US3036341A

US3036341A - Centrifugal casting of collagen to produce films and ribbons

Info

Publication number: US3036341A
Application number: US704730A
Authority: US
Inventors: Taylor Arthur Sinclair
Original assignee: American Cyanamid Co
Current assignee: Wyeth Holdings LLC
Priority date: 1957-12-23
Filing date: 1957-12-23
Publication date: 1962-05-29
Anticipated expiration: 1979-05-29

Description

A. S. TAYLOR CENTRIFUGAL CASTING OF COLLAGEN TO PRODUCE FILMS AND RIBBONS May 29, 1962 2 Sheets-Sheet 1 Filed Dec. 23, 1957 INVENTOR. ARTHUR SINOLAAIR TAYLOR BY FIG.5

ATTORNEY y 1962 A. s. TAYLOR 3,036,341

CENTRIFUGAL CASTING OF COLLAGEN TO PRODUCE FILMS AND RIBBONS Filed Dec. 23, 1957 2 Sheets-Sheet 2 LIQUIFIED COLLAGEN HOT WAX COLLAGEN FILM g CENTRIFUGAL i=*"' cAsT mm! SOLIDIFIED WAX WAX FIG.8 FIG. 9

TORCH 65 SPIRAL GUT REMELTED WAX INVENTOR. H ARTHUR SINCLAIR TAYLOR ATTORNEY nite ates

This invention relates to a method for casting thin films of uniform thickness on the inside of a centrifuge drum, on a centrifugally cast surface, and cutting the thus cast film into a long ribbon of uniform cross-section.

Surgical sutures have normally been made from thin long tissues found in the intestinal tract of animals.

For purposes of the present description the term sutures includes also ligatures. These terms in the medical profession are more descriptive of the use of the strands than their composition. Ligatures are used to tie off blood vessels and the like. Sutures are used to sew or tie together various tissues. The term sutures is used in this specification to refer to both.

There is a limited supply of suitable intestinal tissues and these tissues are not uniform and are difiicult to separate and handle.

It would, therefore, seem obvious that a mechanical process giving uniform materials of uniform cross-section and of greater length than obtainable from animals tissues would have advantages. Attempts have been made to prepare sutures with such characteristics, but such previously known processes have involved unduly complicated casting and slitting procedures.

- One class of sutures is prepared from substantially pure collagen as found in the animals intestinal tract. A collagen of similar and suitable characteristics is found in animal tendons and other animal tissues. This collagen is separated from extraneous tissue material for reforma tion into strands of the proper characteristics for surgical uses. The problem of fluidizing the collagen, casting the fluidized collagen in suitable films, and regenerating has been described. One of the big problems has been a method of casting such that the ribbons or strands have a suitable, uniform cross-section.

60 sutures are defined by the US. Pharmacopoeia XV as having a diameter of not less than 0.0025 inch and not greater than 0.0045 inch. 4-0 strands have a minimum diameter of 0.0070 inch and a maximum of 0.0095 inch. As can be seen, a strandhaving this size is rather delicate to cast.

Additionally, the medical profession desires sutures of a maximum strength. The strength of a suture of unlform composition is determined by the area of the smallest cross-section. For maximum strength, a suture must have a uniform cross-section and preferably a crosssection of as large as possible within the size classification so that the suture will have maximum strength. The fluidized collagen has been cast as ribbons but it has been difficult to secure a completely uniform ribbon which would meet acceptable standards when twisted into a suture. One method of preparing a fluidized collagen and casting is described in United States Patent 2,747,228, Braun et al., Production 'of Collagen Strands, May 29,

It has now been found that a thicker fluidized collagen may be cast and a more uniform fluidized collagen film may be cast by centrifugallycasting the fluidized collagen than by previous methods. In casting on the external surface of a drum or on a continuous strip, only the force atent O 3,036,341 Patented May 29, 1962 ditionally by using a centrifugally formed casting surface greater uniformity may be obtained.

In practice a hollow casting drum is used, either mounted on a shaft, or centerlessly supported, in which a hollow rotating drum having a cylindrical drum face with annular rims on each side of that face is spun at a rate of speed such that materials placed in the drum will be held against the drum face by centrifugal force. Greater speeds give greater force to insure uniformity of the cast material. A higher speed -may be used for the casting step than during subsequent drying.

It is desirable that the casting surface be concentric with the axis of rotation of the drum. This is achieved by using a separate liquid which is also centrifugally cast in the drum and therefor any mechanical eccentricities are self-compensating because the casting surface is formed under the same type of conditions as the collagen film and hence both practically and theoretically the collagen film must be of uniform thickness. Preferably the casting surface is a wax which is introduced into the drum, thus forming a surface which is absolutely concentric with the axis of rotation. As will be later described, the cast film is helically cut to form a ribbon. In this cutting it is difficult to cut through just-the film and no more.- With a wax support it is very convenient to cut through the film and part way into the wax, as later described, which after removal of the ribbon leaves a residual wax surface with a cut spiral groove therein. A heat source such as a torch is introduced into the drum and directed on to the grooved surface of the wax to melt the wax while the drum is spinning. By remelting the wax a fresh concentric surface is formed. After all of the surface irregularities are melted out, the torch is removed and the thus remelted wax again assumes a smooth, miiform, concentric surface.

On the original or remelted smooth wax concentric surface is placed, by spraying or pouring, the fluidized collagen. The fluidized collagen is spread by centrifugal force smoothly and uniformly over the casting surface and, as it, too, is subjected to the same centrifugal force as was the wax forming the casting surface, this liquefied collagen is spread as a uniform film. By rotating at a somewhat higher speed than is necessary to merely retain the liquefied collagen in position, centrifugal forces greater than gravity are brought into play thus insuring that the cast film of collagen is free from air bubbles and other discontinuities. At slower centrifugal speeds or with thicker collagen formulations a small scraper may be used as a doctor to assist in spreading the fluidized collagen more rapidly. The collagen film is then hardened. Usually the collagen mass is an aqueous suspension or solution and is hardened by the evaporation of Water therefrom. An air blast is supplied to the interior face of the drum to speed drying. After the film has dried, the rapid rotation of the drum is stopped, the film cut in a helix, and the long ribbon of collagen thus formed is removed.

It is preferred that the wax be one to which the colla gen film adheres slightly during drying to reduce the tendency of the film to pull loose from the wax due to shrinkage stresses. The liquefied collagen may be of any of the known liquefied forms but conveniently is an acid swelled collagen and may have such plasticizers as polyethylene glycol or glycerine added thereto while in liquefied form. The liquefied form of collagen may either be a true solution or gel or suspension of collagen particles 'yond the. open-ended drums on .each side.

FIGURE 1 is a pictorial view in partial section of a double drum centrifugal casting machine.

FIGURE 2 is a front view of the double drum casting machine.

FIGURE 3 is a view of the pouring of the fluidized collagen in a single drum.

FIGURE 4 is a partial view of helically cutting the dried collagen film.

FIGURE 5 shows the winding of the finished ribbon from the casting surface on to a mandrel.

FIGURE 6 is a partially cut away pictorial view of a single drum centerless casting machine.

FIGURE 7 is a diagrammatic view showing the pour ing of the hot wax into the drum.

FIGURE 8 shows the pouring of the liquid collagen on to the centrifugally cast solidified wax surface.

' FIGURE 9 shows the dried collagen film on said wax surface.

FIGURE 10 shows the spiral cutting of the collagen film.

FIGURE 11 showsa torch remelting the centrifugally cast solidified wax surface.

MODIFICATION I As shown in FIGURE 1, on a support frame 15 is mounted an electric motor 16 attached to a reduction gear drive 17; The reduction gear drive 17 has extend- The shaft has a center 23 which is accessible from the interior of the drum. This center may be either male or "female but as shown in FIGURE 3 is a. male center. At the other side of the drum face is an annular rim 24. The

inside or working side of the drum face is accessible through the hole in this annular rim. As shown in FIG- URE l a safety housing 25 may be placed over the drum with a housing aperture 26 to permit access to the interior of the drum. While not necessary the safety housing is desirable to prevent accidental entanglements of the operators with the rotating drum.

Also driven by the reduction gear drive or other means is ablower 27 which blows air through ducts 28 into the interior of the drums. Parallel to the drum support shaft 18 is a'threaded shaft 29 which is'journalled in threaded shaft-support plates 30. This threaded shaft extends be- While other forms of threads may be used, an Acme thread is preferred for this shaft. The threaded shaft is driven by a disengageable reduction gear train 31 from the drum support shaft 18. Conveniently, but not necessarily, part of the gears in this train are supported on a gear train arm 32. This gear train arm may be disengaged so that .the reduction gear train and th shafiare ly rotated. fwhen needed.

Extending from the support frame 15 isaknife guide 7 33 which is below and parallel to the drum support shafts.

A knife frame 34 base. long half nut 35 adaptedfor restfing on and. engaging the threaded shaft 29. The half Qnutis long enoughjso that it bears on the threaded shaft La11t1iS aligned by contactwiththe threadedshaft.. The

'knifeifrarne 34 isdisengageably guided byrthe knife guide 1 33 so that the knife frame is supported and positioned by the knifeguide and the threaded shaft and as the threaded ffshaft turns, theknifeframe is uniformly advanced along the. thread. [At theend'of the'knife frame isa sharp cutting knife '36 which extendsfdown towards but does not a quite touch the inside of the drum face 20.

7 When. the knife frame is in position, the reduction gear train engaged, and the'drum slowly rotated, the knife point traces a helix very similar to the action of the cutting tool in a lathe. Disengageable with the center 23,

is a mandrel 37. The mandrel can be attached to one end' of a ribbon after it is cast, positionedon the center; and

as the drum rotates, the ribbon is stripped off the wax of the drum and wound on the mandrel as shown in FIG- URE 5. r

Preferably the motor 16 or the reduction gear drive 17 has at least two speeds, one for high speed driving of the drum during the casting operations and a lower speed for use during the cutting and winding operations.

Example 1 As illustrative of the use of the present machine, drums having a diameter of approximateiy 12 inches are rotated at 1760 revolutions per minute. A wax is prepared by mixing 15% of cellulose acetate butyrate such as sold by Tennessee Eastman as type EAB381-20 (20 second viscosity) with 85% acetylated monoglycerides such as is sold by Distillation Products Industries under the trademark Myvacet by melting together at 150 G. with stirring. This type composition is mentioned in Industrial and Engineering Chemistry, 46, l3A- 15A (September 1954). The hot wax is poured into the rotating drum to form a'layer about 3 millimeters thick. Air from the blower is directed onto the cast wax to chill the surface. In its molten staterthe wax spreads uniformly over the interior face of the drum to give a centrifugally cast forming surface 38 on the wax 39. This centrifugally cast forming surface is necessarily concentric with the axis of rotation of the drum. 7

A composition is prepared containing 0.75% dry solids of acid swelled collagen gel. This is prepared by selecting cattle tendons, washing the tendons free from salt, flesh, and foreign matter, then disintegrating in water in a mill. The mixture is diluted to 0.75% dry solids and acidified with hydrochloric acid to a pH of 3.5. 5% by weight of dry solids of polyethylene glycol having an knife on. the knife frame is introduced near one edge of the drum, the reduction gear train is engaged, and the drum is rotated at a speed of about 60 revolutions per minute as the knife advances cutting the film into a ribbon about 3 millimeters wide. After the knife has traversed the entire face of the drum, a similar cutting is made in the other drum. One end of the ribbon is disengaged, at-

tached to a mandrel and the drum rotated slowly as the mandrel is heldin position in the center of the drum as shown in FIGURE 5 pulling the ribbon free from the' 7 cast surface and wrapping the ribbon about the mandrel.

.any fragments of collagen or other debris.

The casting surface is wiped with a damp rag to remove is introduced into the drum and played against the surface of the wax therein as the drum is rotated until the wax melts suificiently to remove the evidence of thecutting knife as it penetrated through the film into the'wax,

then heat is discontinued and the drum is allowed to rotate'at centrifugal speed until the wax film has solidified.

The surface is then in condition for another film casting -operation.

The ribbon of regenerated collagen is rinsed with acetone to remove any adherent wax, wiped dry, and twisted into a suture. The suture may be stretched slightly, chromicized, or otherwise. treated, to have the final characteristicsdesired.

Example 2 r Example l is repeated using glycerine instead of polyethylene glycol as the plasticizer. A good suture is produced. a I

MODIFICATION 11.

Another modification of the machine of this invention is shown 'in FIGURE 6 in which a centerless drum 45 A gas torch consisting of a drum face 46 having an annular rim 47 at each end thereof is supported by single flanged wheels 49 on shafts 48 and held down by wheels on a hold down shaft 50 which are supported by a safety housing 51 on a table 52. Conveniently, but not necessarily the wheels are attached to the shafts and the shafts rotate in bearings 53. The single flanged wheels, like the flanged wheels of railway cars, support the drum for rotation and restrain the drum from axial motion. Adjacent to the drum is a multiple speed motor 54 having thereon a pulley 55. A belt 56 passes around the pulley 55 and the centerless drum 45 thus rotating the drum. The housing 51 is open at both ends thus serving to permit access to the interior of the drum, air flow through the center of the drum, and yet protects operators from accidental contact with the drum.

Adjacent to one end of the drum is a fan 57 on a fan support 58 to blow air through the drum. A disengageable knife guide 5? is mounted on a guide support 60 which engage an edge of the table and is positioned by a dowel 61. A similar support is at each end of the knife guide. Journalled in the guide supports is a threaded shaft 62 on which is mounted a threaded knife carrier 63 which also slides on the knife guide 59 and is positioned thereby. From this carrier extends a knife arm 64 on the end of which is a cutting knife 65. This cutting knife is long enough to extend through a cast film part way into a centrifugally cast wax in the drum but not be dulled by contact with the drum. Adjacent to one end of the threaded shaft is a threaded shaft pulley 66. On one of the shafts 48 is a drive pulley 67. Between these pulleys is a belt 68. Preferably the knife assembly is symmetrical so that it may be driven in one direction during one operation then reversed and driven back in the next cutting operation so that it is unnecessary to reposition the knife carrier on the threaded shaft after a cutting operation.

Example 3 A 36 inch drum is rotated at 700 revolutions per minute. In this drum is poured sufiicient wax to form a layer about a quarter of an inch thick. The wax used is a synthetic acetylated glycerol monostearate of 98% purity. The Wax is allowed to cool and solidify while the drum is spinning. A 1% dry solids liquefied collagen is prepared by shredding 600 grams of beef tendons, about 200 grams dry solids content, and mixing with enough water and 50 milliliters of 3 normal hydrochloric acid to give 20 liters of final solution, the mixture is stirred and passed through a grinding mill. The mixture after standing overnight is then added to the spinning drum in suificient volume to give a dried film inch thick. Air is blown through the rotating drum until the collagen dries to a film, about 12 hours is required.

The knife carrier assembly is positioned and a helix cut by rotating the drum at a slow speed of about 20 revolutions per minute as the knife cuts through the dry film and part way into the supporting wax. The pouring of the wax is shown in FIGURE 7, the casting of the liquid collagen in FIGURE 8, and the spiral cutting is shown in FIGURE 10.

After the entire film is cut to a helix, the knife assembly is removed, a mandrel placed inside of the drum and the ribbon is wound on the mandrel. The ribbon is ready for subsequent processing.

The interior of the drum is wiped with a damp cloth to remove any loose fibers, etc.

High speed rotation of the drum is resumed and a group of burners introduced into the interior of the drum to melt the wax surface until the grooves formed by the cutting knife are removed and a smooth interior surface again formed. The flame is removed and the wax permitted to harden; after which the machine is ready for the next casting operation.

The ribbon may be subsequently processed in accordance with conventional procedures as, for example, ace- 6, tone wiping to remove wax, stretching, chromicizing, and twisting. A plurality of ribbons may be twisted together in a slightly moistened condition to form larger strands. The strands for the sutures may either be processed in the as-cast length or cut into convenient segments for individually processing as individual sutures. i

As will be obvious, many modifications may be made in the process and apparatus, such as the casting speed may vary, the methods of introducing, cooling, and drying may be varied, and the time of cycles varied over a wide range depending upon the temperature of the drying air, the relative humidity of the drying air, the velocity of the drying air, and the thickness of the cast film. Thin films are particularly useful for the smaller strands or the smaller sutures, and thicker films may be cast and cut into wider ribbons for larger strands or larger sutures or for use in the strings of musical instruments or sports equipment such as tennis rackets, as may be desired.

The long continuous uniform strands are of particular utility in the stringing of sports equipment such as tennis rackets because the strand is essentially continuous rather than formed from a plurality of shorter elements, and as such have greater elements, and as such have greater strength, greater uniformity, and greater reliability.

The composition of the material to be cast may vary depending upon the form in which it is prepared and its use. Different plasticizers or chromicizing agents may be introduced into the film as it is cast, or in subsequent treatment different concentrations may be used, and differ ent subsequent treatments may be utilized.

Whereas described primarily in conjunction with the casting of collagen for sutures, the present casting machine and method may be used in the casting of any liquid which forms a thin film in which uniformity and reliability of the film characteristics are regarded as an essential attribute. Whereas wax is particularly useful in the casting of sutures from collagen, other casting surfaces may be used which are inert towards and preferably slightly sticky towards a particular material to be cast.

If the cutting knife is accurately positioned, the surface of the wax may be only slightly out, and may be restored by wiping with a solvent moistened rag to smooth over the surface.

I claim:

1. A process of making a thin collagen ribbon of uniform cross-section which comprises: rotating rapidly a mass of a meltable wax at least the surface of which is in molten form about an axis to form a liquid surface concentric with said axis, cooling and solidifying the wax, to form a smooth solid film forming surface which is concentric with said axis, spreading interiorly on said surface a thin layer of a dilute aqueous regenerable collagen mass, evaporating the water to form a film, while continuing to rapidly rotate; then discontinuing the rapid rotation, cutting a helix through the thus formed film, to form a ribbon, and removing the ribbon from the forming surface.

2. A process of making a thin film of uniform thickness comprising rapidly rotating a hollow drum having annular end walls, at least one end of which is open, about its generating axis, pouring in a mixture of cellulose acetate butyrate and acetylated monoglycerides, and cooling to the solid state, thereby centrifugally casting a smooth solid forming surface, and insuring concentricity of the forming surface and the axis of rotation, casting interiorly thereon a thin liquid layer of a solidifiable film forming collagen gel, solidifying said gel to form a film maintaining contact between the gel and the forming surface, thus obtaining unifor'm film characteristics, and removing the thus formed film.

3. A process of making a thin film of uniform thickness comprising rapidly rotating a hollow drum having annular end walls, at least one end of which is open,

7 ing surface, thus obtaining uniform film characteristics,

cutting a helix into the thus formed film and stripping 19 the thus formed thin ribbon.

References Cited in the file of this patent V UNITED STATES PATENTS 1,318,520

'Wolever Oct. 14, 1919 15 8 Dickson -May 8, Weston' f Mar. 6, Spanel' June 14, 9, Braun etal. May 29, Boggs Mar. 19, Gerson' Oct. 21,

FOREIGN PATENTS Great Britain July 31,