JPH0767861A - Disposable type blood laser irradiation device - Google Patents

Abstract

PURPOSE: To introduce an aseptic light guide up to a necessary length into a vein by arranging a central hole to communicate a cavity of a housing with a cavity of a hollow piston, on one end of the hollow piston in the housing. CONSTITUTION: A device 1 is composed of a housing 2 having an opening 4 to install a needle 5 having a protective cap 6 on one end 3 and an opening 7 to receive a hollow piston 8 on the other end. A hollow hole 9 is arranged on one end of the hollow piston 8, and a cavity of the housing 2 is communicated with a cavity of the hollow piston 8, and an opening 10 to install a solid piston 11 is arranged on its other end. The solid piston 11 has a central hole 12 and a lengthwise directional port 13 to communicate the cavity of the hollow piston 8 with the atmosphere. It also contains an optical fiber 14 placed on the axis of the housing 2, and its one end is placed inside the needle 5. An inside diameter of the needle 5 is set equal to 1.5 times a diameter of a light guide 14, and its other end is fixed in the central hole 12 of the solid piston 11, and slightly projects from the central hole.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of medicine, in particular medical equipment, and more particularly to an apparatus for irradiating blood with light. INDUSTRIAL APPLICABILITY The present invention can be used in any medical field that employs a method of illuminating venous blood with light.

[0002]

2. Description of the Related Art In recent years, phototherapy has been actively introduced clinically. A low-power laser device is used for this. As a method widely used in practice, there is a method of irradiating venous blood with a laser using an optical fiber (fibrous light guide). Optical fibers are thoroughly sterilized in a disinfectant solution before being introduced into a vein. This task is essential for repeated use of optical fiber. In the past, optical fibers were commonly used with connectors. However, such devices are quite costly, and this situation has constrained the wide clinical use of optical fibers. Furthermore, in today's AIDS (Acquired Immune Deficiency Syndrome), or AIDS, eradication, devices for irradiating venous blood with a laser beam must be disposable.

Known devices for introducing pharmaceutical formulations that are unstable in the dissolved state include two cylinders placed in series inside a housing (eg,
French patent application No. 260 4346). One of these two cylinders, that is, the cylinder at the distal end, contains the pharmaceutical preparation which is easily dissolved and adhered to the metal spheres by spraying. In the present specification, the term "far end" refers to a portion of the device placed in a usable position, which is close to the patient and far from the doctor.
A solvent is contained in the other cylinder. The bases of these two cylinders facing each other are made of rubber and act as pistons for each cylinder. A hollow needle with sharp ends is placed between the two pistons to connect the cavities of the two cylinders. The above two pistons are moved by the reaction of a third piston connected to the electric drive. The distal end of the housing is provided with a hole through which the needle is attached, one end of which is rigidly attached to the rubber distal end piston and which has sharpened ends.

When introducing a pharmaceutical preparation into the body of a patient, first, the third piston acts on the second piston. Then, the second piston presses the solvent and causes it to enter the cavity of the first piston. As a result, the pharmaceutical formulation dissolves. Further movement of the third piston advances the needle to inject the pharmaceutical formulation. The structure of the cited device cannot be used for blood collection by venipuncture. Nor can it be used to irradiate venous blood with a laser beam.

As another known device other than the above, there is a device for irradiating venous blood with light (for example, USSR inventor certification No. 1398879). This device is equipped with a light source and an injection needle with a mirror channel (mirror groove),
The mirror channel has a branch pipe fixed to the side surface of the injection needle near the dead end of the injection needle, the branch tube communicating with the inner channel (inner groove) of the injection needle. This branch is connected by a hose to the cavity filled with infusate. A sealed quartz prism is fixed to the dead end of the injection needle, and the front surface of the prism is arranged parallel to the longitudinal axis of the injection needle and at right angles to the light source. The rear mirror surface of the quartz prism is coated with a material that reflects light rays. This mirror surface is arranged at an angle of 45 degrees with respect to the longitudinal axis of the injection needle and the light source.

The introduction of the irradiating light beam into the cavity in the above device is carried out through an infusate which is continuously obtained inside the injection needle and acts as a light guide element. The above device
It is not disposable because its manufacturing technique is quite costly. In these situations, there is a risk of AIDS transmission. Furthermore, this device cannot be used for co-infusion of certain liquids, which limits its practical area of use to a very large extent. It is clearly its chemical composition and flow rate that determine the optical properties of any solution. The above device cannot accurately determine the irradiation power required for blood irradiation.

However, it is known in the known art that the characteristics of a solution and the characteristics of natural water can be rapidly changed by irradiation with light. Therefore, the physiological actions of these solutions and water change, respectively. Injection of such solutions gives unpredictable results. In fact, each use of a new solution results in a new medical method that is qualitatively different from the conventional in terms of physiological effects.

Known in the prior art is a syringe having a housing having a distal end connected to an injection needle for intramuscular injection (for example, Japanese Utility Model Application Publication No. 64-3674). The injection needle surrounds the light guide and a lens is provided inside the housing. Another light guide is secured to the proximal end of the housing (ie, the end closer to the physician), which connects to the light source.

According to the above-mentioned structure of the syringe, the light guide can be positioned inside the needle so that the needle can be used for single intramuscular injection (that is, the needle is disposable). You cannot introduce a guide. If intentionally introduced, the blood vessel may be seriously damaged and the positioning of the light guide in the blood vessel may be incorrect.

Also known in the prior art is a syringe with a housing having at one end a hole for mounting a needle with a protective cap and at the other end a hole for receiving a hollow piston (eg, French patent application No. 2528706). A central opening for communicating the hollow portion of the housing with the hollow portion of the hollow piston is provided at one end of the hollow piston located inside the housing, and the other end of the hollow piston has an opening for receiving the solid piston therein. Is provided.

A member is provided at the distal end of the piston to prevent the piston from completely disengaging from the housing. A central opening closed by a membrane is provided at the distal end of the hollow piston. At the distal end of the solid piston, the above-mentioned membrane is ruptured so that the cavity of the housing communicates with the cavity of the hollow piston, and the two types of liquid mainly enclosed in the two adjacent cavities of the housing and the hollow piston are filled. It has a punch to let it blend into each other. At the far end of the housing is a mixing blade for agitating fresh mixture.

[0012]

The construction of the cited syringe cannot be used to introduce a light guide into a vein. This is because there is no light guide in it and there is no exhaust channel (groove) in the hollow piston. That is, during the movement of the piston, air inevitably enters the vein, causing air embolism in the vein. Also, due to the size of the housing and the central opening of the hollow piston, air tightness is not obtained. Because the dimensions of the housing, needle, and piston are arbitrary, blood collection is not possible even if a light guide is provided and fixed in an airtight position, and the light guide is introduced into the vein to the required length. I can't do it either.

Therefore, it is an object of the present invention to provide a disposable blood laser irradiation apparatus for performing venipuncture for further moving a sterile light guide into a vein to a required length and collecting blood.

DISCLOSURE OF THE INVENTION The disposable blood laser irradiation apparatus of the present invention comprises a housing having an opening for mounting a needle having a protective cap at one end and an opening for receiving a hollow piston at the other end. Then, at one end of the hollow piston placed inside the housing, a central hole is provided for communicating the cavity of the housing with the cavity of the hollow piston,
A hole for receiving the solid piston is provided at the other end of the hollow piston. In the disposable laser irradiation apparatus according to the present invention, a movable light guide is further provided in the housing and the hollow piston, and one end of the light guide is inside the needle having an inner diameter 1.5 times that of the light guide. Placed in
The solid piston is provided with a central hole with a diameter equal to the diameter of the light guide and a longitudinal port that connects the hollow piston cavity to the atmosphere, the axis of which is parallel to the central hole axis. The other end of the light guide is fixed in the central hole of the solid piston, and the correlation between the length of the light guide, the length of the needle, the length of the housing, and the length of the hollow piston is 2.5: 1: 1: 1 with a seal in the central bore of the hollow piston. Further, according to the present invention, the housing and the hollow piston are made of a transparent material, and the outer surface of the housing and the outer surface of the hollow piston have 0, 1/4, 1/2 and 3/4 of the length of the housing. Corresponding to the value of, and the distal end of the housing is marked with a "0", so that when in the initial position the end face of the hollow piston matches the "0" mark on the housing, Also, the end face of the solid piston is "3 /
It conforms to the "4" mark.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail below with reference to the accompanying drawings. As shown in FIG. 1, the disposable blood laser irradiation apparatus 1 of the present invention comprises a housing 2 having an opening 4 at one end 3 for attaching a needle 5. The needle is provided with a protective cap 6. An opening 7 for receiving a hollow piston 8 is provided at the other end of the housing 2. A central hole 9 is provided at one end of the hollow piston 8 placed in the cavity of the housing 2, and this hole communicates the cavity of the housing 2 with the cavity of the hollow piston 8. An opening 10 for mounting a solid piston 11 is provided at the other end of the hollow piston 8.
Is provided. This solid piston 11 has a central hole 12
And a longitudinal port 13 for communicating the cavity of the hollow piston 8 with the atmosphere, the axis of the hollow piston 8 being parallel to the axis of the central bore 12.

The device of the present invention further includes an optical fiber (fiber guide) 14 located on the geometric axis of the housing. One end of the light guide 14 is placed inside the needle 5, and the inner diameter of the needle 5 is equal to 1.5 times the diameter of the light guide 14. The other end of the light guide 14 is fixed in the central hole 12 of the solid piston 11 and slightly protrudes from the central hole. The correlation between the length of the light guide (L), the length of the needle (l), the length of the housing (l), and the length of the hollow piston (l) shows that the needle is in the initial position and during blood collection. It should be 2.5: 1: 1: 1 so that the light guide does not protrude from it.

In the central hole of the hollow piston 8 is installed a seal 15 which is indispensable for maintaining the airtightness of the chamber of the housing 2. The housing 2 and the hollow piston 8 are made of transparent material. The outer surface of the housing 2 and the outer surface of the hollow piston 8 are provided with marks corresponding to 0, 1/4, 1/2, 3/4 of the length of the housing, and "0" is provided at the far end of the housing. (Zero) "mark is applied. In the initial position, the end face of the hollow piston 8 is aligned with the "0" mark of the housing 2, and the end face of the solid piston 11 is "3 /" of the hollow piston.
4 ”mark.

At the position where blood is drawn from the vein (FIG. 2), the end face of the hollow piston 8 is aligned with the "1/4" mark on the housing 2 and the end face of the solid piston 11 remains in the same position, ie the hollow piston 8 It matches the "3/4" mark of. At the position where the light guide 14 is introduced into the vein (FIG. 3), the end face of the hollow piston 8 stays at the same position, that is, it coincides with the "1/4" mark of the housing 2, but the end face of the solid piston 11 does not. It matches the "0" mark. In the use position, this disposable blood laser irradiator is equipped with an optical connector 16 for laser 1
7 (FIG. 4).

The operation of the disposable blood laser irradiation apparatus (FIG. 1) of the present invention is as described below. That is, in the initial position, the end face of the hollow piston 8 contacts the end face of the housing 2, that is, it coincides with the “0” mark of the housing 2, while the solid piston 11
Is pulled out of the hollow piston 8 so that its end face coincides with the “3/4” mark of the housing 2. In the initial position, the light guide 14 is located inside the needle 5 and extends up to 3/4 of the length of this needle.

When performing venipuncture, the light guide 14 is connected to an optical connector 16 connected to a laser 17. The protective cap 6 is removed from the needle 5 and a venipuncture is performed with a pressure cuff on the patient's shoulder. While the needle 5 is being introduced under the patient's skin, a laser glow is generated at the needle opening.
w) decide. The laser glow disappears as soon as the tip of the needle contacts the wall of the vein, but as soon as the tip of the needle enters the blood vessel, the laser glow reappears. At this time, blood collection is performed by moving the hollow piston 8 up to "1/4" of the housing 2 or up to "1/2" mark. This causes the light guide 14 to enter the needle 5 and occupy half the length of the needle.

Once the blood is drawn, the pressure cuff is removed from the patient's shoulder and the next stage is entered. That is, the light guide 14 is moved into the vein. For this reason, the hollow piston 8 remains in its position, that is to say it coincides with the "1/4" mark, and the solid piston 11 moves to the end face of the hollow piston 8 the longest distance, ie to the "0" mark. Note that the end face of the light guide 14 does not coincide with the end face of the needle at the position where the light guide 14 exits from the needle and enters at least the vein. It is very possible that the tip of the needle hits the wall of the vein, but this cannot be visually observed. In such a case, the light guide may strike the vein wall during advancement, but this contact is indicated by mechanical resistance to piston movement. In this case, the doctor must change the position of the needle at the blood vessel opening to remove the obstacle.

To move the solid piston 11 to the end surface of the hollow piston 8, the air in the hollow piston 8 is pushed out into the atmosphere through the longitudinal port 13 of the solid piston 11. Air ingress into a vein can result in fatal patient outcome. Since blood enters the cavity of the housing 2, even if the seal 15 is broken, blood can be prevented from entering the vein. However, if the airtightness is disturbed, air will enter the cavity of the housing 2 at which moment blood movement under pressure will be observed (ie air pressure), in which case the treatment must be stopped immediately. . The irradiation time and the number of irradiation treatments depend on the personality of the disease, the degree of disease progression, and the individuality of the patient. Usually, the time required for one treatment is 30 to 45 minutes. When the irradiation treatment is complete, the light guide 14 is removed from the optical connector 15 and discarded.

Example 1 Patient N, female, 42 years old, medical history on admission: cardiac ischemia, functional grade IV angina. The patient's cardiac ischemia is five years old, according to physician records. However, prior to this treatment, myocardial infarction, arrhythmia, circulatory failure, etc. had no history. When she was admitted to treatment, her complaint was a severe cardiac ischemic attack. This heart ischemic attack occurred even after walking 50 meters or even at rest. The number of cardiac ischemia at rest is 24
I have reached five times in time. Basic treatment: sustak-forte, 6 tablets daily, c
orrinfar, 8 tablets daily, aspirin, 0.125
g, obzidan, 4 times a day, half a tablet at a time. At the same time, the patient was administered 400 tablets of nitroglycerine daily. The findings ECG (electrocardiogram) taken in cardiac ischemia _attack, there is ST segment depression in the induction of V 2 -V _4. Daily electrocardiogram observation shows 0 to 1 ventricular extrasystole
Degree, ie, 36 extra systoles per hour.
The number of incidents of myocardial ischemia was 18, of which 2 were associated with ST segment increase and the remaining 16 were associated with ST segment decline. He was painless 6 times. The total time of ischemia was 108 minutes. Enzymes, LDT ₅ (lactate dehydrogenase), MBPFK (MB fraction of phosphorokinase), ACT (ascarina mina tra)
nsferase) and hemoglobin test results showed no pathological deviation from the normal value. In view of the ineffectiveness of conventional multiple treatments for these special patients, a combination treatment with helium-neon laser therapy was started. Vitamin E (“E” is U for 6 days)
600 mg / day was administered to a background of (based on the vitamin grade of SSR), and intravenous laser treatment was performed using the disposable blood laser irradiation apparatus of the present invention. 1
Each irradiation treatment took 45 minutes and the output at the end of the light guide was 1 mW. The device was discarded after each irradiation treatment. The laser device used is a helium-neon laser device, the spot power of which is 0.5 mW / cm ² . The three areas of Zakharyin-Hedd were irradiated for 1 minute each. That is, the first region is the central part of the sternum, the second region is the fifth intercostal region along the anterior axillary line, and the third region is
The area was the corner of the left shoulder blade. As a result of the above treatment, the patient's condition turned out to be very favorable. At rest, angina did not occur at all, and the patient's tolerance to physical load was improved to functional grade I-II. The dose of nitroglycerin was also reduced to 5 tablets per day. Even in the daily ECG observation (24-hour system), the premature ventricular systole was reduced to 1 hour and 5 times. The number of ischemic incidents was recorded only eight times, three of which were painless. There was no ST segment increase. Therefore,
As can be seen from the above example, the blood laser irradiation apparatus of the present invention can be used for treating a patient suffering from stable angina.

Example 2 Patient S, male, 56 years old, medical history during admission: cardiac ischemia, unstable angina. During the week in which she was admitted for treatment, she had seizures of angina at rest (night), often as many as 4 seizures 24 hours a day. The severity of the angina was functional grade II-III. In the observation of ECG observed 24 hours a day, the ST segment increased by 3 to 4 mm during the nighttime angina attack, and 2 to 7 minutes lasted once the angina occurred. Therefore, the instability of hyperischemia in this particular patient can be explained by the addition of angina with vasospasm or Prince's metal angina. The patient was treated with a continuous nitrate, calcium blocker, and aspirin for a week, but no clinical benefit was obtained with this course of treatment. For this reason, intravenous helium-neon laser treatment was performed every other day, and eight irradiations were performed in the treatment every other day. The irradiation time was 30 minutes against a background of 600 mg / day of deno vitamin E. This laser irradiation treatment was carried out using the apparatus of the present invention. At the end of the sixth irradiation, the patient's condition was completely stable. There was no recurrence of seizures of angina at night. As can be seen from this example, the device of the present invention is also effective for patients with unstable angina.

Example 3 Patient K, male, 53 years old, medical history during admission: Transmural total myocardial infarction (adapted to resuscitation ward). Upon cup-off of Anginal syndrome, a continuous repetitive series of ventricular fibrillation spasms was observed that was stopped by cardioversion. A large-spectrum antiarrhythmic preparation was used, but there was no reliable effect. Next, intravenous laser irradiation was performed using a helium-neon laser device. The output of the device was 1 mW and the irradiation time was 30 minutes. It was the device of the invention that was used. At the end of this treatment, there was no recurrence of ventricular fibrillation spasms and the number of premature ventricular contractions was significantly reduced. As can be seen from this example, the device of the present invention is extremely effective and can be used even in a patient suffering from acute myocardial infarction.

[0025]

The use of the disposable blood laser irradiation apparatus of the present invention makes it unnecessary to disinfect the light guide. This disinfection work takes about 60 minutes with the conventional disinfection method. That is, if the device of the present invention is introduced, more patients can be irradiated and treated. Moreover, the potential for metastasis of AIDS infection is eliminated and other nosocomial infections are reduced.

[Brief description of drawings]

FIG. 1 is an overall view (longitudinal elevational view) showing a disposable blood laser irradiation apparatus of the present invention in a state ready for use.

FIG. 2 is an overall view similar to FIG. 1, showing the state of the device of FIG. 1 after blood is collected from a vein.

FIG. 3 is an overall view similar to FIG. 1, showing the apparatus of FIG. 1 in a state where a light guide is introduced into a vein after blood is collected from the vein.

FIG. 4 is a perspective view showing a state in which the device of the present invention is connected to a laser by a light guide.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Disposable blood laser irradiation device 2 ... Housing 3 ... Housing end surface 4 ... Opening 5 ... Needle 6 ... Protective cap 7 ... Opening 8 ... Hollow piston 9 ... Central hole 10 ... Opening 11 ... Solid piston 12 ... Central hole 13 ... longitudinal port 14 ... light guide 15 ... seal 16 ... connector 17 ... laser

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Galina Mikhailovna Kapustina Soviet Union, Moskoh, Ulyza 26 Bakinskiv Komis Salov, 3, Corpse 1, Kvartilla 48 (72) Inventor Evgeny Hrady Milovich Babenko Soviet Union, Moskovskaya Szyne Oblast, Gorsk, Microlion Rekinzo, 17, Kvartilla 59

Claims (2)

[Claims] 1. A hollow piston having an opening at one end for accommodating a needle with a protective cap and an opening at the other end for receiving a hollow piston, the hollow piston being located inside the housing. In the disposable blood laser irradiation apparatus, a central hole is provided in which the cavity of the housing communicates with the cavity of the hollow piston, and a hole for receiving a solid piston is provided at the other end of the hollow piston. A movable light guide is provided in the housing and the hollow piston, and one end of the light guide is arranged in a needle having an inner diameter of 1.5 times the diameter of the light guide. Is provided with a central hole having a diameter equal to the diameter of the light guide, and a longitudinal port for communicating the cavity of the hollow piston with the atmosphere, the axis of the port being the central hole of the central hole. The other end of the light guide is fixed in the central hole of the solid piston, the length of the light guide, the length of the needle, the length of the housing, Disposable blood laser irradiation device, wherein the correlation with the length of the hollow piston is 2.5: 1: 1: 1, and a seal is provided in the central hole of the hollow piston. 2. The disposable blood laser irradiation device according to claim 1, wherein the housing and the hollow piston are made of a transparent material, and a length of the housing is provided on an outer surface of the housing and an outer surface of the hollow piston. 0, 1/4,
Indicator marks corresponding to the values of 1/2 and 3/4, and a "0" mark at the far end of the housing,
Thus, when in the initial position, the end face of the hollow piston matches the "0" mark on the housing and the end face of the solid solid piston matches the "3/4" mark on the hollow piston. Disposable blood laser irradiation device characterized by the above.