AT512226B1 - ADERLASS ADEL - Google Patents

Abstract

Artery needle (1), comprising a first end (2) and a second end and extending between the two ends along the longitudinal axis of the needle cavity (6), which opens as a needle channel at both ends of the needle in each case an opening. The needle channel (6) has a variable diameter, which passes through a minimum value (d2) between the two openings. In addition, the needle has a remanent magnetization, which is aligned substantially in the longitudinal direction of the needle, has a maximum in a central region of the needle and decreases towards the two ends.

Description

Austrian Patent Office AT512 226 B1 2013-09-15

description

ADLER LEAD AND ADERLASS SYSTEM

The invention relates to a bloodletting needle having a first and a second end and a needle channel, namely a running between the two ends along the longitudinal axis of the needle cavity which opens at both ends of the needle in each case an opening, wherein the first Beveled end of the needle, so that this skew forms a needle tip, wherein the needle channel has a variable diameter, which passes through a minimum value between the two openings. Moreover, the invention relates to a bloodletting system containing this needle.

In a blood letting the patient from a blood vessel - usually from a vein, usually in the elbow - removed. For this purpose, the blood vessel is opened, in particular by piercing with a hollow needle, which is recommended for reasons of hygiene and better handling of the bloodletting process and faster healing of the puncture wound. With the tip of the needle, the blood vessel is punctured; The blood flows through the hollow needle and can be collected at the end or at the end of a tube connected to the needle. The collected blood can then be used for diagnostic or other purposes.

In the Hildegardmedizin, for example, in the book "The Hildegard bloodletting " (Licht-Quantum-Verlag, March 2004) of the applicant, a special bloodletting method is described. This allows the separation of thrombosis-prone, thick blood from the valuable, thin, oxygen-rich blood. However, this is only possible if the blood can flow without turbulence, without congestion and turbulence. The medical Hildegard writings say that this can only be achieved by incising the vein. When using conventional needles, however, there is turbulence and dissipation of mixed blood (Mischblauseitung), which on the one hand cause unfavorable physiological effects and on the other hand complicate the diagnosis or even thwart.

Needles for medical purposes with a magnetization are described in US Patents US 4,508,119 and US 5,894,015 and in the publication WO 02/40087 A1. Further needle constructions emerge from EP 2 149 383 A1 and DE 10 2005 027 147 A1.

It is therefore an object of the subject invention to improve the implementation of a bloodletting by means of a needle, which ensures a laminar flow of the derived blood, possibly along the entire path of the blood collection.

This object is achieved on the basis of a needle of the type described above, in which according to the invention the needle has a remanent magnetization; the remanent magnetization is substantially aligned (i.e., with respect to its major component) in the longitudinal direction of the needle, with the remanent magnetization maximizing in a central region of the needle and decreasing towards both ends. Likewise, the object is achieved by a bloodletting system, which includes a bloodletting needle of the type mentioned and a hose connected thereto.

This solution according to the invention provides a bloodletting needle, namely a needle for performing a bloodletting, and a bloodletting needle / tube system, wherein the bloodletting needle is combined with a specially designed tube for connection to the needle. The bloodletting needle / tube system is called here shortly Aderlasssystem, and the Aderlassnadel invention also laminar needle. By the already mentioned and discussed below properties of the needle or Aderlasssystems is avoided that occur during the bloodletting as well as when collecting the blood removed turbulence. This favors desired physiological effects in the patient and also allows a more differentiated diagnosis based on the derived blood. The remanent magnetization is favorable for a positive influencing of the flow behavior of the blood, particularly in the case of the ATP12226B1 2013-09-15.

In order to suppress the occurrence of turbulence, also an inner coating of the cavity with a smooth surface is low. The inner coating may in particular consist of a silicone-based plastic. A particularly reliable laminar flow also results if the length and the inner diameter of the needle in a ratio of about 41: 1 to each other.

This inner coating can be suitably used to realize the variable inside diameter of the invention over a variable thickness of the coating. In particular, the variable thickness between the two openings can pass through a maximum value, so that the variable diameter of the needle channel is due to the variable thickness of the inner coating.

According to a further advantageous aspect of the invention, the needle point is designed such that the slant of the first end is a foremost - i. directly at the needle tip befindliches - segment which extends at a first angle (which is smaller than 90 °) to the longitudinal axis, and then the slope at a shallower angle to the longitudinal axis as the first angle.

In an advantageous embodiment of the Aderlassnadel invention favorable properties when piercing the needle are achieved in that the skew, then forms the frontmost segment, a rear segment with a constant second angle, wherein the second angle is smaller than the first angle , The first angle (c ^) is favorably in a range between 20 ° and 45 °, preferably from 30 ° to 35 °.

In the bloodletting needle / tube system according to the invention, a laminar flow of the blood at the outlet opening (which is located at the needle opposite end of the connected tube) is promoted when the outlet opening is chamfered, preferably at an angle a3 = 23 °.

The invention together with further features and advantages will be explained below with reference to an embodiment of a laminar needle, which is not to be understood as limiting the scope and application of the invention and which is shown in the accompanying figures. The figures show: Fig. 2 Fig. 3 Fig. 4 Fig. 5 Fig. 6 Fig. 7 Fig. 7 Fig. 9 is a plan view of the laminar needle of the embodiment; the front end of the laminar needle in a side view; the course of the inner diameter of the lumen of the laminar needle in a schematic longitudinal section; the generation of the inner coating of the cavity of the needle; the magnetization of the needle; the process of magnetizing the needle; the turbulence-free transition between hose and needle; various reactions of the body due to the puncture; and the blood-letting system, with the needle with the adapter connection at the top and the outlet opening of the tube at the bottom.

Fig. 1 and 2 show an embodiment of the invention Laminarnadel 1; Shown is the pointed end of the needle in a respective plan view (Fig. 1) and side view (Fig. 2). Visible is the end 2 of the needle, which is formed with a skew 3, which forms a tip 4 at the foremost end. In the skew is the opening 5 of the cavity extending along the needle, which forms a needle channel 6 (lumen, see Fig. 3). The needle 1 is made of stainless steel 5KS-304 or FeCuNi alloy and has in the illustrated embodiment at a length of about 43 mm an inner diameter, the between 1.05 2/9 Austrian Patent Office AT512 226B1 2013-09-15 mm at the narrowest point and about 1.10 mm at the two ends varies.

As is apparent from Fig. 2, the needle 1 has a top sharpening. This is designed as a special long cut over the length L of the bevel 3, namely with two angles of inclination (a 1 and a 2) ground The slope 3 is thus divided into two segments 31, 32 corresponding respectively to the angles cti and a2. first segment 31 is preferably shorter than second segment 32, for example in a 1/3: 2/3 ratio to each other, but other divisions which more or less deviate from the ratio 1: 2 are also possible The first segment (eg The second segment 32 is at a smaller angle a2, and in terms of height the two segments have approximately the same height (ie, perpendicular to the axis), so the length of the second segment is corresponding Its flatter angle greater than that of the first segment - here, for example, 2/3 of the total peak length L. This is a pain-free, reduced puncture allows. Favorable values of the first angle are in a range between 20 ° and 45 °, preferably from 30 ° to 35 °; the second angle a2 is selected with a correspondingly smaller value, for example between 15 ° and 30 °.

Referring to Fig. 3, the needle also has an inner surface of the needle channel 6 which is very smooth, e.g. an extremely smooth surface with a silicone coating 8 whose thickness varies over the length of the needle channel. The inner coating 8 of the needle is e.g. achieved by being sprayed, as illustrated in FIG. 4, by means of a fine nozzle needle 7, which emanates at its end a silicone-based material 8a; while this nozzle needle is pulled through slower in the middle part of the needle than at the end parts. It thus forms a continuous towards the middle thickening of the silicone coating. This results in a tapering of the cross section in the μ range towards the middle of the needle length, or in other words a variable inner diameter with d! ≫ d2 < d3 (where d3 = di). This results in a slight functional nozzle effect of the cavity of the needle.

It results from this coating an optimal laminar flow of blood flowing through the needle. This is due on the one hand to the low frictional resistance, on the other hand by the mentioned profile of the silicone coating in the pm range.

In addition, the needle has a magnetization profile, which is illustrated in Fig. 5, which shows a schematic longitudinal sectional view of a central piece of the needle. The magnetization M and associated magnetic field lines are indicated in FIG.

To create the magnetization profile, the center of the needle is exposed to a strong magnetic field by exposing the needle between two oppositely oriented permanent magnets; Here, the needle is moved transversely to the longitudinal direction so that the middle part of the needle between the two magnets is performed - see. Fig. 6. Due to the magnetizable components of the needle material, a remanent magnetization occurs. There remains a slight but sufficiently large magnetization of the needle whose principal component is oriented parallel to the longitudinal direction, which is strongest in the central region (Figure 5) and gradually weakens toward the ends. In interaction with the magnetically influenceable components of the blood, this leads to an improved laminar flow of viscous liquids. This applies in particular to erythrocytes whose outer membrane is known to be negatively charged. This could be proven by experiments: Liquids with increasing viscosity were passed through the needle. The magnetized needle showed significantly better flow characteristics than the unmagnetised needle. These were on average higher by 2 viscosity levels.

The needle allows a turbulence-free flow of the blood (laminar flow). This laminar flow profile is achieved by the conical, silicone-coated profile as already described and by the likewise mentioned magnetic profile. The profile acts similar to a wing in which an adherent laminar flow is achieved. Through the profile of a nozzle effect is achieved. This leads to an accelerated blood flow, and an unhindered flow of the blood is achieved. Due to the suction effect, a blockage of the needle is prevented and also allows very thick thrombosis-prone AT912 226 B1 2013-09-15

Allow blood to drain freely. The magnetic cone, which supports the nozzle function, is achieved by a permanent magnetic field. This magnetic field reduces the adhesion. This prevents the destruction of the platelets. Thus, the coagulation process is reduced. The erythrocytes also remain undamaged. The phenomenon of the roll of money remains as it flows through the erythrocytes. The interaction between the magnetic field of the needle wall and the negative membrane surface tension of the erythrocytes deflects the red blood cells and forces them into a laminar flow.

With regard to the dimensions of the Aderlassnadel invention was found that a length of 43 mm to 1.05 mm diameter led to optimal laminar flow conditions, corresponding to a length-diameter ratio of about 41: 1. This was determined in 235 flow tests. The length may vary to some extent, namely a few millimeters, for example ± 3 mm.

The puncture stimulus, as is known from pain physiology, triggers vital reactions and immune-enhancing mechanisms in the brain. This is illustrated in FIG. The design of the needle, in particular the two-stage top grinding, results in the puncture positive consequences for the patient, in particular an increased immune stimulation and hormonal regulation.

ADERLASS SYSTEM

9, the needle 1 is a component of a blood-letting system 10. The blood-letting system 10 comprises, in addition to the blood-letting needle according to the invention, a plastic tube 9 of a specific length and a diameter selected to match. To connect the laminar needle 1 to the laminar tube 9 needle and hose can be connected by means of an adapter device made of plastic, which includes a needle adapter 11 and matching hose adapter 12. Through the use of an adapter can be achieved by twisting a firm and dense, but at the same time without problem detachable connection between the laminar needle 1 and the laminar tube 9. The adapter type shown corresponds to a Luer connection; As a variant of the adapter connection shown, of course, other known from the prior art, suitable adapter connections can be used.

As already mentioned, an adapter device for connecting the needle is provided at one end of the tube. At the other end, the tube has an outlet opening 13 with a specifically selected acute angle. The tube 9 is preferably as well as the needle 1 equipped with an inner coating 14, for example of silicone-based material.

The special angle of the outflow opening 13 of the tube 9 prevents too rapid expansion pressure loss. It thereby lengthens and stabilizes the laminar flow and prevents too rapid expansion pressure which leads to turbulence of the outflowing blood. The tube system also allows a safe drainage, collecting the blood and provides the conditions for the vital diagnostics of the blood.

The tube 9 is preferably made of polyvinyl chloride and is thus free of latex and diethylhexyl phthalate. Advantageously, the tube is also equipped on the inside with a silicone coating. This extremely smooth surface reduces the adhesion of the blood and prevents platelet aggregation. In the blood vessel system, the smoothness is produced by the endothelium. The silicone coating comes very close to the endothelial surface of the vascular system in terms of smoothness. Laminar boundary layers have a significantly lower wall friction compared to turbulent boundary layers. This is achieved by the silicone coating.

By the interaction of the described features of the bloodletting needle / tube system 10 according to the invention a laminar flow is achieved in which the value of the Reynolds number Re = w * d / v is well below 2320, which is the critical value 4/9 Austrian Patent Office AT512 226B1 2013-09-15 in a turbulent flow in a pipeline with a circular cross-section. This is achieved in particular by (1) the smooth surface coating, (2) favorable choice of the length and diameter ratios, (3) absence of internal adapter resistors, and (4) design of the outflow opening with an acute angle.

In conventional needles, turbulence occurs in the flow of blood flowing through the needle. Here, as already mentioned, the diameter of importance. If the needle is too thin, there will be accumulation of turbulence in front of the end of the needle. a thicker needle causes turbulence in the canal of the needle.

In too thick hoses, but also in too thin hoses, turbulence occur. For the medium blood, a ratio of diameter to length of the tube could be determined by experiments in which blood flows in laminar flow. The length S of the tube is e.g. 975 mm, its diameter is 3 mm (inside) or 4.1 mm (outside). The length of the tube is chosen in view of the diastolic pressure in the bloodstream of the patient, namely such that the hydrostatic pressure of the blood column is below the diastolic pressure. In this case, the length can vary to some extent, namely by a few millimeters, for example ± 10 mm. The inner diameter is chosen so that thick blood can flow well through the tube.

The aforementioned absence of internal adapter resistors is achieved in that the adapter transitions are not mounted against the direction of flow, but only - seen in the flow direction - continue to represent transitions. This is shown in FIG. 7. The flow direction of the flow is indicated by an arrow. The step-like transition is associated with an increase in the diameter. For example, the subsequent pipe part is slipped on the outside of the approach with a smaller diameter. In this way flow obstacles fall away, which would otherwise lead to turbulence

OUTFLOW OPENING WITH TIP ANGLE

By the outflow opening, the speed of the blood flow is controlled; In addition, a reduction of the expansion pressure of the exiting blood is possible.

The venous blood typically has a pressure of 60 to 85 mmHg upon exiting the venous system. In addition, when passing through the hose system, the kinetic energy is added by the drop height of the discharged blood, the drop height being determined by the length of the hose, thus approximately 975 mm when the hose is vertical. The flow rate of a laminar flow of a viscous liquid is determined by the known law of Hagen-Poiseuille; Accordingly, the flow rate depends inter alia on the pressure difference between the beginning and end of the tube and the viscosity of the liquid. The length of the tubing and the pointed-angle orifice of the blood-drain needle / tube system can absorb the expansion pressure that would result in turbulent flow.

On the basis of examinations carried out on 920 blood vessels with straight and pointed-angle outflow openings, clear results were obtained: at an angle a3 = 23 ° (see Figure 9) of the outflow opening results in a laminar blood outflow, the fractal and shift assessment by means of the vital diagnosis of Veined blood allows. Different geometries, e.g. when the outlet opening is straight (a = 90 °) leads to turbulence, with turbulently mixed blood makes a vital diagnosis using the vein bleeding impossible. The laminar flow of the blood is achieved by the interaction of the needle and tube design features described herein.

Consequently, for physicians who use the Hildegard bloodletting after Dr. med. Ewald Töth perform, the bloodletting laminar needle / tube system according to the invention an absolutely indispensable equipment. 5.9

Claims (8)

Aderlassnadel (1), comprising a first and a second end and a needle channel (6) in the form of a running between the two ends along the longitudinal axis of the needle cavity (6), the opening at each end of the needle in each case an opening, wherein the first end (2) of the needle is chamfered and the skew (3) thus formed forms a needle tip (4), wherein the needle channel (6) has a variable diameter, which between the two openings undergo a minimum value (d2), characterized by a remanent magnetization, which is aligned substantially in the longitudinal direction of the needle, has a maximum in a central region of the needle and decreases toward the two ends. 2. Aderlassnadel according to claim 1, characterized in that the cavity (6) has an inner coating (8,14) with a smooth surface. 3. Aderlassnadel according to claim 2, characterized in that the inner coating (8, 14) preferably consists of a silicone-based plastic and having a variable thickness, which passes through a maximum value between the two openings, and the variable diameter of the needle channel through the variable Thickness of the inner coating is conditional. 4. Aderlassnadel according to any one of the preceding claims, characterized in that the bevel (3) of the first end has a foremost segment (31) which extends at a first angle (c ^) less than 90 ° to the longitudinal axis, and then the bevel at a shallower angle to the longitudinal axis than the first angle. 5. Aderlassnadel according to claim 4, characterized in that the skew, apart from the foremost segment (31), a rear segment (32) with a constant second angle (a2), wherein the second angle is smaller than the first angle. 6. Aderlassnadel according to claim 4 or 5, characterized in that the first angle (ai) is in a range between 20 ° and 45 °, preferably from 30 ° to 35 °. 7. Aderlass system, comprising a bloodletting needle (1) according to one of the preceding claims and a hose (9) connectable thereto. 8. Aderlass system according to claim 7, wherein the hose (9) at the end opposite the needle has an outlet opening (13), wherein the outlet opening is chamfered, preferably at an angle a3 = 23 °. 3 sheets of drawings 6/9