RU2636222C1 - Bio-solder for laser welding of biological tissues - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: bio-solder contains an aqueous dispersion basis of albumin protein. At that, single-walled carbon nanotubes and a medical dye indocyanine green are introduced into its composition with the following component ratio, wt %: albumin 20-25, single-walled carbon nanotubes 0.02÷0.05, indocyanine green 0.01, distilled water - the rest.EFFECT: reduced injuries and seam sealing, in particular, when welding small blood vessels and canals, soft tissues.1 tbl, 1 dwg

Description

The invention relates to the field of laser technology used for nanotechnological purposes, and in particular to methods of combining biological tissues under the influence of laser radiation.

Laser welding provides several advantages over traditional methods of joining biological tissues (using surgical suture materials, such as needles and threads). In particular, the tightness and sterility of the wound, vascular anastomosis, almost imperceptible scars at the joints, quick connection of tissues, etc. [one].

Biological solder (bio-solder), which is used in laser welding, mainly consists of biological material in a liquid state, for example, an aqueous dispersion of albumin [2]. After completion of the laser welding process, the liquid form of bio-solder hardens and a strong seam is formed at the junction of biological tissues.

Existing laser bio-solders do not provide the proper durability of the laser seam. For example, it is known that bio-solder for laser welding based on an aqueous dispersion of albumin makes it possible to realize a tensile strength of the laser seam of ~ 0.05 kPa (pig skin) [3], or ~ 0.43 kPa (dog intestine) [4]. Such strength is unsatisfactory, since it is several orders of magnitude inferior to the strength of sutures obtained by surgical methods [5].

It is known that bio-solder based on nanomaterial, which contains albumin and carbon nanotubes, significantly increases the strength of the laser weld [6, 5, 6]. In the study of such bio-solders on cartilage and skin tissue, the values of their tensile strength of the seam amounted to 25-30% relative to the strength of continuous tissue in vitro. The achieved limit values are inferior to the values of the strength of the seam obtained with traditional methods of stitching [5].

Closest to the proposed invention is bio-solder used in the method of laser welding of biological tissues, characterized in that it contains various proteins acting as a binder, as well as fillers, such as surfactants and multi-walled carbon nanotubes [7] (prototype) . Laser welding using the proposed bio-solder requires a high radiation power (tens of watts), in addition, the welding process takes several minutes.

The objective of the invention is to obtain a high-strength seam when connecting biological tissues.

The specified technical problem is solved by the fact that monolayer carbon nanotubes and the medical dye Indocyanin green are introduced into the bio-solder based on an aqueous solution of albumin protein in the following ratio of components, wt.%: Albumin 20-25, single-layer carbon nanotubes 0.02 ÷ 0.05, green indocyanin 0.01, distilled water - the rest.

The essence of the invention lies in the fact that during laser welding from a bio-solder, the liquid component of the dispersion evaporates and hardens, and single-walled carbon nanotubes (SWCNTs) are structured in a certain way, and thus a durable seam is formed at the junction of tissues. Moreover, SWCNTs have an advantage with respect to multilayer carbon nanotubes (MWCNTs). For example, with a high level of dispersion of nanotubes and their identical mass percentage in the matrix of bio-solder based on SWCNTs, a higher quantitative concentration of nanotubes in the volume of the matrix is realized than in bio-solder based on MWNTs. Consequently, the creation of a dense skeleton in the solder based on SWCNTs is more likely than in the solder based on MWNTs. The medical dye Indocyanin Green (ICG) has a pronounced absorption maximum in the region of 800 nm, which coincides with the wavelength of laser radiation generation (810 nm). Therefore, this dye serves as a strong absorber of laser radiation in bio-solder, in addition, the radiation energy is effectively absorbed by carbon nanotubes. The regions where the nanotubes touch each other overheat the nanotubes and weld them together. As a result, a strong frame of carbon nanotubes is formed in the matrix of albumin, which allows a strong weld.

The practical applicability of the proposed method is illustrated by the following steps of manufacturing an aqueous dispersion of bio-solder:

1. SWCNTs are added to distilled water in an amount of 0.02-0.1 wt.%, After which the resulting dispersion is stirred in a magnetic stirrer for 30 min, and then dispersed in an ultrasonic disperser at a temperature of ≤30 ° С for 30 min. obtaining a homogeneous dispersion of black.

2. Bovine serum albumin (BSA) powder is introduced into the aqueous dispersion of SWCNTs at a concentration of 20-25 wt.% And then the dispersion is placed in an ultrasonic bath and dispersed at a temperature of ≤40 ° C for 60 min until a homogeneous dispersion of BSA / SWCNTs in black is obtained .

3. 0.01 wt.% ICC is added to the BSA / SWCNT aqueous dispersion, the dispersion is dispersed in an ultrasonic bath at a temperature of ≤40 ° C for 60 minutes.

4. The aqueous BSA / SWCNT / ICZ dispersion is decontaminated within 24 hours, filtered and poured into another vessel.

5. The dispersion of BSA / SWCNTs / ICZ is a bio-solder and is used in laser welding.

6. A bio-solder is applied with a thin layer to the surfaces to be joined and brought as close to each other as possible (“under the face”) so that there is practically no gap in the area of the proposed joint. A laser beam with a diameter of ~ 0.8-1.0 mm passes at a speed of 2-5 mm / s along the surface of the proposed weld with applied solder. Depending on the composition of the tissues being welded, the laser operation mode (diode laser with fiber optic output) is selected: specific radiation power 0.02-0.1 MW / m ² , lasing wavelength 810 nm, lasing mode - continuous, pulsed. Empirical selection of the laser mode allows you to implement the desired mechanical parameters of the weld.

Table 1 shows the results of measurement (in vitro) of the tensile strength of the laser suture for some types of tissue (pig skin and bovine cartilage). The values of σ _m and σ show the tensile strength of a continuous fabric and a laser seam, respectively. These values were measured with an AIGUZP-500N dynamometer with a resolution of 0.1 N, taking into account the size of biological tissues. Samples of biological tissues were shaped into strips with dimensions: length 25-30 mm, width 5-8 mm, thickness 1-2 mm.

In FIG. 1 shows a typical pattern of a laser seam obtained by a scanning electron microscope. Carbon nanotubes are visible, which are entangled or rolled into bundles and distributed almost uniformly in the bulk of the matrix. They create a skeleton-like structure in the albumin matrix. Since carbon nanotubes have high mechanical parameters, for example, high tensile strength, therefore, the framework created by them is also strong. The creation of a strong framework is facilitated by the addition of an ICC, since this dye provides strong absorption of laser radiation with bio-solder, overheating of carbon nanotubes and welding them together. In general, the laser seam obtained using laser bio-solder as part of BSA / SWCNT / ICZ acquires high strength.

Thus, the skeleton-like structure of SWCNTs in the bio-solder matrix during laser welding provides high mechanical strength of the weld, i.e. high bond strength of biological tissues.

Important advantages of bio-solder made by the proposed method, relative to the known materials and prototype are [3, 4, 6, 7]:

- its matrix consists of biological material (albumin protein) and of fillers in the form of single-walled carbon nanotubes and the medical dye Indocyanin green, and in general the nanomaterial is biocompatible;

- its composition is 25 wt.% BSA / 0.05 wt.% SWCNT / 0.01 wt. % ICC during laser welding allows you to realize a seam, the strength of which reaches up to 40% relative to the strength of the connected cartilage tissue;

- low content of SWCNTs emphasizes a high degree of safety and biocompatibility of the material;

- in its composition the content of SWCNTs is reduced, and the strength of the laser seam is significantly increased (see table. 1);

- the specific power (~ 0.02-0.1 MW / m ² ) of laser radiation to obtain a laser seam is reduced several times;

- the speed of laser welding is increased several times (~ 2-5 mm / s),

- the diameter of the spot of the laser beam at the seam 0.6-0.8 mm

The advantage of bio-solder for laser welding obtained by the proposed method is its high efficiency, achieved due to the high tensile strength of the laser seam, the low content of carbon nanotubes, the low energy load of the laser radiation on the fabric to be welded, and the high speed of the welding process.

The proposed bio-primer is promising for use both in traditional surgical procedures and in complex cases where it is important to reduce injuries and seal the seam, in particular when welding small blood vessels and channels, soft tissues: liver, lungs, etc.

Thus, a technical solution to the problem posed in the present invention. A method for the preparation of bio-solder for laser welding based on the biological material of albumin and a filler from single-walled carbon nanotubes and the medical dye Indocyanine green is proposed. Bio-solder, which is a nanomaterial, is biocompatible.

Information sources

1. Sawyer P.N. Method for welding biological tissue. - US Patent No. 5,824,015.

2. Forer B., Vasilyev T., Brosh T., et al. Lasers in Surgery and Medicine, 9999, 1 (2005).

3. Simhon D., Halpern M., Brosh T., and et al. Annals of surgery, 245 (2), 206-213 (2007).

4. Bleustein C. B., Felsen D., Poppas D. P. Lasers in Surgery and Medicine, 27 (2), 82-86 (2000).

5. Hench L., Jones D. Biomaterials, artificial organs, and tissue engineering. M .: Technosphere. 2007 .-- 304 s.

6. Gerasimenko A.Yu., Ichkitidze L. P., Podgaetsky V. M., Ponomareva O. V., Selishchev S. V. / Nanocomposite solder for laser welding of biological tissues // University proceedings. Electronics. 2010. No4. S. 33-41.

7. Patent RU No. 2425700.

Claims (1)

Bio-solder containing an aqueous dispersion base of albumin protein, characterized in that monolayer carbon nanotubes and a medical dye Indocyanine green are introduced into the composition in the following ratio of components, wt.%: Albumin 20-25, single-layer carbon nanotubes 0.02 ÷ 0.05, indocyanine green 0.01, distilled water - the rest.

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