foreign body is low, method only rests on qualitative (" nothing " foreign body promptly " is arranged "), can't quantitatively determine the size of foreign body, more can't carry out imaging tissue and foreign body wherein.
The objective of the invention is to, for overcoming the weak point of prior art, a kind of digital near-infrared medical imaging and foreign body positioning unit are proposed, adopt the high frequency near-infrared laser as detection light source, by receiving the scattered photon that sees through human body, physiological tissues such as human body soft tissue such as mammary gland are carried out imaging, have stable performance, good reliability, the resolution height: become image to adopt pseudo-color method to handle after, have intuitively, understandable, characteristics such as clear layer.
The present invention proposes a kind of digital near-infrared medical imaging and foreign body positioning unit, it is characterized in that comprising, multichannel near-infrared laser radiating circuit, and corresponding multichannel light-receiving of this radiating circuit and amplifying circuit, be connected in automatic sweep apparatus between this radiating circuit and reception and the amplifying circuit, the signals collecting formed by signal acquiring board, scan control plate, microcomputer and the corresponding software program in the microcomputer that is stored in handle imaging system.
Above-mentioned multichannel near-infrared laser radiating circuit can comprise: near infrared laser and drive circuit thereof produce the 50MHz signal generator that high_frequency sine wave is input to the near-infrared laser drive circuit; Said multichannel light-receiving and amplifying circuit comprise, will be converted to the optical-electrical converter of the signal of telecommunication through the optical signal of physiological tissue, and the signal of telecommunication that this optical-electrical converter is exported passes through preamplifier and the demodulator amplifier of separating the mediation amplification.
Said automatic sweep apparatus can comprise, two transparency glass plates of clamping physiological tissue to be measured, be used to guide the emission light guide bundles array of a plurality of light sources and receive the light guide bundles array, said emission light guide bundles array is relative in twos with reception light guide bundles array, be separately fixed at the glass plate both sides, drive said two glass plates and carry out synchronous shift and the motor that on 180 ° of directions, rotates.
Whole testing process is controlled by the corresponding software program that is stored in the microcomputer, checks that step process is:
1. startup microsystem, fixing physiological tissue to be measured, and definite scanning starting position and motor moving step length.
2. one dimension detects: the optical signal of laser tube output shines a side of physiological tissue by light guide bundles, and the light guide bundles of offside is delivered to light-receiving and amplifying circuit with the optical signal that receives.A plurality of emission light guide bundleses are relative in twos with a plurality of reception light guide bundleses.Under microcomputer control, order is opened corresponding laser tube and optical receiver, carries out one dimension and detects, and go into the microcomputer storage by the data acquisition plate digital is laggard.
3. two-dimensional scan: after one dimension detected and finishes, microcomputer was by scan control plate control step motor movement, and realization is launched light guide bundles and received the same moved further of light guide bundles.Then, carrying out one dimension once more detects.Up to the detected tissue of whole scannings, thereby finish two-dimensional detection.
4. the detection data are kept in the microcomputer with the form of file, carry out date processing and pictorial display then.Date processing comprises: the most probable path is handled and calculated to Filtering Processing, deblurring.
Imaging system resolution of the present invention is: for Intralipid solution (volume is about 400 milliliters, and its scattering coefficient is similar to human body soft tissue such as mammary gland tissue) (74 * 69 * 143) millimeter of 0.25% concentration
3In, the resolution of the single body of high absorption coefficient is 3 millimeters objects of diameter, it is 8 millimeters that the I between the scattering object of high scattering coefficient is distinguished distance, is the 8-10 millimeter to the distinguishable distance of the relative high scattering coefficient object with of a high absorption coefficient object.The scattering coefficient of the object of high relatively scattering coefficient is about 100 millimeters
-1(concentration of Intralipid is about 1%).The distinguishable distance of the object of two high relatively scattering coefficients is the 10-12 millimeter.Foreign body resolution to actual fatty tissue (thickness is 30 millimeters) is 8 millimeters.(above distinguishable distance all refers to object inward flange distance)
The present invention can be used for the detection of clinical breast carcinoma, brain function detection etc.The canceration or the physiological function that also can be used for simultaneously other physiology soft tissues detect.Because light source is modulated onto very high frequency, to several GHz, the transillumination amplitude is mainly from the contribution of lacking the evolving path photon as tens MHz, and the contribution of long the evolving path photon is suppressed.Compare native system stable performance, good reliability, resolution height with common transmission imaging device; Become image to adopt pseudo-color method to handle after, have directly perceived, understandable, characteristics such as clear layer.
In addition, the present invention utilizes the most probable the evolving path, realizes the three-dimensional localization of tumor.Tumor-localizing precision of the present invention is: for mammary gland tissue, the located lateral precision is 0.5 millimeter, and the longitudinal register precision is 1 millimeter.
Brief Description Of Drawings:
Fig. 1 is the population structure block diagram of digital near-infrared medical imaging of the present invention system.
Fig. 2 transmits and receives schematic diagram for single channel near-infrared laser of the present invention.
Fig. 3 is the automatic sweep apparatus sketch map of imaging system of the present invention.
Fig. 4 is the software control process chart of imaging system of the present invention.
Fig. 5 is the 50MHz signal generating circuit schematic diagram of present embodiment imaging system.
Fig. 6 is the optical receiving circuit schematic diagram of present embodiment imaging system.
Fig. 7 is the band pass filter circuit schematic diagram in the present embodiment imaging system amplifying circuit.
Fig. 8 is the low-pass filter circuit schematic diagram in the present embodiment imaging system amplifying circuit.
The present invention designs a kind of digital near-infrared medical imaging and foreign body positioning unit embodiment is described in detail as follows in conjunction with each accompanying drawing:
Fig. 1 is the population structure block diagram of digital near-infrared medical imaging of the present invention system, comprises multichannel near-infrared laser radiating circuit, automatic sweep apparatus, multichannel light-receiving and amplifying circuit, signal acquiring board, scan control plate, and microsystem.Microcomputer is a System Control Center, adopts Pentium CPU, the 32M internal memory.Control the switching of multi-path laser radiating circuit and light receiving amplification circuit on the one hand by the mechanical switch of scan control plate, also control step motor movement simultaneously, thus finish two-dimensional scan.Optical receiver adopts photomultiplier tube and common PIN photodiode dual mode to realize the conversion of optical signal to the signal of telecommunication.The photomultiplier tube conversion effect is good, and common PIN photodiode volume is little, realizes easily.The light receiving amplification circuit output signal by being inserted in the PS-216 signal acquiring board on the computer motherboard, entering the microcomputer storage, and after the end to be scanned, carries out the date processing imaging.
Fig. 2 is the single channel near-infrared laser emission in the imaging system of the present invention and receives schematic diagram.Going up frame of broken lines among the figure is the near-infrared laser radiating circuit, and following frame of broken lines is an optical receiving circuit, and the centre is a physiological tissue to be measured.
The near-infrared laser radiating circuit is used to produce high frequency modulated laser.The high_frequency sine wave that the 50MHz signal generator produces outputs to the near-infrared laser drive circuit, is used for the output optical signal of modulated laser pipe, output 50MHz high frequency lasers.Chopper is used to realize the external modulation of near-infrared high frequency lasers, and the external modulation frequency is 1600 hertz.Laser emission power is 5 milliwatts, and mid frequency is 780 nanometers.
Shine physiological tissue through twice synthetic near-infrared laser by light guide bundles, the light guide bundles of offside will be delivered to optical receiving circuit by the light of physiological tissue.Match with laser tube, the photosensitive response crest frequency of receptor is 780 nanometers.The optical signal that sees through physiological tissue at first arrives photomultiplier tube (PMT) by light guide bundles, and optical signal is converted to the signal of telecommunication.The signal of telecommunication of PMT output amplifies through separating to be in harmonious proportion, then by entering Computer Processing behind the multiplexed signal sampling plate digital.
Fig. 3 is the automatic sweep apparatus of imaging system of the present invention.Physiological tissue to be measured is fixed in two transparency glass plates, is used to guide the emission light guide bundles array of a plurality of light sources and receive the light guide bundles array, and is relative in twos, is separately fixed at the glass plate both sides.Package unit can rotate on 1800 directions, so that in different directions tissue to be measured is scanned.At a time, control only has one road near-infrared laser and relative optical detection circuit work, by multi-way switch circuit, makes multi-path laser emission and optical receiving circuit by to work, realizes that one dimension detects.Microcomputer is realized emission light guide bundles array and receives the same moved further of light guide bundles array that the one dimension by multi-way switch circuit detects again, thereby finishes two-dimensional scan by scan control plate control step motor.
Fig. 4 is the software control handling process of imaging system of the present invention, comprises step motor control module, light source and receiver array switching controls module, data acquisition module, date processing and image-forming module.Date processing comprises filtering, the calculating of most probable the evolving path, deblurring processing etc., and concrete steps as previously mentioned.
Fig. 5 is the 50MHz signal generating circuit of present embodiment imaging system, system uses higher-order of oscillation chip MC1648 to form sine-wave generator as core component, the 50MHz frequency of oscillation is by electric capacity between pin one 0 and the pin one 2 and inductance decision, and pin 3 is the 50MHz sinewave output.
Fig. 6 is the optical receiving circuit of present embodiment imaging system, uses common PIN photodiode and common double bipolar transistor.About 0.7 millimeter of photodiode photosurface diameter, bandwidth of operation is 0.5-60MHz, photosensitive circuit peak response frequency is 780 nanometers.Peace is received in the dark current of PIN pipe<1, and responsiveness is greater than 20 millivolts/microwatt.
Fig. 7 is the band filter in the present embodiment imaging system amplifying circuit, is to be used for the basic circuit that light-receiving and the preposition amplification of amplifying circuit and modulation amplify.Band filter uses the VCVS active filter, by changing R in the circuit
2, R
3, R
4, R
5And R
8Resistance value, not only can change the mid frequency of VCVS, and can adjust amplification.
Fig. 8 is the low pass filter in the present embodiment imaging system amplifying circuit, is the second-order low-pass filter amplifying circuit, can adjust amplification by variable resistance, and uses feedback capacity as frequency-selective circuit.
Claims (3)
1. digital near-infrared medical imaging and foreign body positioning unit is characterized in that comprising: multichannel near-infrared laser radiating circuit, and corresponding multichannel light-receiving of this radiating circuit and amplifying circuit, be connected in automatic sweep apparatus between this radiating circuit and reception and the amplifying circuit, the signals collecting formed by signal acquiring board, scan control plate, microcomputer and the corresponding software program in the microcomputer that is stored in handle imaging system.
2. digital near-infrared medical imaging as claimed in claim 1 and foreign body positioning unit, it is characterized in that, said multichannel near-infrared laser radiating circuit comprises: near infrared laser and drive circuit thereof produce the 50MHz signal generator that high_frequency sine wave is input to the near-infrared laser drive circuit; Said multichannel light-receiving and amplifying circuit comprise, will be converted to the optical-electrical converter of the signal of telecommunication through the optical signal of physiological tissue, and the signal of telecommunication that this optical-electrical converter is exported passes through preamplifier and the demodulator amplifier of separating the mediation amplification.
3. digital near-infrared medical imaging as claimed in claim 1 and foreign body positioning unit, it is characterized in that, said automatic sweep apparatus comprises, two transparency glass plates of clamping physiological tissue to be measured, be used to guide the emission light guide bundles array of a plurality of light sources and receive the light guide bundles array, said emission light guide bundles array is relative in twos with reception light guide bundles array, be separately fixed at the glass plate both sides, drive said two glass plates and carry out synchronous shift and the motor that on 180 ° of directions, rotates.
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CN 99110835 CN1112163C (en) | 1999-07-23 | 1999-07-23 | Digital near-infrared medical imaging and foreign body positioning unit |
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CN 99110835 CN1112163C (en) | 1999-07-23 | 1999-07-23 | Digital near-infrared medical imaging and foreign body positioning unit |
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CN1112163C CN1112163C (en) | 2003-06-25 |
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1307944C (en) * | 2004-07-16 | 2007-04-04 | 中国人民解放军第三军医大学野战外科研究所 | Digital foreign matter position finder |
CN100382750C (en) * | 2003-03-07 | 2008-04-23 | 皇家飞利浦电子股份有限公司 | Device and method for locating an instrument within a body |
CN100464695C (en) * | 2007-03-21 | 2009-03-04 | 北京师范大学 | Optical parameter measuring instrument for mammary gland and its usage |
CN103385734A (en) * | 2012-11-15 | 2013-11-13 | 广州呼研所红外科技有限公司 | Double check comprehensive diagnostic apparatus guiding ultrasound by infrared thermography and detection method of diagnostic apparatus |
CN104144274A (en) * | 2014-07-16 | 2014-11-12 | 北京赛智创业科技有限公司 | Laser scanning imaging system and method |
CN106372403A (en) * | 2016-08-29 | 2017-02-01 | 合肥菲力姆数码科技有限公司 | Medical image output system based on non-invasive imaging |
CN108209859A (en) * | 2016-12-09 | 2018-06-29 | 天津宝仑信息技术有限公司 | A kind of electromechanical integration medical image display device |
-
1999
- 1999-07-23 CN CN 99110835 patent/CN1112163C/en not_active Expired - Fee Related
Cited By (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN100382750C (en) * | 2003-03-07 | 2008-04-23 | 皇家飞利浦电子股份有限公司 | Device and method for locating an instrument within a body |
CN1307944C (en) * | 2004-07-16 | 2007-04-04 | 中国人民解放军第三军医大学野战外科研究所 | Digital foreign matter position finder |
CN100464695C (en) * | 2007-03-21 | 2009-03-04 | 北京师范大学 | Optical parameter measuring instrument for mammary gland and its usage |
CN103385734A (en) * | 2012-11-15 | 2013-11-13 | 广州呼研所红外科技有限公司 | Double check comprehensive diagnostic apparatus guiding ultrasound by infrared thermography and detection method of diagnostic apparatus |
CN103385734B (en) * | 2012-11-15 | 2016-08-24 | 广州呼研所红外科技有限公司 | Infrared thermal imagery is utilized to guide ultrasonic duplication check comprehensive diagnostic instrument and the detection method of this diagnostic apparatus |
CN104144274A (en) * | 2014-07-16 | 2014-11-12 | 北京赛智创业科技有限公司 | Laser scanning imaging system and method |
CN104144274B (en) * | 2014-07-16 | 2017-11-28 | 北京赛智创业科技有限公司 | Laser scanning imaging system and method |
CN106372403A (en) * | 2016-08-29 | 2017-02-01 | 合肥菲力姆数码科技有限公司 | Medical image output system based on non-invasive imaging |
CN108209859A (en) * | 2016-12-09 | 2018-06-29 | 天津宝仑信息技术有限公司 | A kind of electromechanical integration medical image display device |
CN108209859B (en) * | 2016-12-09 | 2021-07-23 | 丹钠美科电子科技(上海)有限公司 | Mechanical-electrical integration medical image display device |
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