RU2652083C2 - Method of preparing skin graft for free autodermoplastics - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates medicine, namely to general surgery, aesthetic surgery and traumatology. Performed are two parallel incisions of the skin and the subcutaneous tissue in the donor area to a depth down to the surface fascia. Mobilized is a skin flap under the microcirculation control to reduce the microcirculation rate by 40–50 %. Applied onto the incisions are intradermal cosmetic sutures after forming the hypoxia region. Skin graft is sampled 12–24 hours later from the skin area between the incisions and a free dermoplastics is performed, herewith the length of the incisions should be twice of the distance between the incisions.

EFFECT: method allows to create a repository of cytokines, primarily hypoxia-inducible factor (HIF-1α) the flap being transplanted, to improve the graft engraftment by adapting the graft to the conditions of engraftment in the recipient zone with compromised microcirculation.

1 cl, 2 ex

Description

The invention relates to medicine, namely to general surgery, aesthetic surgery, traumatology, and can be used in the preparation of the donor site necessary for taking a split skin graft for free autodermoplasty.

A particular problem of surgery is wound defects that have occurred in patients with a compromised microvasculature, for example, in patients with diabetes mellitus. Their feature is a long, stubborn course, the cause of which is damage to the blood vessels, in particular microangiopathy. The pathogenesis of diabetic microangiopathy is multicomponent: hyperglycemia disrupts the exchange of mucopolysaccharides and induces the accumulation of low-density glycoproteins and lipoproteins in the basement membrane of arterioles, which thickens and prevents diffusion of oxygen into the tissue, and the binding of excess glucose to hemoglobin, the formation of sorbitol, and the formation of lipid peroxidation edema and tissue hypoxia (1). A significant pathogenetic factor in wound healing in diabetes mellitus is a decrease against the background of hypoxia of angiogenesis and cell proliferation (2).

The closure of soft tissue defects in patients with diabetic foot syndrome is performed in various ways, while free skin grafting is one of the most common. However, the method has a known drawback: when it is used in patients with diabetes mellitus, that is, in conditions of recipient zone tissue blood supply compromised at the microcirculatory level, flap necrosis is highly likely against tissue hypoxia (3).

A known method of skin plastics, protected and.with. USSR No. 1000023, cl. A61B 17/00, publ. 02/28/83, When implementing the method of skin grafting with a free transversely split dermal flap, the flap is transversely split on both sides in the form of a corrugated plate and stretch it. The disadvantage of this method is the complexity of wound healing in diabetes mellitus (2).

A known method of training a skin flap for hypoxia before local plastic surgery (4) by phased formation of a flap, the so-called delay method. In the first operation, a skin flap is cut with parallel incisions along its edges, deepening to the fascia. After stopping the bleeding, an intradermal suture is applied. In the second operation, after 7-10 days, the intradermal suture is removed, the skin area between the sutures is separated to the fascia, after which the intradermal suture is again applied. After another 7-10 days, an incision is made at the end of the flap, after which non-free skin grafting is performed to prepare a flap thus prepared for hypoxia. The meaning of operations is to stimulate the growth of blood vessels against the background of a decrease in blood supply to a closed skin flap. A disadvantage of the known method is also the complexity of wound healing in diabetes mellitus (5).

Closest to the claimed solution to this problem is the "Method of preparing donor sites when performing skin plastics" (6). The method includes the introduction of a plasma-replacing solution into the subcutaneous tissue of the donor site, in which an ozonized physiological solution with an ozone content of 160-200 μg is injected into the donor site zone, the introduction being carried out 10-15 minutes before cutting the grafts in a volume of 150-200 ml.

The disadvantages of this method include the following. It is known that the half-life of ozone in saline is 30 minutes (7), the introduction of an ozonized solution to prevent ischemic necrosis is effective for 3-4 hours, after which the solution loses its ability to give oxygen to tissues. A skin flap under hyperoxia goes into a hypoxic state, which is serious stress and may itself cause necrobiotic changes. Therefore, the known method of preparing a skin flap for transplantation under conditions of compromised microcirculation is not able to provide adequate healing of the skin wound.

The objective of the proposed method is the ability to plasticize soft tissue defects with a split skin flap in patients with pathology of the microvasculature by stimulating the production of their own cytokines in the near-wound region, in particular, a specific oxygen-sensitive protein complex - hypoxia-inducible factor (HIF-1α), in order to train the donor zone to hypoxia conditions.

The technical result of the claimed invention is to improve the graft engraftment by adapting the graft to the engraftment conditions in the recipient zone with compromised microcirculation.

The specified technical result is achieved by the fact that the method of preparing a transplant for free autodermoplasty involves performing two parallel incisions of the skin and subcutaneous tissue in the donor area to a depth of the superficial fascia, mobilizing the skin flap under the control of microcirculation to reduce the microcirculation rate by 40-50%, applying to the incisions intradermal cosmetic sutures after the formation of the area of hypoxia, graft collection after 12-24 hours from the area of the skin between the incisions and free skin second plastics, wherein the length of the cuts should be equal to twice the distance between the slits

In the proposed method, after training, free skin grafting is performed with a split flap, there are only two steps — closing the flap and taking the graft, the period between operations is reduced to 12-24 hours, since the task is not to create a network of newly formed vessels, but to create a depot of cytokines, in the first the turn of hypoxia inducible factor (HIF-1α). The length of the incisions should be no more than twice the distance between them, since with a larger length of the incisions, the skin flap may be in critical ischemia.

The method is as follows. In the donor area (usually the anterior-lateral surface of the thigh), two parallel cuts of the skin and subcutaneous tissue to the superficial fascia are performed so that the distance between the cuts was at least 5 cm and the length of the cuts exceeded the distance between them by 2 times. Microcirculation is controlled (for example, using laser Doppler flowmetry - LDF) or the partial oxygen tension in tissues (for example, using a TCM-400 monitor from Radiometer (Denmark) or an analogue), if necessary, mobilizing a skin flap so that according to LDF to achieve a reduction in microcirculation to a level of 40-50% of the original. A decrease in the values of the microcirculation index to the level of 40-50% of the initial one leads to compensated hypoxia. At less than 40% of the initial value of the microcirculation index, pronounced stimulation of proliferative activity does not occur; at more than 50%, the risk of developing critical ischemia with the formation of necrosis is high. After the formation of the area of hypoxia, intradermal cosmetic sutures are applied to the incisions. After 12-24 hours, the graft is taken from the area between the incisions and free skin grafting is performed. With a time period of less than 12 hours, a depot of cytokines affecting proliferative activity does not have enough time to form in the tissues, with a longer period of time than 24 hours, compensatory processes in the body, in particular the development of collateral blood flow, lead to restoration of blood supply to the donor site.

As a result of the application of this method in tissues located between two parallel sections, microcirculation and circulatory compensated hypoxia occur. Under conditions of compensated hypoxia, cytokines accumulate, first of all, HIF-1α. Adaptation to hypoxia is a complex of regulatory-compensatory mechanisms, which allows urgent or delayed reduction of the effect of impaired oxygen consumption. Training for hypoxia or the so-called hypoxic preconditioning allows tissues to withstand oxygen deficiency much more effectively (8). Hypoxic preconditioning is a preventive measure and consists in a short-term non-damaging hypoxic or ischemic effect, leading to pronounced resistance to a more severe level of ischemia. It is known that under conditions of ischemia in tissues, the adaptation process is controlled primarily by a specific oxygen-sensitive protein HIF-1α, recent studies have confirmed its role in wound healing, in particular, diabetic ones (9, 10). This factor, accumulating in tissues under hypoxic conditions, is responsible for the expression of proteins that control the delivery of oxygen to the cell. HIF-1 inhibits oxidative stress and the action of inflammatory factors and affects the survival rate of a skin flap in rats (11). Hypoxia-induced factor (HIF-1) is a key transcriptional regulator for several angiogenesis factors, in particular, the induction of HIF-1α induces the expression of target genes, including vascular endothelial growth factor (VEGF) (12-14). Tissue hypoxia is of great importance in wound healing, since it usually plays a key role in the regulation of all processes involved in tissue repair, and hypoxia-induced factor (HIF-1 alpha) is a critical transcription factor that regulates adaptive responses to hypoxia. HIF-1 tissue accumulation is necessary and sufficient to stimulate wound healing in a diabetic environment (15).

Clinical example 1.

Patient M., born in 1942, was admitted to the purulent surgery department of GBUZ NO “City Clinical Hospital No. 30” on December 25, 15, with a diagnosis of type 2 diabetes mellitus, insulin-dependent. Diabetic foot syndrome, neuroischemic form, Wagner 2, diabetic microangiopathy. Condition after amputation of the fourth toe of the right foot in August 2015. Condition after endovascular balloon angioplasty of the femoral-popliteal-tibial segment with stenting on the right in December 2015. Long-term non-healing wound of the right foot. Coronary heart disease, atherosclerotic cardiosclerosis, post-infarction cardiosclerosis (myocardial infarction in 2014), atrial fibrillation, heart failure 2a art., Hypertension 3 art., 2 art., Risk of cardiovascular complications 4. Chronic gastroduodenitis, gastric polyposis. Cerebrovascular disease. Dyscirculatory encephalopathy 2 tbsp. Condition after acute cerebrovascular accident (2012).

Complaints: the presence of a non-healing wound in the right foot.

Locally: skin of both lower limbs is flesh-colored, no edema. Both lower limbs are warm to the touch. Auscultation in the projection of the great vessels, the sounds are heard. Active and passive movements in the ankle joints in full, painless. Palpation of the muscles of both legs is painless. Pulsation of the main arteries is determined on both lower extremities at all levels. A wound of the dorsum of the right foot of a trapezoidal shape, 5 × 2.5 cm in size (after amputation of the fourth finger), up to 0.2 cm deep, the bottom of the wound is represented by light yellow fibrin, necrotic tissues, and from the wound there is a sparse serous-purulent discharge.

The general state of moderate severity is due to the underlying and concomitant diseases of the patient. The results of sowing the wound discharge of the right foot - S. epidermidis, sensitive to cephalosporins, fluoroquinolones. Conducted: antibiotic therapy (ceftriaxone), vasotropic antiplatelet therapy, antioxidant therapy, insulin therapy, local treatment - mechanical cleansing of the wound from fibrin, necrotic tissue, dressings with an aqueous 0.05% chlorhexidine solution.

The first stage of skin plastic surgery was performed on January 5, 2016 under the control of a laser analyzer of capillary blood flow (LAKK-02), the value of the microcirculation index in the donor region is 4.4 pF. units The skin flap was closed on the front-outer surface of the right thigh with two parallel cuts of the skin and subcutaneous tissue to the superficial fascia so that the distance between the cuts was 5 cm and the length of the cuts was 10 cm. The skin flap was mobilized under the control of microcirculation, a decrease in the microcirculation index was observed to the level of 2.2 pf. Food (50% of the original). After that, an intradermal cosmetic suture was applied to the incisions. After 24 hours, 01/06/16, free skin plastic surgery was performed with a perforated dermatome flap 0.3 mm thick, the flap was taken from the area between the incisions. On the 6th day, a change in the bandage of the right foot - engraftment of the flap on 95% of the wound area.

Clinical example 2.

Patient V., born in 1940, was admitted to the purulent surgery department of GBUZ NO “City Clinical Hospital No. 30” on December 25, 15, with a diagnosis of type 2 diabetes mellitus, insulin-dependent. Diabetic foot syndrome, neuroischemic form, Wagner 2, diabetic microangiopathy. Condition after endovascular balloon angioplasty of the femoral-popliteal-tibial segment with stenting on the right in October 2015. Long-term non-healing wound of the rear foot of the right foot. Coronary heart disease, atherosclerotic cardiosclerosis, CHF 2a art., Hypertension 3 art., 2 art., The risk of cardiovascular complications 4.

Complaints: for the presence of a non-healing wound in the rear of the right foot.

Locally: skin integument of both lower limbs of flesh-colored, moderate swelling of the rear of the right foot. Palpation of the muscles of both legs is painless. Pulsation of the main arteries is determined on both lower extremities at all levels. The wound of the dorsum of the right foot in the form of an irregular quadrangle, 6 × 3 cm in size, up to 0.2 cm deep, the bottom of the wound is represented by fibrin of light yellow color, necrotic tissues, and from the wound is a poor serous-purulent discharge. The sowing results of the wound discharge of the right foot - Klebsiella pneumoniae, sensitive to fluoroquinolones. Conducted: antibiotic therapy (Ciprofloxacin), vasotropic antiplatelet therapy, antioxidant therapy, insulin therapy, local treatment - mechanical cleansing of the wound from fibrin, necrotic tissue, dressings with an aqueous 0.05% chlorhexidine solution.

The first stage of skin grafting was performed on December 25, 2015 under the control of a laser analyzer of capillary blood flow (LAKK-02), the value of the microcirculation index in the donor region is 5.2 pF. units The skin flap was closed on the front-outer surface of the right thigh with two parallel cuts of the skin and subcutaneous tissue to the superficial fascia so that the distance between the cuts was 5 cm and the length of the cuts was 10 cm. The skin flap was mobilized under the control of microcirculation to the level of microcirculation 2.1 pf. units (40% of the initial), after which an intradermal cosmetic suture was applied to the incisions. After 12 hours, free skin grafting was performed with a perforated dermatome flap 0.3 mm thick, the flap was taken from the area between the incisions. On the 6th day, a change in the bandage of the right foot - engraftment of the flap on 94% of the area of the wound.

The analysis of patent and medical literature has shown that the proposed method contains features that distinguish it not only from the prototype, but also from other options for preparing a skin flap for free plastic. These differences allow us to conclude that the claimed technical solution meets the criteria of the invention of "novelty."

A comparative analysis of the proposed method and prototype shows that the claimed method differs from the known one in that for the preparation of a graft for free autodermoplasty in patients with compromised microcirculation, the drug is not administered locally and for a short time acting on the processes of reparative regeneration, but it induces the formation of endogenous cytokines that increase tissue viability, by creating local circulatory tissue hypoxia.

The inventive method provides an improvement in the graft engraftment by adapting the graft to the engraftment conditions in the recipient area with compromised microcirculation.

The method comprising the claimed invention is intended for use in healthcare. This method can be used in surgery and traumatology. The possibility of its implementation is confirmed by the available techniques and means described in the application, therefore, the proposed technical solution meets the criteria of the invention "industrial applicability".

Sources of infotermation

1. J. Kasznicki et al. Evaluation of oxidative stress markers in pathogenesis of diabetic neuropathy. Mol Biol Rep. 2012 Sep; 39 (9): 8669-8678.

2. Gao W, Ferguson G, Connell P, Walshe T, Murphy R, Birney YA, O’Brien C, Cahill PA. High glucose concentration alter hypoxia-induced control of vascular smooth muscle cell growth via a HIF-1 alpha-dependent pathway. J Mol Cell Cardiol. 2007 Mar; 42 (3): 609-19.

3. Bensman B.M .: Surgery of purulent-necrotic complications of the diabetic foot. M .: Publishing house MEDPRAKTIKA-M, 496 p.

4. Zoltan J. Skin transplantation / Zoltan J. - Budapest: Publishing House of the Hungarian Academy of Sciences, 1984. - 304 p.

5. Izmailov S. G., Izmailov G. A., Vidmanov G. I. Evaluation of the effectiveness of treatment of non-healing wounds and trophic ulcers of the lower extremities // Surgery. - 2003. - No. 2. - S. 44.

6. Aminev V.A., Dokukina L.N., Peretyagin S.P. A method of preparing donor sites when performing skin plastics. RF patent for the invention No. 2392885.

7. Physiotherapy: national leadership / Ed. G.N. Ponomarenko. - M.: GEOTAR-Media, 2009 .-- S. 252.

8. Lukyanova L.D., Germanova E.L., Kopaladze R.A. ukyanova L.D., Germanova E.L., Kopaladze R.A. Development of resistance of an organism under various conditions of hypoxic preconditioning: role of the hypoxic period and reoxygenation. Bull. Exp.Biol. Med. 2009; 147: 4: 400-404.

9. Ke Q, Costa M. Hypoxia-inducible factor-1 (HIF-1). Mol Pharmacol. 2006 Nov; 70 (5): 1469-80.

10. Yu DH, Mace KA, Hansen SL, Boudreau N, Young DM. Effects of decreased insulinlike growth factor-1 stimulation on hypoxia inducible factor 1-alpha protein synthesis and function during cutaneous repair in diabetic mice. Wound Repair Regen. 2007 Sep-Oct; 15 (5): 628-35.

11. Duscher D. Fibroblast-Specific Deletion of Hypoxia Inducible Factor-1 Critically Impairs Murine Cutaneous Neovascularization and Wound Healing. Plast Reconstr Surg. 2015 Nov; 136 (5): 1004-13.

12. Chen GJ, Chen YH, Yang XQ, Li ZJ. Nano-microcapsule basic fibroblast growth factor combined with hypoxia-inducible factor-1 improves random skin flap survival in rats. Mol Med Rep. 2015 Dec 21. doi: 10.3892 / mmr.2015.4699. [Epub ahead of print].

13. Leung KW, Ng HM, Tang MK, Wong CC, Wong RN, Wong AS. Ginsenoside-Rgl mediates a hypoxia-independent upregulation of hypoxia-inducible factor-1α to promote angiogenesis. Angiogenesis. 2011 Dec; 14 (4): 515-22.

14. Ahluwalia Al, Tarnawski AS. Critical role of hypoxia sensor-HIF-1α in VEGF gene activation. Implications for angiogenesis and tissue injury healing. Curr Med Chem. 2012; 19 (1): 90-7.

J, Lindberg S, Pereira T,

S, Poellinger L, Brismar K, Catrina SB. Stabilization of HIF-1 alpha is critical to improve wound healing in diabetic mice. Proc Natl Acad Sci USA. 2008 Dec 9; 105(49): 19426-31.15. Botusan IR, Sunkari VG, Savu O, Catrina AI,

J, Lindberg S, Pereira T,

S, Poellinger L, Brismar K, Catrina SB. Stabilization of HIF-1 alpha is critical to improve wound healing in diabetic mice. Proc Natl Acad Sci USA. 2008 Dec 9; 105 (49): 19426-31.

Claims (1)

A method of preparing a graft for free autodermoplasty, including performing two parallel incisions of the skin and subcutaneous tissue in the donor area to a depth of the superficial fascia, mobilizing the skin flap under microcirculation control to reduce the microcirculation rate by 40-50%, applying intradermal cosmetic sutures after the formation of the region hypoxia, graft collection after 12-24 hours from the area of the skin between the incisions and the implementation of free skin grafting, while the length of the incisions should be twice the distance between cuts.