HEMOSTATIC PASTE AND METHODS OF MAKING THEREOF

Abstract

The present invention is directed to a flowable hemostatic paste comprising a crosslinked carboxymethyl cellulose and at least one non-toxic dispersant. More specifically the present invention relates to a hemostatic paste containing citric acid cross-linked CMC, which is suspended or dispersed as a powder in a mixture of a first non-toxic glycerol-containing hygroscopic dispersant and a second non-toxic alcohol functionalized dispersant comprising propylene glycol or 1,3-butanediol.

Claims

1. A flowable hemostatic paste comprising: a. An xerogel crosslinked milled polysaccharide dispersed within a substantially anhydrous blend of i. A glycerol-containing dispersant and ii. An alcohol-functionalized dispersant selected from the group consisting of propylene glycol and 1,3-Butanediol or mixtures thereof, wherein the paste has a moderate viscosity at rest and room temperature and provides a substantially homogenous dispersion of the crosslinked polysaccharide, and wherein: (i) said paste comprises the weight ratio of propylene glycol to glycerol of from about 1:0.5 to about 1:2; (ii) said paste further comprises an alkaline agent; and/or (iii) the weight ratio of cross-linked polysaccharide to glycerol-containing dispersant is about 0.9-1.25.

2. The hemostatic paste of claim 1, wherein the crosslinked polysaccharide comprises a carboxymethyl cellulose (CMC) that is cross-linked by reaction via a polyfunctional carboxylic acid, wherein said acid is selected from the group consisting of malic, tartaric, citric, malonic, succinic, glutaric, or adipic acid or mixtures thereof.

3. The hemostatic paste of claim 2, wherein said acid is citric acid.

4. The hemostatic paste of claim 3, wherein said paste comprises: a. 35% to 65% by weight of citric acid cross-linked CMC, which is suspended or dispersed in powder form in a viscous liquid mixture of a glycerol-containing hygroscopic dispersant and an alcohol-functionalized dispersant of propylene glycol, 1,3-Butanediol or mixtures thereof.

5. The hemostatic paste of claim 4, wherein said cross-linked CMC is a suspended powder having average particle size less than 100 microns.

6. The hemostatic paste of claim 5, wherein said paste comprises less than 1% of water.

7. (canceled)

8. The hemostatic paste of claim 7, wherein said alkaline agent comprises sodium hydroxide, present at about 0.1-3%.

9. (canceled)

10. (canceled)

11. The hemostatic paste of claim 5, wherein said paste comprises a. about 49-55% of citric acid cross-linked CMC; b. about 18-30% of glycerol; c. about 15-30% of propylene glycol.

12. (canceled)

13. The hemostatic paste of claim 5, wherein said paste is supported on a substrate that is a flexible bioabsorbable sheet.

14. The hemostatic paste of claim 13, wherein said substrate comprises oxidized cellulose or polyglactin 910.

15. The hemostatic paste of claim 5, wherein said paste is disposed in a squeezable tube.

16. (canceled)

17. (canceled)

18. A method of making a wound dressing containing the hemostatic paste of claim 5, comprising the steps of: a. Applying said hemostatic paste onto at least one face of a flexible bioabsorbable sheet substrate.

19. A method of making a wound dressing according to claim 18 wherein the flexible bioabsorbable sheet is in the form of a woven mesh, structured felt, unstructured felt, film, powder or combinations thereof and contains one or more layers of oxidized cellulose, hemostatic polymeric blends or mixtures thereof.

20. A method of using the hemostatic paste of claim 5, comprising the steps of: a. Applying said hemostatic paste, optionally supported on a flexible absorbable sheet substrate, to a bleeding tissue or wound.

Description

BRIEF DESCRIPTION OF FIGURES

[0043] FIG. 1 shows schematic pathway for synthesis of cross-linked carboxymethyl cellulose (CMC).

[0044] FIG. 2 is a photo showing hemostatic paste as it is expressed from a tube onto a substrate.

[0045] FIG. 3 shows swelling of CMC-CA xerogels in plasma, saline, and water at 1 min and 2.5 min after immersion.

[0046] FIG. 4 shows swelling of CMC based xerogels crosslinked by different carboxylic acids upon exposure to water at 1 min and 2.5 min after immersion.

[0047] FIG. 5 shows swelling of xerogels made by crosslinking of different polysaccharides by citric acid in comparative chart for swelling in DI water, saline or porcine plasma.

[0048] FIG. 6 shows hygroscopic or water-free paste relative to paste containing 10% and 20% water.

[0049] FIG. 7 shows the hydrogel paste containing 5% and 10% of water in a cut open dispensing tube.

[0050] FIG. 8 shows a chart presenting viscosities of different formulations of the instant hemostatic paste as a function of shear rate.

[0051] FIG. 9 is showing CMC-CA powder on animal model bleeding site comprising a puncture wound.

[0052] FIG. 10 is showing the hemostatic paste precisely delivered to the wound site.

[0053] FIG. 11 is showing CMC-CA powder applied on the puncture model.

[0054] FIG. 12 is showing SEM micrograph of CMC-CA powder formed hydrogel

[0055] FIG. 13 is showing the inventive hemostatic paste applied onto the liver puncture model

[0056] FIG. 14 is showing the expressed hemostatic paste containing particle size 100 m 300 m.

[0057] FIG. 15 is showing a micrograph of CMC-CA xerogel powder for particle size <100 m.

[0058] FIG. 16 shows the testing results of the hemostatic paste containing non-cross-linked CMC (comparative example).

[0059] FIG. 17 shows the testing results of the hemostatic paste containing CMC-CA (inventive example).

[0060] FIG. 18 shows the testing results of the hemostatic paste containing CA cross-linked carboxymethyl starch (comparative example).

[0061] FIG. 19 shows the testing of the adhesion to the tissue.

[0062] FIG. 20 shows the inventive CMC-CA based hemostatic paste prior, during application, and after application into liver punch model.

[0063] FIG. 21 shows the inventive CMC-CA based hemostatic paste applied to commercially available Oxidized Regenerated Cellulose (ORC)-based non-woven pad.

[0064] FIG. 22 shows the CMC-CA based hemostatic paste applied to commercially available Oxidized Regenerated Cellulose (ORC)-based non-woven pad and the resulting composite prior to being tested for adhesion to a liver tissue coupon, and after contacting with liver tissue coupon.

DETAILED DESCRIPTION

[0065] The present invention relates generally to agents and materials for promoting hemostasis and tissue sealing and, more particularly, to fast swelling, highly absorbent hemostatic composition in a form of a paste comprising a mixture of crosslinked carboxymethyl cellulose with one or more dispersants, and to methods for manufacturing and using such hemostatic composition.

[0066] The embodiments of the present invention further relate to fast swelling, superabsorbable, biodegradable hemostatic paste. In some embodiments, the hemostatic paste comprises at least three components. The first component comprises a xerogel powder that is synthesized by crosslinking carboxymethyl cellulose (CMC) using polyfunctional carboxylic acids such as citric acid (alternatively malic, tartaric, citric, malonic, succinic, glutaric, adipic acid etc.). A xerogel is obtained when the liquid phase of a gel is removed by evaporation. It typically exhibits shrinkage of greater than (>) 90%.

[0067] Cross-linked CMC can form hydrogel when placed in contact with body fluids. A hydrogel is a network of polymer chains that are hydrophilic, sometimes found as a colloidal gel in which water is the dispersion medium. The concentration of crosslinked CMC in the hemostatic paste ranges from about 35% to 65% weight by weight. The second component comprises a glycerol-containing dispersant at 10% to 30% weight by weight. The third component comprises an alcohol-functionalized dispersing agent at 10% to about 30% weight by weight, such as propylene glycol or 1,3-Butanediol. The hemostatic paste is biocompatible to treat mild or moderate bleeding.

[0068] According to one embodiment, a fast swelling, superabsorbable, biodegradable hemostatic paste comprises: carboxymethyl cellulose crosslinked by citric acid (or similar polyfunctional carboxylic acid e.g. malic, tartaric, citric, malonic, succinic, glutaric, adipic acid) 35% to 65% which is suspended or dispersed as a fine powder, as demonstrated in the examples, in a mixture of a first non-toxic glycerol-containing, hygroscopic dispersant and a second non-toxic alcohol-functionalized dispersant, preferably comprising propylene glycol or 1,3-Butanediol. A paste means, for purposes of this application, a flowable material that has sufficient viscosity and cohesion to maintain a continuous, singular form at room temperature when placed upon a flat, unconstrained flat surface. A pile of sand or similar collection of particulates would not be a paste as the individual particles lack sufficient cohesion with one another. The inventive formulation is substantially free of water or anhydrous. In some embodiments, both dispersants are hydrophilic.

[0069] Dried cross-linked CMC xerogel has three-dimensional crosslinked polymeric network that are capable of absorbing large quantities of water, saline or physiological liquid forming hydrogels. The powerful osmotic action dehydrates and gels the blood upon contact and swelling to more than 20 times of the dry xerogel volume to fill up a wound and produce a back pressure in the confined wound space to simulate tamponade effect and enhance the natural clotting process. The flowability and flexibility of the inventive paste also ensure its access to narrow spaces and its application to uneven surfaces, making it a useful material to address the intra-operational bleeding or oozing. The instant paste is particularly suitable for hard to access wounds such as tissue crevice or cavity bleeding.

[0070] In an alternative embodiment, the inventive paste can also be used in conjunction with a backing, pad, scaffold, or matrix to provide mechanical strength to cover the wound surface. In this case, the instant paste is supported on a pad for ease of application or tamponade.

[0071] In another embodiment, the instant hemostatic paste can be employed for a timed or delayed release of active agents e.g. as a drug-delivery vehicle. The composition can incorporate growth factors, antibiotics, local anesthetics, and any agents useful to improve wound healing, prevent infection or relieve pain. By incorporating coagulation activators, platelet activators or blood vessel constrictors, fibrinolytic function inhibitors, etc., including thrombin, fibrinogen, etc., the hemostatic effect of the paste could be further improved.

[0072] According to the inventive embodiments, the instant hemostatic paste is anhydrous and hygroscopic. It can absorb liquid, such as water, blood, etc., and expands to form hydrogel within seconds, such as within 5, 20, 30, 50, 120, 300 seconds, more preferably within 5-30 seconds.

[0073] The xerogel powder particles are suspended in dispersant components of the hemostatic paste. The resulting paste is flowable, and can be deposited into/onto uneven surfaces or into narrow spaces.

[0074] The main component of the paste forming the xerogel, is carboxymethyl cellulose, crosslinked by citric acid, resulting in an increased mechanical stability. Several polysaccharides show a high absorption ability in the unmodified state, but these have the disadvantage that the swelling occurs only in warm water and that dissolution can take place. Such unmodified/uncross-linked polysaccharides have low mechanical stability and can undergo degradation, and/or retrogradation, and/or and syneresis (contraction of a gel accompanied by the separating out of liquid).

[0075] The inventors observed that advantageously cross-linked CMC particles do not absorb the dispersants which are anhydrous but hydrophilic, glycerol and propylene glycol, despite glycerol and propylene glycol being hydrophilic, while particles were still capable to rapidly absorbing blood, plasma, water, bodily fluids.

[0076] Without wishing to be bound by any theory, the non-aqueous solvents/carriers/dispersants are outside of the crosslinked network particles and should not influence their ability to absorb liquids. The absorption would appear to be maximized by eliminating pre-swelling or pre-load. The particles do not swell or absorb the selected solvents/carriers/dispersants but can quickly swell when provided with plasma and absorb the greatest % of plasma components. Presence of compounds such as sorbitol in the cross-linking reaction solution may result in the sorbitol would become entrapped within the cross-linked network. The entrapped sorbitol would then help to prevent excessive crosslinking by taking up space for a network link and could also alter the hydrophilicity of the overall particle by attracting water into the crosslinked particles. Thus, it is preferred that the present system is devoid of sorbitol or similar chemical moieties and/or excipients. The selected solvents/carriers/dispersants should not shield the crosslinked network particles from the plasma components that are intended to be absorbed.

Example 1. Making of the Hemostatic Paste and Paste Composition

[0077] Referring to FIG. 1, one schematic pathway for synthesis of cross-linked carboxymethyl cellulose (CMC) is shown, with initial reagents being CMC sodium salt (CMC-Na) and Citric acid (CA), with the reaction carried out, as an example only, at 140 C. for 25 min, resulting in the cross-linked CMC (CMC-Na-CA). Dried cross-linked CMC, which can be referred to as a xerogel or dried, compact hydrogel, is then used as a component for forming the inventive highly absorbent (super absorbent) hemostatic paste.

[0078] In one embodiment, CMC was cross-linked by citric acid as follows. The sodium salt of the CMC (supplier: Shanghai Aladdin biochemical Technologies Co. Ltd, China) was used for the synthesis of the hydrogels. A cross-linker ratio Fz of 0.025 was used. Fz is defined as the amount of cross-linking agent divided by the amount of anhydroglucose units. The cross-linking agent was first dissolved in distilled water and then thoroughly homogenized with the CMC, resulting in a homogeneous dough-like product. The dough-like product was then chopped into small chunks. The product was heated at 140 C. for 25 min in a preheated oven to accomplish cross-linking. The obtained product was dried at 70 overnight and then ground to an average particle size of below 100 m.

[0079] The resulting cross-linked CMC powder was then mixed with dispersants as follows. Glycerol (in some embodiment containing 1% of NaOH) was added into powder, and mixed/stirred until all powder particles are coated by glycerol, forming a dough-like paste. Then propylene glycol is added to the above paste, and mixed/stirred, to form the final, flowable hemostatic paste.

[0080] Sodium hydroxide is added into glycerol to neutralize the free acid. Sodium hydroxide component is believed to chemically stabilize the formulation by neutralizing the unreacted citric acid and polycarboxylic group of the carboxymethyl cellulose. Undesirably, the carboxylic group in the citric acid and the crosslinked CMC might react with the hydroxyl group in the propylene glycol resulting in an esterification reaction which may cause the hardening of the paste over time. Sodium hydroxide further is expected to improve the water absorption and swelling property of the cross linked carboxymethyl cellulose.

[0081] According to one embodiment, glycerol was used with about 1% of sodium hydroxide dissolved in it to adjust pH. NaOH was added to glycerol at elevated temperature, such as 65 C., resulting in rapid dissolution and no precipitating out upon cooling to ambient temperature of 20-25 C. The pH of the glycerol was measured as 5.7 with NaOH added, prior to adding NaOH pH was 5.18.

[0082] Without wishing to be bound by any theory, additions of sodium hydroxide enable improved performance and stability of the final hemostatic paste. The COOH group in the CMC-CA may tend to react with OH group of propylene glycol and cause limited stability of the paste. Use of NaOH then enables formulation which has the COOH groups at least partially neutralized. However simply adding NaOH into the CMC-CA paste will not be practical or possible because with such small amount of NaOH powder, it is virtually impossible to uniformly and homogenously disperse it through the CMC-CA powder matrix. On the other hand, dissolving NaOH in water and then adding it as aqueous solution also will not work as the paste formulation needs to be anhydrous. Even small quantities of water present in contact with the CMC-CA powder could cause the powder to swell and may compromise the ability to quickly absorb blood when applied to the wound.

[0083] Advantageously, for the inventive hemostatic paste, the dispersant is anhydrous. According to embodiments of the present invention, for the dispersant selection, the key requirements are non-toxic, anhydrous, able to dissolve NaOH, and biocompatible. While NaOH was found to be very poorly soluble at room temperature in glycerol (i.e. it was exceedingly difficult to dissolve NaOH at room temperature) the inventors discovered that NaOH can be easily dissolved in glycerol at about 65 C. and then will not precipitate upon cooling. Table 1 shows the solubility of NaOH in glycerol as a function of temperature. Full dissolution was observed at least 65 C.

TABLE-US-00001 TABLE 1 Dissolution temperature of NaOH in glycerol 100 mg of NaOH powder mixing with 10 g of glycerol Temperature C. Dissolving or not 25 no 35 no 45 no 55 no 65 yes

[0084] After dissolving 1% of NaOH in glycerol, the inventors used this solution to partially neutralize the formulation, improve stability and swellability. As discussed above, pH was adjusted from 5.18 to 5.71.

[0085] Referring to Table 2, Composition of hemostatic paste is presented. All components are biocompatible.

TABLE-US-00002 TABLE 2 Composition of the hemostatic paste Weight % Weight to prepare Compound Function concentration 10 g of paste, g Cross-linked CMC Absorbent 53.1% 5.31 powder (CMC-CA) particles 1% NaOH in glycerol Dispersant 26.5% 2.65 Propylene glycol Dispersant 20.4% 2.04 TOTAL: 100 10 g

[0086] Referring to FIG. 2, appearance of the inventive hemostatic paste is shown as it is expressed from a tube onto a substrate. The paste is anhydrous, flowable and ready-to-use. It can be used by directly applying it to a bleeding site, or be used together with a hemostatic gauze or substrate, absorbable or not absorbable.

[0087] Comparisons of hemostatic paste with only one dispersant to the instant hemostatic paste are presented below. Hemostatic paste formulated with glycerol only, without the second dispersant (such as propylene glycol or 1,3-Butanediol), will have very high viscosity and the composition with only glycerol has poor absorbing properties. Hemostatic paste formulated with the second dispersant propylene glycol or 1,3-Butanediol, without the first dispersant (glycerol) would result in a poor dispersing effect of crosslinked CMC. Precipitation was observed within short time. However, Propylene glycol, as a water-miscible co-solvent, does not inhibit the crosslinked CMC from rapidly absorbing liquid. With both glycerol and the propylene glycol in a certain range, the viscosity of the paste can be tuned to ranges convenient for expressing and storage while no precipitation was observed, while at the same time properties of crosslinked CMC of rapidly absorbing liquids was maintained. Thus, it was shown that the presence of two dispersants, as described, was critical for the hemostatic paste handling, storage, and performance.

[0088] Advantageously, the present hemostatic paste compositions are anhydrous, with the water absence critical to performance.

Example 2. Swelling Properties of Cross-Linked CMC and Other Polysaccharides

[0089] For swelling testing, 1 gram of xerogel was immersed in excess DI water, saline or porcine plasma at room temperature for certain period to reach swelling equilibrium. At time intervals of 1, 2.5 min, swollen samples were separated from the unabsorbed DI water, saline or plasma by filtering through a 100-mesh screen. Swelling percent at each time point was calculated using the following formula Equation: SP=100 (MtMd)/Md where SP is the swelling percent, Mt and Md are the weights of swollen hydrogel particles at time t and dry xerogel particles, respectively.

[0090] Referring to FIG. 3, swelling of CMC-CA xerogels is shown in plasma, saline, and water at 1 min and 2.5 min after immersion, with significant swelling of the order of 1900-2700% at 1 min and 2500-3600% at 2.5 min observed experimentally.

[0091] Referring to FIG. 4, swelling of CMC based xerogels crosslinked by different carboxylic acids is compared upon exposure to water at 1 min and 2.5 min after immersion. The data show that xerogels made by crosslinking CMC with Citric acid (CMC-CA) has strongest swelling capacity with significant swelling of the order of 2900% at 1 min and 4200% at 2.5 min observed experimentally, vs. somewhat lower swelling for xerogels made by crosslinking CMC with Succinic acid, Malic acid or Glutaric acid (CA: Citric acid; MA: Malic acid; SA: Succinic acid; GA: Glutaric acid).

[0092] Referring to FIG. 5, swelling of xerogels made by crosslinking of different polysaccharides by citric acid is presented in a comparative chart for swelling in DI water, saline or porcine plasma. As can be seen from the data presented, in water, xerogels made from carboxymethyl chitosan showed highest swelling property. However, in saline and plasma, xerogel made from carboxymethyl cellulose showed highest swelling property.

Example 3. Criticality of Water Absence

[0093] The criticality of water absence was further evaluated by testing the instant hemostatic paste with additions of water. It was shown that at 5% and above concentration of water, properties of the hemostatic paste have degraded. Referring to FIG. 6, hygroscopic or water-free paste is shown as flowable, semi-liquid material, while paste containing 10%, 20% water is shown as clumped, crumbly material.

[0094] Referring to FIG. 7, The flowability of the hydrogel paste is reduced when containing water, potentially due to volume expanding of hydrogel particles, especially over time. The paste containing 5% of water is shown in a cut open dispensing tube, with properties making it hard to dispense. The paste containing 10% water is shown as rubber-like solidified material which will not be possible to express from the tube.

[0095] Thus, the water content can compromise the flowability of the instant hemostatic paste with the water content is inversely proportional to the flowability of the paste. Thus, it is preferred that the paste is substantially water free, or has water content 0-5%, such as 0, 0.5, 1, 2, 3, 5%.

Example 4. Evaluations of Optimal Concentration Ranges and Optimal Ratios

[0096] A range of different formulations of the hemostatic paste was further evaluated. Referring now to Table 3, several formulations of the hemostatic paste are presented, with all having 53% by weight CMC-CA and variable amounts of glycerol, propylene glycol (PG) dispersants.

TABLE-US-00003 TABLE 3 Formulations of hydrogel paste CMC- propylene CMC PG Glycerol Formulation CA/g glycol/g glycerol/g % % % description 1 5 0.00 4.44 53% 0.0% 47% Only Glycerol 2 5 2.22 2.22 53% 24 24 PG:Glycerol 1:1 3 5 1.78 2.66 53% 19 28 PG:Glycerol 1:1.5 4 5 1.48 2.96 53% 16 31 PG:Glycerol 1:2 5 5 1.92 2.52 53% 20 27 PG:Glycerol 1:1.3 6 5 4.44 0.00 53% 47 0.0 Only PG 7 5 2.66 1.78 53% 28 19 PG:Glycerol 1.5:1 8 5 2.98 1.48 53% 32 16 PG:Glycerol 2:1

[0097] Referring to FIG. 8, viscosities of different formulations of the instant hemostatic paste are presented as a function of shear rate. The data was measured by Discovery HR-3 hybrid rheometer (TA instruments), using flat plate, steady shear test. It was discovered that for a hemostatic paste with good performance, the viscosity should rapidly decrease while the shear force is increasing, corresponding to ease of expressing the paste from the storage container when being applied. The paste should also have high viscosity at stationary state, which makes it stay at where it is applied instead of flowing away (run-off). Eight different formulations were tested to evaluate the appropriate range of the dispersants. According to the viscosity data and the performance of paste on the animal tissue, the range between PG-glycerol 1:0.5 to PG-glycerol 1:2 is the best performing range. Referring to Table 3, showing eight different formulations tested, for 100 g of paste, the CMC powder represents 53% (w/w) of the total weight and that of Glycerol is between 16%-31% (w/w).

[0098] A range of compositions with variable ratios of glycerol and propylene glycol were further evaluated and optimized. Referring to Table 4, properties of the resulting hemostatic paste are shown as a function of the composition.

TABLE-US-00004 TABLE 4 Glycerol and the propylene glycol ratio optimization. Appearance/ Propylene glycerol/ CMC-CA/ flowability/ CMC- Glycol Glycerol, CMC- PG Glycerol PG glycerol viscosity CA, g (PG), g g CA % % % RATIO RATIO of paste 1 8.4 6.3 0 57 43 0 0 1.33 thin 2 5.76 2.3 4.3 47 17 35 1.87 0.87 Thick 3 13 5 6.55 53 20 27 1.31 1.13 moderate scale 61.26 23.5 30.62 53 20 27 1.30 1.13 Moderate up

[0099] The terms Thick, Thin, Moderate above are based on flowability and appearance. The thick sample is almost un-flowable, and will not conform well to the irregular shape of wound site. The thin sample is too liquid resulting in easy to runoff and not staying in place. Moderate compositions were found to be acceptable in that they can be easily shaped, conformed well to the wound site, and resulted in no runoff.

[0100] Compositions containing about 49-55% of CMC-CA are preferred.

[0101] Compositions containing about 18-30% of glycerol are preferred.

[0102] Compositions containing about 15-30% of propylene glycol are preferred.

[0103] Compositions characterized by the ratio of glycerol to propylene glycol (by weight) of about 1-1.5 are preferred.

[0104] Compositions characterized by the ratio of CMC-CA to glycerol (by weight) of 0.9-1.25 are preferred.

Example 5. Dispersants Comparisons

[0105] In some embodiments, three different dispersants were compared: propylene glycol, dipropylene glycol, 1,3-Butanediol, as shown in Table 5. At the same ratio, the dipropylene glycol paste is stickier and less useable than the other two. The flowability of the dipropylene glycol paste was not as good as paste formulated with propylene glycol and the 1,3-Butanediol.

TABLE-US-00005 TABLE 5 Dispersants comparisons Actual weight/g CMC-CA 5.31 glycerol 2.94 propylene glycol 2.28 RESULT: Paste with moderate viscosity, acceptable flowability CMC-CA 5.31 glycerol 2.94 dipropylene glycol 2.31 RESULT: Paste with sticky viscosity, not acceptable CMC-CA 5.31 glycerol 3.04 1,3-Butanediol 2.3 RESULT: Paste with moderate viscosity, acceptable flowability

Example 6. Paste-Powder Comparisons

[0106] CMC-CA powder was further compared to the inventive paste in performance, and the advantages in performance demonstrated showing that the flowable viscous paste format has advantages over the same material as a powder. According to an animal study result, although CMC-CA powder was also effective stopping bleeding in a puncture model, powder has exhibited two disadvantages comparing with the paste:

[0107] Powder was not possible precisely deliver, and as it was sprayed, the covering range was somewhat wide, not as suitable for a confined wound space. Referring to FIG. 9, showing CMC-CA powder on animal model bleeding site comprising a puncture wound, CMC-CA powder covers a wide surface area surrounding the puncture wound, resulting in broad coverage but lack of precise delivery. Referring to FIG. 10, showing the instant hemostatic paste delivery, paste is shown to be precisely delivered to the wound site, and does not block the vision. Referring to FIG. 11, CMC-CA powder applied on the puncture model shows less cohesiveness between particles and blood can break through the gaps between the powder particles.

[0108] Referring to FIG. 12, SEM micrograph of CMC-CA powder (<100 m) formed hydrogel is presented. The hydrogel formed by powder shows that there are still gaps, crevices within the hydrogel matrix. Through which blood can seep through or leak through.

[0109] Referring to FIG. 13, the inventive hemostatic paste is shown applied onto the liver puncture model, resulting in hemostasis. Paste format has higher cohesiveness among the particles compared with powders. No blood break-through through the paste was observed.

Example 7. CMC-CA Xerogel Particulate Properties

[0110] CMC-CA powder with particle size 100 m300 m was observed to result in solid powder in the paste started to precipitate during storage. When tube contained the hemostatic paste was squeezed to dispense the paste, dispersants came out first, and the powder settled to the bottom of the tube, and was hard to dispense, rendering a portion of the paste dry and non-flowable. However, powder particle size <100 m such detrimental performance was not observed, with the paste kept homogeneous throughout storage, and none or minimal sedimentation was observed. Referring to FIG. 14, particle size 100 m300 m is seen rendering a portion of the paste dry and non-flowable, due to precipitation.

[0111] CMC-CA powder was further characterized showing the shape of the particles is irregular, because of blender used to mill the powder. Referring to FIG. 15, Micrograph of CMC-CA xerogel powder is shown for particle size <100 m.

Example 8. Hemostatic Paste Properties in Heparinized Animal Model: Hemostasis Data for Cross-Linked and Non-Cross-Linked CMC

[0112] The hemostatic paste formulated as described in Example 1 was further evaluated in heparinized liver punch model (porcine), comparing paste formulated with citric acid cross-linked CMC (CMC-CA) and non-cross-linked CMC. The testing was performed as follows in heparinized animals. The animal (pig) was injected with heparin to inhibit the blood coagulation system. An 8-mm punch hole wound was made on the liver. The evaluated hemostatic paste was then applied into the punch hole wound and pressed with gauze for 1 minute. The gauze was removed to observe whether hemostasis is achieved. Extend the observation time up to 30 minutes to evaluate the effectiveness of the hemostatic paste.

[0113] Referring to FIG. 16, the testing results of the hemostatic paste formulated as described in Example 1, but using non-cross-linked CMC, is presented (comparative example). Non-crosslinked CMC hemostatic paste was applied into the punch wound, and hemostasis was achieved in 1 minute, as shown. However, re-bleeding was observed at around 30 minutes, as shown. Potentially due to partial dissolution of non-cross-linked CMC in blood or plasma, the paste gradually lost its mechanical strength. It is observed that the interface of paste with the tissue dissociated, potentially resulting in re-bleeding. Thus, the non-crosslinked CMC hemostatic paste has failed in longer term hemostatic evaluation.

[0114] Referring to FIG. 17, the testing results of the hemostatic paste formulated as described in Example 1, using CMC-CA, is presented (inventive example). The inventive hemostatic paste achieved hemostasis in under 1 minute, as shown, in heparinized liver punch model. After 30 minutes, no re-bleeding was observed. Thus, the instant crosslinked CMC-CA based paste exhibited superior hemostatic properties due to its 3D polymer net structure with better mechanical and dissolution strength compared with pure non-cross-linked CMC.

Example 9. Hemostatic Paste Properties in Animal Model: Hemostasis Data for Cross-Linked Starch Vs. Cross-Linked CMC Based Paste

[0115] The hemostatic paste formulated as described in Example 1 was further evaluated in liver punch model (porcine), comparing the inventive paste formulated with citric acid cross-linked CMC (CMC-CA) and paste with CMC-CA xerogel replaced with the cross-linked starch.

[0116] Referring to FIG. 18, the testing results of the hemostatic paste formulated as described in Example 1, but using CA cross-linked carboxymethyl starch, is presented (comparative example). Citric acid cross-linked carboxymethyl starch paste was applied onto the liver punch model. While it has achieved hemostasis at 1 min, continuing observation for 30 minutes indicated that the comparative paste became dry and began to dissociate with the liver tissue. Further it was shown that it was relatively easy to remove the paste compact from the punch hole with a tweezer. To the contrary, the inventive CMC-CA based paste does not exhibit this dissociation from tissue phenomenon even after 30 min, as shown in FIG. 17. Based on this evaluation, the inventive crosslinked CMC-CA based paste exhibited superior hemostatic properties when compared to cross-linked starch based paste which showed poor tissue adhesion.

Example 10. Hemostatic Paste Adhesion to the Tissue: Comparative Testing

[0117] Referring now to FIG. 19, testing the adhesion to the tissue was further evaluated as follows. The inventive CMC-CA based hemostatic paste and comparative hemostatic pastes were applied onto backing materials, including commercially available Oxidized Regenerated Cellulose (ORC)-based non-woven pad and synthetic polymer polyglactin 910 (copolymer made from 90% glycolide and 10% L-lactide, PG910)-based non-woven pad, as shown. Then the patches were applied to the porcine liver tissue. After a 1 min tamponade by hand, the patches were peeled off from the liver tissue by forceps. The peeling force, which represented the adhesive force of each hydrogel, was evaluated and was ranked from 1 to 5. Referring to Table 6, adhesiveness evaluations are presented, with 5 being most adhesive; 1 being not adhesive, for the inventive CMC-CA based paste, and for comparative pastes based on pregelatinized starch hydrogel and on CMC-CA/pregelatinized starch 1:1 mixture.

TABLE-US-00006 TABLE 6 Tissue adhesiveness evaluation (5-most adhesive; 1-not adhesive) Sample Adhesiveness CMC-CA hydrogel based paste (inventive) 5 Pregelatinized starch hydrogel (comparative) 2 CMC-CA/pregelatinized starch 1:1 3 (comparative)

[0118] Based on this evaluation, the inventive crosslinked CMC-CA based paste exhibited superior hemostatic properties of tissue adhesion when compared to Pregelatinized starch hydrogel based paste and CMC-CA/pregelatinized starch 1:1 based pastes.

Example 11. Hemostatic Paste Properties in Animal Model

[0119] The hemostatic paste formulated as described in Example 1 was further evaluated in liver punch model (porcine). Referring to FIG. 20, inventive CMC-CA based hemostatic paste is shown prior, during application, and after application into liver punch model, as pressed into narrow wound, with the hemostasis achieved within 1 min.

Example 12. Hemostatic Paste on a SubstrateProperties in Animal Model

[0120] The inventive CMC-CA based hemostatic paste was applied onto backing materials comprising a pad or a gauze for applications onto broader areas of tissue to address surface bleeding or oozing. Referring now to FIG. 21 inventive CMC-CA based hemostatic paste is shown applied to commercially available Oxidized Regenerated Cellulose (ORC)-based non-woven pad. Referring now to FIG. 22, the resulting composite is shown prior to being tested for adhesion to a liver tissue coupon, and after contacting with liver tissue coupon.

[0121] Having shown and described various versions in the present disclosure, further adaptations of the methods and systems described herein may be accomplished by appropriate modifications by one of ordinary skill in the art without departing from the scope of the present invention. Several of such potential modifications have been mentioned, and others will be apparent to those skilled in the art. For instance, the examples, versions, geometrics, materials, dimensions, ratios, steps, and the like discussed above are illustrative and are not required. Accordingly, the scope of the present invention should be considered in terms of the following claims and is understood not to be limited to the details of structure and operation shown and described in the specification and drawings.