RU2268693C2 - Method for manufacture of medicinal plaster bandage - Google Patents

Abstract

FIELD: medicine, in particular, manufacture of plaster bandages used in traumatology and orthopedics.

SUBSTANCE: method involves applying ground hemihydrate plaster to base and fixing said plaster thereon; using multilayer base; preliminarily applying ground hemihydrate plaster onto each layer of said base; applying layers onto each other and fixing plaster on base; rolling base and placing resultant base roll into plaster fixing enclosure and further into tight package, which fixes shape of article.

EFFECT: provision for producing of high-quality and high-strength article convenient in use.

Description

The invention relates to medicine, namely to the manufacture of medical gypsum dressings used in traumatology and orthopedics.

Of all the known methods for the manufacture of such dressings, the closest to the proposed one is the method of rubbing gypsum or gypsum powder into the surface of the gauze manually or mechanically (Bam G.Yu., Chernavsky VA "Plaster dressings in orthopedics and traumatology." M .: Medicine, 1966, 135 pp.).

The disadvantage of this method is the unsatisfactory quality of dressings (hereinafter bandages) due to the deficiency of gypsum on the surface of the gauze, resulting from shedding of dry gypsum during storage and leaching of gypsum with water during the soaking of the bandage.

All other methods of manufacturing gypsum bandages are aimed mainly at eliminating these two drawbacks - shedding and leaching of gypsum, since its amount located on the surface of gauze soaked and prepared for application of the bandage is, other things being equal, the main factor of strength and, accordingly quality bandage.

For this purpose, liquid adhesive components are used in the form of aqueous and even aqueous-alcoholic solutions of cellulose ethers and the like, which, in turn, in addition to the high cost of the components themselves, requires additional costs for drying the gypsum slurry, and therefore becomes very complicated and the production cycle becomes more expensive.

Meanwhile, it is possible to eliminate the crumbling of dry gypsum during storage of the bandage by preliminary tight mutual compression of the gypsum and gauze and subsequent careful preservation of the immobility of all layers of the bandage folded into a roll and placed in a tight-fitting form of high strength. Such a shape, for example, may be shrink wrap.

Before application, the bandage is soaked mainly in a rolled state by immersing the whole roll in water, which reduces the time of application of the bandage and ensures the convenience of the medical staff.

Hence, the preliminary placement of the roll in a filtering gypsum-free membrane prevents the gypsum from being washed out into the water, and the possibility of free flow of excess water without squeezing eliminates the accidental rupture of the filtering membrane and uncontrolled loss of gypsum in this case.

The strength of the bandage necessary for guaranteed fixation of the connected parts of bone and other tissue is achieved in medical practice by applying 8-12 layers of the bandage, since its normalized thickness is only 0.8 mm.

Under the conditions of minimum requirements for tissue fixation, such a number of applied layers is at least not justified and may well be replaced by the application of all, for example, 3-4 layers of a 3-layer bandage, the thickness of which, in this case, will be only 2.4-2.5 mm. Such a bandage is guaranteed to have the same plastic properties as a single-layer one and will provide a tight fit to all irregularities - protrusions and depressions - of the fixed surface of the fabric, and the number of operations and the application time of the bandage is reduced by at least three times. In addition, the three-layer bandage itself during the operations of applying it provides almost complete mutual immobility between the three adjacent layers of the bandage, and therefore eliminates the loss of gypsum at this stage.

Laboratory studies of the operations of the proposed method showed its full applicability and the possibility of serial production on industrial equipment of high-quality, and most importantly, high-strength products.

On each of the three pieces of gauze, 1 m long and 14 cm wide, 90 g of semi-aquatic gypsum were manually applied with the required indicators of grinding fineness, setting start and end time. Then the pieces laid on top of each other were placed on a hard, even surface, covered with a layer of the same gypsum 4-5 mm thick, and then with a hand roll with a load of 15 kg suspended on it (i.e. <1.0 kg per 1 cm of rolled bandage width) a three-layer bandage was already rolled once, after which the bandage was wound into a roll with a diameter of ≈50 mm. The latter with the maximum fit to its cylindrical and straight surfaces in paper for packaging tea so that when soaked to exclude the possibility of opening the package (for example, wrap several times with threads). A roll prepared in this way was sealed in a shrink film with a maximum shrink force, i.e. compression.

After short-term (for several days) storage, the film cover was removed, the bandage in an intact paper shell was immersed in room temperature water for a period of reliable soaking - up to 50 s and without subsequent crimping of excess water it was hung on a wall rod at a position of ≈30-45 ° to the horizontal , where it was kept for another 15-30 s for free flow of excess water. After removing the paper shell, all the gypsum, with the exception of the part on its outer layer (and the entire surface of this layer is 0.04 of the working surface of the bandage), remains on the gauze in the form of a bandage, ready to be applied simultaneously in three layers. In this case, the absence of the influence of any components on the setting time and strength of gypsum makes it possible to have them with the maximum specified accuracy.

Claims (1)

A method of manufacturing a medical gypsum dressing, including applying to the base of ground semi-aquatic gypsum and fixing it on the base, characterized in that they use a multilayer base, each layer of which is pre-ground with semi-aquatic gypsum, the layers are laid on top of each other, and then the gypsum is fixed on the base, the base is rolled up, placed in a filtering gypsum sheath, and then in a tight package, fixing the shape of the product.