AU2020202701B2 - Semi-synthetic powder material, obtained by modifying the composition of a natural marine biomaterial, method for producing same, and applications thereof - Google Patents

Semi-synthetic powder material, obtained by modifying the composition of a natural marine biomaterial, method for producing same, and applications thereof Download PDF

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AU2020202701B2
AU2020202701B2 AU2020202701A AU2020202701A AU2020202701B2 AU 2020202701 B2 AU2020202701 B2 AU 2020202701B2 AU 2020202701 A AU2020202701 A AU 2020202701A AU 2020202701 A AU2020202701 A AU 2020202701A AU 2020202701 B2 AU2020202701 B2 AU 2020202701B2
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insoluble
hippopus
notably
biopolymers
calcium carbonate
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Georges Camprasse
Serge Camprasse
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MBP Mauritius Ltd
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    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K35/00Medicinal preparations containing materials or reaction products thereof with undetermined constitution
    • A61K35/56Materials from animals other than mammals
    • A61K35/618Molluscs, e.g. fresh-water molluscs, oysters, clams, squids, octopus, cuttlefish, snails or slugs
    • AHUMAN NECESSITIES
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    • A61L24/00Surgical adhesives or cements; Adhesives for colostomy devices
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Abstract

The invention relates to a pulverulent semisynthetic material, derived from a natural marine biomaterial, namely the aragonitic inner layer of the shell of bivalve molluscs selected from the group comprising Pinctadines, notably Pinctada maxima, margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus porcelanus, in pulverulent form, with addition of insoluble and soluble biopolymers and calcium carbonate transformed by carbonation; it also relates to the method of preparation thereof and to the uses thereof.

Description

SEMI-SYNTHETIC POWDER MATERIAL, OBTAINED BY MODIFYING THE COMPOSITION OF A NATURAL MARINE BIOMATERIAL, METHOD FOR PRODUCING SAME, AND APPLICATIONS THEREOF
Related Applications The present application is a divisional of Australian
Patent Application No. 2016282441, itself a national phase
entry of International Patent Application No.
PCT/FR2016/051497, which claims priority from French Patent
Application No. 1555782, the entire contents of each of
which are incorporated herein by reference.
Field of the invention The present invention relates to a pulverulent
semisynthetic bioabsorbable material, obtained from a
natural marine biomaterial derived from the shell of
bivalve molluscs such as the Pinctadines (oysters) in
general and notably Pinctada maxima, margaritifera, and the
Tridacnes(giant clams): Tridacna gigas, maxima, derasa,
tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus
porcelanus.
Context of the invention
Generally the materials used for filling losses of
bone substance of traumatic, tumoral, dystrophic or
degenerative origin are calcium phosphate cements, bio
copolymers, and materials of animal or human origin.
For sealing prostheses, only polymethylmethacrylate
(PMMA) is used, optionally combined with antibiotics, an
initiator, an activator, an opacifier or a colorant.
Endoprostheses are generally sealed with PMMA cements, the
drawbacks of which are well known, in particular the
exothermic reaction produced during polymerization of the
cement, the resulting osteocyte necrosis, shrinkage of the
cement over time and ageing thereof, which cause mobility of the prosthesis and the need to repeat it within 10 to 15 years after surgery, in most cases.
All these materials are biocompatible, and some of
them, such as the calcium phosphate cements, claim
osteoconduction properties; few are bioactive, the majority
being inert.
The injectable cements consist of a mineral phase and
a liquid phase, which may be phosphoric acid, an aqueous
solution or gel of HPMC, stoichiometric water of 0.1 mole,
sulphuric acid, or citric acid.
The biomaterials, synthetic or of bovine origin, used
as bone substitutes, present essentially osteoconduction
properties and generally are not completely bioabsorbable.
For some of them, notably the polymers, it is found
that there is release of degradation products, which may in
the long term have harmful effects on the surrounding or
systemic diseased tissues. This bioabsorption is patient
dependent.
Moreover, nearly all of the bone substitutes are not
bioactive; this necessitates combining them with collagen
of animal origin, or with other substances which, being
bioabsorbed, induce a major inflammatory reaction in the
recipient, greater than and different from the
physiological reaction.
The major drawback of bone substitutes in the form of
powder or granules is that during use, whether with
autologous blood, saline solution or any other liquid
carrier, they do not form a "coagulum" having adhesive and
plastic properties promoting their cohesion and maintenance
on and in the site.
It is known that human bone consists of 43% of
inorganic components, 32% of organic components and 25%
water. The organic component consists of 90% of collagen
proteins - including 97% of type I, of type III, IV and V collagen - as well as 10% of non-collagen proteins represented by osteocalcin, osteonectin, osteopontin, bone sialoprotein, proteoglycans, fibronectin, growth factors and morphogenic proteins. These non-collagen proteins play an essential role in the processes of osteogenesis and repair of damaged tissues. The inorganic fraction largely consists of hydroxyapatite in the form of crystals of calcium phosphate; this fraction also contains other minerals such as sodium, potassium, copper, zinc, strontium, fluorine, aluminium, and silicon in very small amounts. All these elements play an important role in cellular metabolism as well as in healing and bone regeneration. Investigation of the architecture and composition of the shell of the bivalve molluscs, such as Pinctadines in general and notably Pinctada maxima, margaritifera, and the Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus porcelanus, has shown that it comprises a nacreous inner layer, made up of 3 to 5% of an organic fraction, itself consisting of collagen proteins and non-collagen proteins, essentially insoluble and soluble biopolymers. The nacreous inner layer also contains an inorganic fraction representing 95 to 97%, consisting essentially of calcium carbonate, minerals and metal ions, as well as 3% water. This investigation of the architecture of the shell of the molluscs to which the invention relates also shows that it consists of a calcitic outer layer, structurally different from the aragonitic inner layer, but also containing an organic fraction made up of insoluble and soluble biopolymers. Several publications have demonstrated the osteoinduction and osteoconduction properties of the natural biomaterial derived from the aragonitic layer of the marine molluscs mentioned above.
These properties result from the presence of
biopolymers contained in the organic fraction, in which
structural proteins similar to those that contribute to the
architecture of organs such as the teeth, bones, skin,
muscles, mucosae, etc. have been identified. Functional
proteins similar to those that are involved in metabolic
and biochemical processes (enzymology, immunology, membrane
receptors, signal molecules, etc.) are also present. The
collagens are particularly represented among these
structural proteins: thus, type I, II, III and related
collagens have been identified.
Apart from the free amino acids, the presence of
proteoglycans (carbohydrates bound to small peptides), and
of glycoproteins (association of collagen and
carbohydrates) including glycoproteins of low molecular
weight, generally regarded as growth factors related to
BMP, TNF B, TGF B, PGF, etc., has been identified.
Moreover, it is known that certain non-collagen
molecules have a fundamental role in the physiological
healing process and in cell and tissue regeneration.
The properties of healing, regeneration, angiogenesis
and osteoinduction of the organo-mineral complex of the
inner layer of the shell of the aforementioned molluscs,
properties linked to the presence of these various
collagens and growth factors, have been demonstrated in
vitro and in vivo.
If we compare the physicochemical composition of bone
tissue and that of aragonite of the shells of the molluscs
in question, we note great similarity of the organic
components present at a percentage of 32% in bone tissue
and from 3 to 5% in aragonite. The mineral phases, 43% for
bone, essentially calcium phosphate, represent in aragonite
95 to 97% in the form of calcium carbonate; the proportions
of the other minerals are very similar.
Taking into account the role of the biopolymers contained in the organic fraction of the natural marine biomaterial, the inventors found it pertinent to modify its composition by increasing the proportion of these biopolymers in the composition of a novel semisynthetic hybrid biomaterial. It is known that the organic fraction of the aragonitic inner layer and calcitic outer layer of the shells of the molluscs in question contains soluble, diffusible molecules, having osteogenic properties involved in the mineralization and growth of calcified tissues. The presence of insoluble structural proteins in the peri crystalline and interlamellar envelopes of aragonite has also been demonstrated. Moreover, the molecules contained in the organic fraction of the calcitic outer layer of the shell are similar to those contained in the aragonitic inner layer of the shell of the molluscs to which the invention relates. That is why it seemed pertinent to extract and concentrate not only the organic molecules closely linked to the biocrystals and to the intercrystalline lamellae of which the aragonite of the nacreous tests is constituted, but also those contained in the calcitic outer layer of the shells of the molluscs in question. Extraction of the biopolymers of the organic fractions of the biomaterial has the aim of providing soluble and insoluble molecules. The objective is to be able to increase, by supplementing with extracted insoluble and soluble biopolymers, the organic-inorganic structural ratio, in order to optimize the properties of cell and tissue regeneration, healing, osteoinduction, and angiogenesis of the biomaterial thus obtained. Thus, the present inventors found that it is possible, starting from the shell of a mollusc selected from Tridacna maxima, Tridacna gigas, Tridacna derasa, Tridacna tevaroa, Tridacna squamosa, Tridacna crocea, Hippopus hippopus,
Hippopus porcelanus, Pinctada maxima, Pinctada margaritifera,
and other Pinctadines, to obtain a material that meets these
requirements by adding to it both soluble and insoluble
biopolymers and calcium carbonate transformed by carbonation.
Thus modified, the novel pulverulent semisynthetic
bioabsorbable material according to the invention is intended
for manufacturing, for example, bone substitutes, injectable
cements or cements for sealing endoprostheses, or for making
bioabsorbable osteosynthesis devices and moulded implants.
Thus, according to a first aspect, the invention relates
to a pulverulent semisynthetic material, derived from a natural
marine biomaterial, with addition of insoluble and soluble
biopolymers and calcium carbonate transformed by carbonation.
The invention also relates to a method for preparing this
semisynthetic material.
It also relates to a composition comprising the soluble
and insoluble biopolymers or calcium carbonate transformed by
carbonation employed in the semisynthetic material.
It finally relates to the use of the semisynthetic
material or of the composition for manufacturing for example
bone substitutes, injectable cements or cements for sealing
endoprostheses, or else for making bioabsorbable osteosynthesis
devices and moulded implants.
In one embodiment, the present invention provides a useof
insoluble and soluble biopolymers extracted from the organic
fraction of the aragonitic inner layer and/or of the calcitic
outer layer of the shell of bivalve molluscs selected from the
group comprising Pinctadines, notably Pinctada maxima,
margaritifera, and Tridacnes, notably Tridacna gigas, maxima,
derasa, tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus
porcelanus, as additives of pulverulent composition comprising
calcium salts, natural or synthetic polymers, collagen, mineral
6a structures of bony tissues of human or animal origin, wherein the pulverulent composition is a pulverulent semisynthetic material derived from a natural marine biomaterial, said natural marine biomaterial being the aragonitic inner layer of the shell of bivalve molluscs selected from the group consisting of Pinctadines, notably Pinctada maxima, margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, and Hippopus porcelanus. In another embodiment, the present invention provides insoluble and soluble biopolymers extracted from the organic fraction of the aragonitic inner layer and/or of the calcitic outer layer of the shell of bivalve molluscs selected from the group consisting of Pinctadines, notably Pinctada maxima, margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus and Hippopus porcelanus combined with calcium carbonate transformed by carbonation, for their use for the healing of hard tissues such as bone and cartilage and of soft tissues such as skin, muscles and mucous membranes. In another embodiment, the present invention provides a pulverulent semisynthetic material obtained from a natural marine biomaterial with addition of insoluble and soluble biopolymers extracted from the organic fraction of the aragonitic inner layer and/or of the calcitic outer layer of the shell of bivalve molluscs selected from the group consisting of Pinctadines, notably Pinctada maxima, and margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, and crocea, and Hippopus hippopus and Hippopus porcelanus, and calcium carbonate converted by carbonation, for its use for the healing and regeneration of losses of substance or for the treatment of burns, sores, ulcers and erythematous skin lesions. Detailed description of the invention:
6b According to a first aspect, the invention relates to a
pulverulent semisynthetic material, derived from a natural
marine biomaterial, with addition of insoluble and soluble biopolymers and calcium carbonate transformed by carbonation.
The material according to the invention is derived
from a natural marine biomaterial, namely the aragonitic
inner layer of the shell of bivalve molluscs selected from
the group comprising Pinctadines, notably Pinctada maxima,
margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus
hippopus, Hippopus porcelanus, said aragonitic layer being
in pulverulent form.
The pulverulent semisynthetic material according to
the invention is bioabsorbable.
According to one embodiment, the granulometry is from
5 nm to 100 pm, preferably from 20 nm to 50 pm, even more
preferably from 50 nm to 20 pm.
The soluble and insoluble biopolymers are extracted
from the aragonitic inner layer and/or from the calcitic
outer layer of the shell of the bivalve molluscs selected
from the group comprising Pinctadines, notably Pinctada
maxima, margaritifera, and Tridacnes, notably Tridacna
gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus
hippopus, Hippopus porcelanus.
A method for extracting these polymers is described
hereunder.
According to a particular embodiment, the extracted
soluble biopolymers and insoluble biopolymers are added in
a ratio of soluble biopolymers to insoluble biopolymers
corresponding to that existing in the starting biomaterial.
The calcium carbonate transformed by carbonation
employed in the semisynthetic material of the invention is
derived from a natural terrestrial, natural marine or
precipitated calcium carbonate, or from the inorganic
fraction of the aragonitic layer after extraction of the
insoluble and soluble biopolymers, which was transformed by carbonation. It is known that calcium carbonate, crystallized in the orthorhombic or rhombohedral system, when submitted to thermal treatment between 800 and 1100°C, presents, through thermolysis and oxidation, new properties that are reflected in considerable adhesive power and plasticity that allows easy modelling. This phenomenon is carbonation, according to the following reaction: CaC03 + thermal treatment 4 Ca (OH)2 + C02 4 CaC03 + H2 0 In this reaction, during which the temperature rises and is maintained for a time from 20 to 40 min, the calcium carbonate is transformed chemically into lime, then under the action of the C02 and ambient moisture it becomes amorphous calcium carbonate. This chemical transformation takes place over several days, depending on the ambient hygrometry. Thus, the pulverulent semisynthetic material according to the invention comprises a powder derived from a natural marine material whose organic fraction is supplemented with extracted insoluble and soluble biopolymers, and the mineral fraction is supplemented with calcium carbonate of sedimentary or madrepore marine origin, or of sedimentary or precipitated terrestrial origin, transformed by a carbonation process. According to a particular embodiment, the pulverulent semisynthetic material according to the invention comprises aragonite in pulverulent form with a granulometry from 5 nm to 100 pm, preferably from 20 nm to 50 pm, even more preferably from 50 nm to 20 pm, insoluble and soluble extracted biopolymers, and calcium carbonate transformed by carbonation. By adding the insoluble and soluble extracted biopolymers, the proportion of the organic fraction of the initial material is increased in a range between 1% and 10%, preferably respecting the proportions between insoluble biopolymers and soluble biopolymers existing in the starting material. By adding calcium carbonate transformed by carbonation, the proportion of the mineral fraction of the initial material is increased in a range between 1% and 10%, depending on the desired physicochemical characteristics. According to a particular embodiment, the semisynthetic material according to the invention comprises: for 100 g of aragonite in pulverulent form with a granulometry from 5 nm to 100 pm, preferably from 20 nm to 50 pm, even more preferably from 50 nm to 20 pm; from 1 g to 50 g, preferably from 5 g to 25 g, even more preferably from 10 g to 15 g of insoluble and soluble extracted biopolymers; and from 0.5 g to 50 g, preferably from 1 g to 25 g, even more preferably from 2 g to 10 g of calcium carbonate transformed by carbonation. During extraction of the biopolymers, the inventors demonstrated that in the aragonitic inner layer and calcitic outer layer of the molluscs used for carrying out the invention, the proportion of the insoluble biopolymers represents from 2.6% to 4.3% and that of the soluble biopolymers from 0.4% to 0.7% of the total weight. Biopolymers are added to the material according to the invention in such a way that the ratio of soluble biopolymers to insoluble biopolymers is similar to the ratio in the original natural product. The invention also relates to a method for preparing a pulverulent semisynthetic material, as described above. According to the method of the invention, the constituent elements are prepared separately and then mixed so as to obtain the material according to the invention. Thus, the pulverulent material derived from a natural marine biomaterial, the insoluble and soluble biopolymers extracted from a natural marine biomaterial and the calcium carbonate transformed by carbonation are prepared.
More particularly, the method of preparation
comprises mixing a ground natural biomaterial, insoluble
and soluble polymers extracted from the aragonitic inner
layer and/or from the calcitic outer layer of the shell of
the bivalve molluscs selected from the group comprising
Pinctadines, notably Pinctada maxima, margaritifera, and
Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa,
squamosa, crocea, Hippopus hippopus, Hippopus porcelanus
and calcium carbonate transformed by carbonation.
In a particular embodiment, the ground natural
biomaterial is the aragonitic inner layer of the shell of
the molluscs. Grinding is carried out so as to obtain an
average granulometry from 20nm to 50pm. The grains obtained
may be spheronized to improve the flowability and
compressibility of the powder.
In the method according to the invention, the
insoluble and soluble biopolymers are extracted
respectively by supercentrifugation and by tangential
ultrafiltration coupled to reverse osmosis after
hydrolysis. Before extraction, the aragonitic inner layer
and/or the calcitic outer layer of the shell of the
molluscs may be crosslinked. To facilitate extraction, the
aragonitic inner layer and/or the calcitic outer layer of
the shell of the molluscs is(are) ground and sieved to a
granulometry between 250 pm and 50 pm.
These various steps are described successively
hereunder.
The natural marine biomaterial used as raw material
is selected from the group comprising Pinctadines, notably
Pinctada maxima, margaritifera, and Tridacnes, notably
Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea,
Hippopus hippopus, Hippopus porcelanus.
Each of the components may be derived from the same
marine biomaterial or from different marine biomaterials.
The shells selected are cleaned, decontaminated,
optionally crosslinked, and the calcitic layer is separated
from the inner layer. The inner layer is ground. A portion
of the ground inner layer constitutes the base component of
the material according to the invention. The soluble and
insoluble biopolymers are extracted from the calcitic layer
and/or from the inner layer. The calcium carbonate, which
may be derived from the mineral portion recovered after
extraction of the biopolymers, is transformed by
carbonation. The biopolymers thus extracted and the calcium
carbonate transformed by carbonation are added to the base
component previously obtained.
A specific embodiment of the method according to the
invention is described in detail hereunder. Of course, a
person skilled in the art will be able to adapt the
conditions of this method to the specific starting
biomaterials and to the desired end uses.
I. PREPARATION OF THE COMPONENTS:
After removing the epibiont by scraping, the shells
obtained from the selected marine biomaterial undergo the
following treatments:
I.1) Decontamination of the shells:
The shells are decontaminated by immersing in a bath
of mains water to which a solution of hypochlorite at 2% of
active chlorine is added.
1.2) Ultrasonic treatment of the shells:
The shells are then rinsed and treated with
ultrasound in a tank filled with microbiologically
inspected mains water, for example at a temperature of
550C, to which a cleaning and disinfecting solution is
added at a dilution of 1 part of solution to 127 parts of
water. The treatment time is about 30 min at a frequency of
about 40 kHz.
1.3) Rinsing and drying the shells:
The shells are then rinsed for example for 20 min in
a bath of demineralized water at a temperature of 90°C, to
which Calbenium@ is added at a dilution of 2%, for 30 min.
They are then dried.
1.4) Crosslinking of the shells:
According to another embodiment, in order to endow
the biomaterial of natural origin with enhanced biological
properties, notably in view of the optimization of cellular
metabolism and the reinforcement of the anti-radical
properties, the shells may be crosslinked as follows:
In a translucent glass or plastic container of
variable capacity, a mixture of mains water with addition
of 10% riboflavin is prepared; the whole is maintained at a
temperature above 200C, and stirring of the mixture
generates a flow perpendicular to the UVA radiation.
The shells are placed therein vertically and are
submitted on both sides to irradiation from UVA lamps with
a wavelength of 365 nanometres/second, at an intensity of
2300 microjoules per square centimetre for 180 min. The
whole is kept under vacuum throughout the treatment.
The shells are then rinsed and dried in a stream of
hot air at 40°C.
It is also possible to use the method described in
patent application FR 14 50204 filed on 10 January 2014.
1.5) Removal of the calcitic outer layer: The calcitic outer layer of the shells is removed by grinding, with a fine-grain grinding wheel. The product is put to one side and constitutes the "Batch for extraction of the biopolymers from the calcitic outer layer".
1.6) Freezing of the nacreous tests exposed after grinding: According to the invention, the nacreous tests are frozen at a temperature of -18°C for 120 min.
1.7) Crushing of the nacreous tests and recovery of the batches: Then crushing of the nacreous tests is carried out for example in a crusher with tungsten carbide jaws, with aspiration, so as to recover the suspended particles, which also contain nano-grains. The crushing operation is repeated at least 3 times, and 2 batches are set aside after sieving: - The first with a random granulometry from 20 microns to 50 nanometres will constitute the aragonite mixed portion of the product according to the invention, called "aragonite mixed batch" hereinafter. "Aragonite mixed batch" means the pulverulent form obtained after grinding, comprising the two organic and inorganic components. - The second batch with a granulometry from 250 to 50 microns is put to one side for extraction of the insoluble and soluble biopolymers. It will be called "batch for extraction of the biopolymers from the aragonitic inner layer". A laser granulometer will be used for determining the grain size and size range of the powders obtained.
1.8) Spherification of the aragonite mixed batch:
The aragonite mixed batch undergoes mechanical
treatment intended to make the grains uniform by spherification, the aim being to round off the corners and
edges of the grains by attrition.
This treatment has the effect of promoting the
flowability and compressibility of the powder obtained and
thus promote densification and inter-particle bonds when
using the material according to the invention, notably as
bone substitutes, sealing cements, injectable cements,
bioabsorbable osteosynthesis devices and moulded implants.
The following procedure may be adopted for this
spherification step: A mixture of equal parts of
pulverulent material from the aragonite mixed batch and
chips of some mm 2 of hard wood, for example oak, sterilized
in an autoclave, is put in a cylindrical container made of
glass or zirconium for example, with horizon tal rotation
axis, which has glass blades of variable width.
The container is rotated for a variable time and at a
variable speed, depending on the size of the container and
the amount of product to be treated.
At the end of the spherification treatment, the whole
mixture, aragonite mixed batch and chips, is recovered in
an inert container filled with a sufficient amount of
water, which is stirred continuously for about 15 min.
After resting, the wood chips floating on the surface are
removed by suction.
The solution is then filtered on a nylon filter with
mesh with a diameter of 20 microns, then the residue is
dried in the Rotavapor® at 400C and packaged.
According to another embodiment, equal parts of
sodium chloride in the form of grains with random diameters
ranging from 1 to 3 mm may also be added to the aragonite mixed batch. After treatment, the sodium chloride is removed by dissolving with hot water at 900C and filtering on a nylon filter, followed by washing with hot water at 900C and drying in a stream of hot air at 40°C.
II. EXTRACTION OF THE BIOPOLYMERS II.1 Extraction of the insoluble biopolymers: According to the invention, a suitable amount of powder from the batch for extraction of the biopolymers from the aragonitic inner layer obtained in step 1.5) is mixed with a sufficient amount of demineralized water, to be injected into a hydrolysis reactor, to which a defined amount of 25% citric acid is added; the whole is cooled at a temperature fluctuating between 4 and 5°C, stirring continuously. The inventors favoured the use of citric acid owing to its properties of lowering the pH and surface tension. The pH, monitored with a pH-meter, is maintained above 4.5 by adding 2.5 N sodium hydroxide to prevent degradation of the biopolymers; it is then brought back to 7 at the end of the step by adding 0.1 litre of 5N sodium hydroxide per 100 litres of hydrolysate. Once the powder has dissolved completely, the hydrolysate is transferred to a storage tank, still stirring continuously, and is then transferred to a centrifugal separator, where it is subjected to a force of from 18 to 20 000G in the cyclone. The operation is repeated if necessary after checking the solution by turbidimetry and correcting with citric acid if necessary, while maintaining the temperature between 4 and 5°C.
Depending on the results from turbidimetry, the hydrolysate may undergo supercentrifugation again.
At each cycle of supercentrifugation, the residue of the insoluble biopolymers collected is washed and set aside. The water from washing the residues is treated with oxalic acid to check for presence or absence of calcium. At the end of the last supercentrifugation, a residue is therefore obtained containing all the insoluble biopolymers, in the form of a wet brownish cake, which is dried by lyophilization, or Zeodratation (hydration using zeolites); at the end of treatment we have grey spherules with diameter from 2 to 3 mm, resulting from the coiling of the proteins under the action of the centrifugal force. The insoluble biopolymers extracted are ground for example in a planetary mill until a powder is obtained with a random granulometry from 5 microns to 100 nanometres, recovered after sieving.
11.2 Extraction of the soluble biopolymers: The permeate and the wash water are sent for desalting in a tangential ultrafiltration device, for example with cassettes having a cut-off point of lkD. A sufficient amount of sulphuric acid at 2.0 mol/L is added to the permeate, in order to cause precipitation of the calcium sulphate salts. The solution is filtered, and the permeate is concentrated in the Rotavapor® under vacuum at a boiling point of 330C in order to remove the citric acid in the form of crystals. The distillate containing the low molecular weight proteins as well as the mono- and multivalent ions is extended. As the cut-off point of the cassettes does not retain all of the proteins and notably those of very low molecular weight, the distillate is submitted to reverse osmosis.
The distillate is transferred to undergo a liquid
phase separation treatment by permeation through semi
selective membranes for example with a pore diameter of
0.0001 micron, under the effect of a pressure gradient from
40 to 80 bar.
The distillate is passed so as to retain all the
mono- and multivalent ions such as iron, magnesium, zinc,
etc.
The retentate recovered on the reverse osmosis
membranes is collected and extended with apyrogenic water,
then concentrated for example in the Rotavapor®, under
vacuum, at a temperature of 400C, and then lyophilized by
Zeodratation or cryodessication.
A very fine greyish-white powder is obtained, which
is put to one side, and then ground for example in a
planetary mill to obtain, after sieving, a powder with
random granulometry ranging from 5 microns to 100
nanometres.
The permeate is checked for presence or absence of
proteins by taking an aliquot of solution, which is treated
by Bradford's colorimetric method.
11.3 Extraction of the biopolymers from the batch for
extraction of biopolymers from the calcitic outer layer
According to another embodiment, extraction of the
biopolymers from the calcitic outer layer is carried out
identically to that of the biopolymers from the aragonitic
inner layer.
III. CARBONATION OF CALCIUM CARBONATE:
It is known that calcium carbonate, crystallized in
the orthorhombic or rhombohedral system, when submitted to
thermal treatment between 800 and 1100°C, presents novel
properties through thermolysis and oxidation, which are reflected in considerable adhesive power and plasticity that allows easy modelling. This phenomenon is carbonation, according to the following reaction: CaCO3 + thermal treatment 4 Ca (OH)2 + C02 4 CaCO3 + H 2 0
In this reaction, during which the temperature rises and is maintained for a time of from 20 to 40 min, the calcium carbonate is transformed chemically, becoming lime, and then under the action of the C02 and ambient moisture, it becomes amorphous calcium carbonate. This chemical transformation takes place over several days, depending on the ambient hygrometry. According to other embodiments, all the calcium salts, other than calcium carbonate, may, by chemical reactions of precipitation, give rise to calcium carbonate, which can be transformed by carbonation. Thus, it is possible, for example, to obtain carbonated calcium carbonate starting from calcium hydroxide, calcium acetate, calcium oxalate, calcium sulphate, or calcium citrate; it is within the skill set of a person skilled in the art to carry out the known chemical processes for these precipitations. The calcium carbonate may also come from the aragonitic inner shell of the bivalve molluscs such as the Pinctadines in general and notably Pinctada maxima, margaritifera, and the Tridacnes, Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus porcelanus, after extraction of the biopolymers. It may also be of madrepore origin.
IV. FORMULATION OF A MIXTURE STARTING FROM THE ARAGONITE MIXED BATCH, THE INSOLUBLE AND SOLUBLE EXTRACTED BIOPOLYMERS, AND CALCIUM CARBONATE TRANSFORMED BY CARBONATION
An amount of the insoluble and soluble biopolymers, extracted from two inner aragonite and outer calcite batches, determined according to the desired proportion of organic fraction, and a determined amount of calcium carbonate transformed by carbonation, are mixed with a defined amount of the aragonite mixed batch to constitute a formulation of the product according to the invention. Mixing is carried out for example in a knife mixer until a homogeneous powder is obtained, which is then packaged.
According to another aspect, the invention relates to the use of the material according to the invention as bone substitute for extemporaneous formulation, for healing and regeneration of losses of substance, for treating burns, sores, ulcers, erythematous skin lesions or in the manufacture of devices or moulded implants. The pulverulent semisynthetic material according to the invention may also be used in the manufacture of devices or moulded implants with controlled bioabsorption comprising suture threads with bioabsorption staggered over time. It may also be used for formulating preparations for bone substitutes for extemporaneous use, bone substitutes with porous collagen support, bone substitutes with a mineral structure of animal or human origin, bioabsorbable osteosynthesis devices and moulded implants, devices with controlled bioabsorption, cements for sealing endoprostheses, injectable cements for minimally invasive surgery in vertebroplasty, kyphoplasty and bone tumour surgery. According to another embodiment, the product according to the invention may be combined with a porous collagen support such as Spongia officinalis that has undergone mechanical and thermochemical treatment intended for bacterial and viral decontamination, for removal of any pigments, and for neutralizing immunogenicity. It is known that Spongia officinalis is made up of spongin, consisting in its turn of fibres of a carbonated scleroprotein related to collagen. This protein is of low solubility and plays a role of protection and support of all tissues: connective tissue, tendons, bone tissues, muscle fibres, skin, hair and nails. Spongin is a structural and storage collagen protein; it is inert, water-insoluble, hydrophobic and is not easily denatured. It constitutes a porous support, suitable for osteoconduction. It may therefore be used in combination with the material according to the invention for making bone substitutes.
The material according to the invention may be
combined with calcium salts such as dehydrated or hemi
hydrated calcium sulphate, calcite, anhydrous calcium
hydroxyphosphate, @-TCP, and calcium hydroxide. The
material according to the invention may be combined with
mineral structures of bone tissues of animal or human
origin.
It may also be combined with bioabsorbable polymers
such as collagen, hyaluronic acid, chitosan, starch,
alginate or with absorbable synthetic polymers such as
polyglycolide, poly(DL-lactide-co-glycolide), poly(L
lactide) or with acrylic polymers such as polyhydroxyethyl,
methylmethacrylate, polymethylmethacrylate, as well as with
medicinal substances in pulverulent form, such as non
steroidal anti-inflammatory drugs, antibiotics,
antimitotics or any other substance with a therapeutic
objective.
Taking into account the drawbacks connected with the
use of methylmethacrylate sealing cements, the inventors
propose sealing cements manufactured with the product according to the invention, which, being naturally radiopaque, performs mechanical primary retention of the endoprosthesis on account of its adhesive properties, leading secondly to tissue integration by reason of its osteomimetic, osteoinductive, osteoconductive, and bioactive properties, induced by the presence of signal molecules, initiators of biomineralization.
These signal molecules stimulate the local endogenous
factors of biomineralization in situ, leading to the
formation of metaplastic bone.
According to another aim, the invention relates to
the use of calcium carbonate that has undergone carbonation
as employed in the material according to the invention or
as prepared according to step III of the method described
above in compositions comprising calcium salts, natural or
synthetic polymers, collagen, mineral structures of bone
tissues of animal or human origin.
It may also be combined with bioabsorbable polymers such as
collagen, hyaluronic acid, chitosan, starch, alginate or
with absorbable synthetic polymers such as polyglycolide,
poly(DL-lactide-co-glycolide), poly(L-lactide) or with
acrylic polymers such as polyhydroxyethyl,
methylmethacrylate, polymethylmethacrylate, as well as with
medicinal substances in pulverulent form, such as non
steroidal anti-inflammatory drugs, antibiotics,
antimitotics or any other substance with a therapeutic
objective.
It is known that the insoluble and soluble
biopolymers contained in the organic fraction of the
aragonitic and calcitic layers have healing and
regeneration properties, both of hard tissues such as bone
and cartilage, and soft tissues such as the skin, muscles
and mucosae. Certain of these non-collagen biopolymers,
notably the low molecular weight glycoproteins, may be likened to growth factors such as BMP, TNFB, EGPF, TGFB,
IGF, FGF, etc., as well as cytokines, mediators of
inflammation.
The invention also relates to the use of the soluble
and insoluble biopolymers employed in the material
according to the invention or as extracted by step II of
the method described above as additives for pulverulent
compositions comprising calcium salts, natural or synthetic
polymers, collagen, mineral structures of bone tissues of
animal or human origin. They may also be combined with
bioabsorbable polymers such as collagen, hyaluronic acid,
chitosan, starch, alginate or with absorbable synthetic
polymers such as polyglycolide, poly(DL-lactide-co
glycolide), poly(L-lactide) or with acrylic polymers such
as polyhydroxyethyl, methylmethacrylate,
polymethylmethacrylate, as well as with medicinal
substances in pulverulent form, such as non-steroidal anti
inflammatory drugs, antibiotics, antimitotics or any other
substance with a therapeutic objective. They may also be
combined with calcium carbonate transformed by carbonation.
The invention will be described in more detail with
the aid of the following examples, given purely for
illustration, and the appended drawings, where:
Fig. 1 and Fig. 2 are photographs of mixtures:
- of powder of nacre and calcium carbonate with whole
blood (No. 1) and
- of powder of nacre and calcium carbonate that has
undergone carbonation with whole blood (No. 2)
taken respectively 2 min and then 15 min after adding the
whole blood.
EXAMPLES:
In order to verify the pharmacological properties of
the product according to the invention, the inventors formulated preparations with a therapeutic objective and used them for recording clinical observations.
EXAMPLE 1:
The pulverulent semisynthetic material according to
the invention was prepared as follows:
I. PREPARATION OF THE COMPONENTS:
After removing the epibiont by scraping, the shells
undergo the following treatments:
I.1) Decontamination of the shells: The shells are decontaminated by immersing in a bath
of mains water to which a solution of hypochlorite at 2% of
active chlorine has been added.
1.2) Ultrasonic treatment of the shells: The shells are then rinsed and treated with
ultrasound in a tank filled with microbiologically
inspected mains water, at a temperature of 550C, to which a
cleaning and disinfecting solution is added at a dilution
of 1 part of solution to 127 parts of water. The treatment
time is 30 min at a frequency of 40 kHz.
1.3) Rinsing and drying of the shells: The shells are then rinsed for 20 min in a bath of
demineralized water at a temperature of 90°C, with
Calbenium@ added at a dilution of 2%, for 30 min. They are
then rinsed and dried.
1.4) Removal of the calcitic outer layer: The calcitic outer layer of the shells is removed by
grinding, with a fine-grain grinding wheel.
The product is put to one side and constitutes the "Batch
for extraction of the biopolymers from the calcitic outer
layer".
1.5) Freezing of the nacreous tests exposed after grinding:
The nacreous tests obtained in step 1.4) are frozen
at a temperature of -18°C for 120 min.
1.6) Crushing of the nacreous tests and recovery of the batches: Then the nacreous tests are crushed in a crusher with
tungsten carbide jaws, of the ESSA@ type, with aspiration,
so as to recover the suspended particles, also containing
nano-grains.
The crushing operation is repeated at least 3 times
and 2 batches are put aside after sieving:
- The first with a random granulometry from 20 microns to
50 nanometres will constitute the aragonite mixed portion
of the product according to the invention called "aragonite
mixed batch" hereinafter. "Aragonite mixed batch" means the
pulverulent form obtained after grinding, comprising the
two organic and inorganic components. - The second batch with a granulometry from 250 to 50
microns is put to one side for extraction of the insoluble
and soluble biopolymers. It will be called "batch for
extraction of the biopolymers from the aragonite inner
layer".
The grain size and range of the powders obtained are
determined using a laser granulometer.
1.7) Spherification of the aragonite mixed batch: The aragonite mixed batch undergoes mechanical
treatment that is intended to make the grains uniform by
spherification, the aim being to round off the corners and
edges of the grains by attrition.
A mixture of equal parts of pulverulent material from
the aragonite mixed batch and 5 mm 2 chips of hard wood, for
example oak, sterilized in the autoclave, is put in a cylindrical container made of zirconium, with horizontal rotation axis, which has glass blades of variable width.
The container is rotated for a variable time and at a
variable speed, depending on the size of the container and
the amount of product to be treated.
At the end of the spherification treatment, the whole
mixture, aragonite mixed batch and chips, is recovered in
an inert container filled with a sufficient amount of
water, which is stirred continuously for 15 min. After a
30 min rest, the wood chips floating on the surface are
removed by suction.
The solution is then filtered on a nylon filter with
mesh having a diameter of 20 microns, then the residue is
dried in the Rotavapor® at 400C and packaged.
II. EXTRACTION OF THE BIOPOLYMERS
II.1 Extraction of the insoluble biopolymers: A suitable amount of powder from the batch for
extraction of the biopolymers from the aragonitic inner
layer is mixed, by aspiration in the feed tank in Zone I,
with a sufficient amount of demineralized water, to be
injected in Zone II into the hydrolysis reactor, to which a
defined amount of 25% citric acid is added; the whole is
cooled at a temperature fluctuating between 4 and 5°C,
stirring continuously. The pH, monitored with a pH-meter,
is maintained above 4.5 by adding 2.5 N sodium hydroxide to
prevent degradation of the biopolymers; it is then brought
back to 7 at the end of the step by adding 0.1 litre of 5N
sodium hydroxide per 100 litres of hydrolysate.
Once the powder has dissolved completely, the
hydrolysate is transferred to the storage tank, still
stirring continuously, then transferred to the centrifugal
separator, where it is submitted to a force from 18 to
20 000G in the cyclone.
The operation is repeated if necessary after checking
the solution by turbidimetry and correcting with citric
acid if necessary, the temperature being maintained between
4 and 5°C.
Depending on the results supplied by turbidimetry,
the hydrolysate undergoes supercentrifugation again.
In each cycle of supercentrifugation, the residue of
the insoluble biopolymers collected is washed and set
aside. The water from washing the residues is treated with
oxalic acid to check for presence or absence of calcium.
At the end of the last supercentrifugation, a residue
is therefore obtained containing all the insoluble
biopolymers, in the form of a wet brownish cake, which is
dried by lyophilization, and at the end of treatment we
have grey spherules with a diameter from 2 to 3 mm,
resulting from the coiling of the proteins under the action
of the centrifugal force.
The insoluble biopolymers extracted are ground in a
planetary mill until a powder is obtained with a random
granulometry from 5 microns to 100 nanometres, which is
recovered after sieving.
11.2 Extraction of the soluble biopolymers: The permeate and the wash water are sent for
desalting in the device for assembly of the tangential
ultrafiltration cassettes, Millipore@ of 1 kDa each,
mounted in series to give a surface area of 15 M2 , at a
pressure of 5 bar and a flow rate from 10 to 15 litres per
hour, at a temperature of 40°C.
A sufficient amount of sulphuric acid at 2.0 mol/L is
added to the permeate, to cause precipitation of the
calcium sulphate salts.
The solution is filtered, the permeate is concentrated in
the Rotavapor® under vacuum at a boiling point of 330C in
order to remove the citric acid in the form of crystals.
The distillate containing the low molecular weight
proteins as well as the mono- and multivalent ions is
extended.
As the cut-off point of the cassettes does not retain
all of the proteins and notably those of very low molecular
weight, the distillate is submitted to reverse osmosis.
The distillate is then transferred to undergo a
liquid-phase separation treatment by permeation through
semi-selective membranes with membrane pore diameter of
0.0001 micron, under the effect of a pressure gradient from
40 to 80 bar.
The distillate is passed in order to retain all the
mono- and multivalent ions such as iron, magnesium, zinc,
etc.
The retentate recovered on the reverse osmosis membranes is
collected and extended with apyrogenic water, then
concentrated in the Rotavapor®, under vacuum, at a
temperature of 40°C, and then lyophilized by Zeodratation.
A very fine greyish-white powder is obtained, which
is put to one side, and is then ground in a planetary mill,
obtaining, after sieving, a powder with random granulometry
ranging from 5 microns to 100 nanometres.
Presence or absence of proteins in the permeate is
checked by taking an aliquot of solution, which is treated
by Bradford's colorimetric method.
III. CARBONATION OF THE CALCIUM CARBONATE:
The calcium carbonate recovered after extraction of
the above biopolymers is submitted to thermal treatment
between 800 and 11000C, lasting 20 to 40 min, then cooled slowly in the open air. This phenomenon is carbonation, according to the following reaction:
CaC03 + thermal treatment 4 Ca (OH)2 + C02 4 CaC03 + H2 0 In this reaction, the calcium carbonate is
transformed chemically, becoming lime, and then under the
action of C02 and humidity it becomes amorphous calcium
carbonate again. This chemical transformation takes place
over several days, depending on the ambient hygrometry.
IV. FORMULATION OF A MIXTURE STARTING FROM THE ARAGONITE MIXED BATCH, THE INSOLUBLE AND SOLUBLE EXTRACTED BIOPOLYMERS, AND THE CALCIUM CARBONATE TRANSFORMED BY CARBONATION
During extraction of the biopolymers, it was
demonstrated that in the aragonitic inner layer and the
calcitic outer layer of the shells used, the proportion of
the insoluble biopolymers represented from 2.6% to 4.3% and
that of the soluble biopolymers represented from 0.4% to
0.7%.
The material according to the invention was prepared
by mixing the aragonite mixed batch, insoluble polymers
obtained in step II.1, soluble polymers obtained in step
11.2 and calcium carbonate that has undergone carbonation
obtained in step III above. The specific amounts of the
various components are specified in each of the embodiment
examples given below.
Mixing is carried out in a knife mixer until a
homogeneous powder is obtained, which is then packaged.
EXAMPLE 2:
The procedure of example 1 above is followed, except
that a crosslinking step as described below is added at the
end of step 1.3.
A mixture of mains water with 10% riboflavin added is
prepared in a translucent glass or plastic container; the
whole is maintained at a temperature above 200C, and
stirring of the mixture generates a flow perpendicular to
the UVA radiation.
The shells are placed vertically therein and are subjected
on both sides to irradiation with UVA lamps with a
wavelength of 365 nanometres/second, at an intensity of
2300 microjoules per square centimetre for 180 min. The
whole is kept under vacuum throughout the treatment.
The shells are then rinsed and dried in a stream of
hot air at 40°C.
EXAMPLE 3:
The properties of adhesiveness and cohesion of the
carbonated calcium carbonate are verified as follows:
To two Dappen cups, designated Dappen No. 1 and No. 2
respectively, each containing 1 g of the powdered nacre
obtained at the end of step 1.7 of the procedure in example
1, the following are added:
- 0.lg of natural calcium carbonate (Dappen No. 1),
- 0.lg of natural calcium carbonate that has undergone
carbonation, obtained from step III of the procedure
of example 1 (Dappen No. 2).
After mixing, the contents of each Dappen cup are
mixed with 2 cc of whole blood.
A photograph of each Dappen cup is taken 2 minutes
(Fig. 1) and then 15 minutes (Fig. 2) after mixing with
whole blood.
As illustrated in Fig. 1(1), the mixture in Dappen
No. 1 remains in the form of a red powder; no coagulum has
formed. After 15 minutes, no coagulum has formed (Fig.
2(1)).
As illustrated in Fig. 1(2), the mixture in Dappen No. 2 quickly forms a coagulum and gradually changes colour from red to brown, it cakes, can be modelled, becomes sticky and hardens after 15 minutes (Fig. 2(2)).
EXAMPLE 4: Formulation for extemporaneous bone substitute A critical clinical case was an oblique fracture of the cannon of a 1-year-old filly, treated by osteosynthesis. After osteosynthesis failed, reflected in breakage of 4 screws, pseudarthrosis with sepsis, followed by a comminuted secondary fracture with small fragments, leaving euthanasia of the animal as the only alternative, it was decided to use the material according to the invention with the following formulation:
• 40 g of aragonite mixed batch with a granulometry from 50 nanometres to 20 microns, resulting from step 1.8 of example 1; • 0.070 g of insoluble extracted biopolymers obtained in step 11.2 of example 1;
• 0.010 g of soluble extracted biopolymers obtained in step II.1 of example 1; • 2 g of carbonated calcium carbonate resulting from step III of the procedure of example 1; • 10 ml of autologous venous blood to form a coagulum, modelled into the shape of a cylinder with length of 10 cm and diameter of 2 cm, placed in the loss of substance after ablation of the bone sequestra.
The limb, protected with compresses, was put in plaster. Post-operative radiography showed the presence and adhesion of the bone substitute according to the invention, then consolidation at 4 months, after which the filly was able to gallop and jump obstacles. Later X-rays showed complete restoration of the bone shaft with reconstruction of the medullary canal. The same formulation was also used, making a coagulum extemporaneously with 2.5 ml of water for injection (WFI) at room temperature.
EXAMPLE 5: Formulation of a skin healing cream A preparation of the product according to the invention was made with the following percentage formulation:
• 10 g of aragonite mixed batch with a granulometry from 50 nanometres to 20 microns obtained according to example 2; • 0.035 g of insoluble extracted biopolymers obtained in step 11.2 of example 1;
• 0.005 g of soluble extracted biopolymers obtained in step II.1 of example 1;
• 0.5 g of carbonated calcium carbonate;
• 15 drops of a complex of essential oils comprising, for 100 ml: Lavandula spica: 1 ml Salvia officinalis: 2 ml Rosa rubiginosa: 10 ml Helichrysum italicum: 1.5 ml Wheatgerm vegetable oil: 50 ml Evening primrose oil: 10 ml Sweet almond oil: 20 ml O/W Emulsion, q.s. 100 g
This preparation was applied on a cutaneous necrosis of the sternal plastron of a horse, from the base of the neck to the stifles, to a height of 32 cm and a width of 18 cm. Clinical observation showed exceptional healing of 1 cm per day in height and in width with reconstruction of the various aponeurotic, subcutaneous and cutaneous planes, and simultaneous regrowth of the hair without discoloration, with complete healing of the integuments in
28 days.
EXAMPLE 6: Formulation for a dermatological preparation for treating psoriasis As is well known, psoriasis is an inflammatory
disorder of the skin, characterized by accelerated cell
renewal, without apoptosis, which leads to the formation of
thick crusts as plaques. Apart from corticosteroid therapy
and local treatments based on coal tar and PUVA therapy,
the results of which are variable and disappointing, there
are more drastic treatments with dangerous side-effects for
the patient.
A preparation of the product according to the
invention is made according to the following percentage
formulation:
• 3 g of insoluble extracted biopolymers obtained in
step 11.2 of example 1;
• 0.45 g of soluble extracted biopolymers obtained in
step II.1 of example 1;
• 0.5 g of carbonated calcium carbonate obtained in step
III of example 1;
• 10 drops of a complex of essential oils containing, for 100 ml:
Lavandula spica: 1 ml
Salvia officinalis: 2 ml
Rosa rubiginosa: 10 ml
Helichrysum italicum: 1.5 ml
Wheatgerm vegetable oil: 50 ml
Evening primrose oil: 10 ml
Sweet almond oil: 20 ml
O/W Emulsion, q.s. 100 g
This emulsion is applied daily on the lesions of severe psoriasis at the level of the torso, back, arms and legs. After the third application, disappearance of the redness is observed, indicating relief of the inflammatory phenomenon, skin flakes, and relief of pruritus and superimposed infections with a notable improvement in appearance. Improvement of the clinical signs reflects the eutrophic, antiphlogistic and regenerative properties of the insoluble and soluble biopolymers.
EXAMPLE 7: Formulation of a skin dressing for burns The exceptional properties of soft tissue regeneration of the insoluble and soluble biopolymers extracted according to step II of example 1 were demonstrated in a case of deep second-degree and third degree burns after failure of keratinocyte grafts, with the following formulation:
For 100 g: • 50 g of aragonite mixed batch with a granulometry from 50 nanometres to 20 microns obtained according to example 2; • 0.174 g of insoluble extracted biopolymers obtained in step 11.2 of example 1; • 0.026 g of soluble extracted biopolymers obtained in step II.1 of example 1; • C6rat de Galien (Galen's Wax) with cherry laurel water q.s. 100 g.
The preparation is applied on all of the burned areas under an occlusive dressing, and this is repeated every 72 hours.
Repeated clinical examinations have shown relief of
the exudative phenomenon, significant angiogenesis, pain
relief, re-epithelialization of the areas impregnated of
blood and a notable decrease in fibroplastic strain.
EXAMPLE 8: Formulation for bioabsorbable moulded bone substitute
The material according to the invention can be used
for making bioabsorbable osteosynthesis devices and moulded
implants.
According to the invention, the following is
prepared, for 100 g:
• 80 g of aragonite mixed batch with a granulometry from
50 nanometres to 20 microns obtained in step 1.8 of
example 1;
• 0.139 g of insoluble extracted biopolymers obtained in
step 11.2 of example 1;
• 0.021 g of soluble extracted biopolymers obtained in
step II.1 of example 1;
• 20 g of macrogol 400;
• 4 g of carbonated calcium carbonate obtained in step
III of example 1.
The whole is mixed in a mixer for 10 min at room
temperature until a homogeneous plastic paste is obtained
that is extrudable and mouldable.
Mould cavities of suitable shape are produced by
digital modelling of the anatomy of the possible zones for
insertion of the osteosynthesis devices and/or implants.
A sufficient amount of the paste obtained previously
is injected into the compression chamber of a mould
comprising one or more mould cavities.
The whole is then compressed at a pressure gradually increasing from 100 to 220 N; the pressure is maintained for a variable time, gradually decreasing to 0. The device, once removed from the mould and dried at 400C, and packed in double packaging, is sterilized with ionizing radiation at 25 kGy.
EXAMPLE 9: Preparation for bone substitute with controlled bioabsorbability It has been found that the bioabsorption of a bone substitute, or of a bioabsorbable device, is directly linked to the diameters of the interconnected pores, which must vary from 5 to 100 microns, to allow its colonization by neovascularization and the cells involved in bone remodelling. That is why the inventors propose making bone substitutes or moulded implants with controlled interconnected porosity. For this purpose, the following preparation is made, for 100 g: • 80 g of aragonite mixed batch with a granulometry from 50 nanometres to 20 microns obtained in example 2; • 0.139 g of insoluble extracted biopolymers obtained in step 11.2 of example 1;
• 0.021 g of soluble extracted biopolymers obtained in step II.1 of example 1; • 20 ml of a 50% solution of hydroxypropylmethylcellulose (HPMC); • 20 mm 3 of strands of absorbable synthetic mono-filament suture threads, with length of 5 mm, with diameter ranging from 5/0 to 12/0.
These absorbable threads are polymers such as glycolic acid, glycolic copolymer, c-caprolactone polyglactin (Vicryl Rapide or irradiated), chitosan. These threads display staggered absorption from 12 to 90 days. As in the preceding example, the paste is injected into the cavities of a mould, and then compressed. The devices or implants are then removed from the mould, dried, packed in double packaging and sterilized as before at 25 kGy.
EXAMPLE 10: Preparation for injectable bone substitute and endoprosthesis sealing cement Cements are prepared with the following composition, for 100 g:
• 80 g of the material according to the invention, consisting of:
• 73 g of aragonite mixed batch with a granulometry from 50 nanometres to 20 microns obtained at the end of step 1.8; • 2.702 g of insoluble extracted biopolymers obtained in step 11.2 of example 1;
• 0.405 g of soluble extracted biopolymers obtained in step II.1 of example 1; • 3.699 g of carbonated calcium carbonate resulting from step III of example 1; • 20 g of HPMC in high-viscosity aqueous solution at 50%.
The product thus obtained is packaged under vacuum or under controlled atmosphere in syringes of variable capacity, from 0.5 cm 3 to 1 cm 3 for example, with straight
or angled tips, stored cold at a temperature of about 4°C. This preparation, also usable as sealing cement, makes it possible to avoid passage of the sealing product into the circulatory system, for example during sealing of the tail of the prosthesis in the medullary cavity.
Moreover, owing to its composition, it does not cause
release of volatile substances with risk of impacting the
pulmonary system.
Such a composition is also proposed for
vertebroplasty and kyphoplasty in minimally invasive
surgery.
EXAMPLE 11: Preparation for bone substitute with collagen support Bone substitutes are made with the following
composition:
Preparation for 100 g:
• 50 g of aragonite mixed batch with a granulometry from
50 nanometres to 20 microns obtained in step 1.8 of
example 1;
• 0.087 g of insoluble extracted biopolymers obtained in
step 11.2 of example 1;
• 0.013 g of soluble extracted biopolymers obtained in
step II.1 of example 1;
• 2.5 g of carbonated calcium carbonate obtained in step
III of example 1;
• 50 g of macrogol 400.
The whole is mixed until a gel with a viscosity of
about 10 Pa-s is obtained.
30 g of Spongia officinalis reduced to fragments with
a size of 2 mm is added to this gel.
The whole is mixed until a homogeneous paste is
obtained with a viscosity of about 108 Pa-s. The whole is
injected into a mould comprising mould cavities for
osteosynthesis devices or implants. After mould release,
the devices or implants are dried under a stream of hot air
at 400C, packed in double packaging and sterilized in
accordance with the current protocol.
EXAMPLE 12: Preparation for bone substitute According to another embodiment, the biopolymers extracted from the aragonite fraction alone and/or from the calcite fraction may be added to any other biomaterial of synthetic or natural origin in order to optimize or induce certain properties, notably osteoinductive or osteomimetic properties that they lack. Thus, osteoconductive substitutes, such as certain calcium salts, were supplemented with the biopolymers extracted from the aragonitic layer, according to the formulation for 100 g:
• 95 g of granules of TCP, with granulometry ranging from 50 to 250 microns;
• 4.4 g of insoluble extracted biopolymers obtained in step 11.2 of example 1; • 0.6 g of soluble extracted biopolymers obtained in step II.1 of example 1. This preparation, mixed with autologous blood, is inserted in a bone defect created by the exeresis of a cyst at the apex of the upper central incisor.
At the same time, TCP alone is compacted in a loss of substance created by the exeresis of a periapical granuloma at the upper canine. Radiological examination performed at 2 weeks showed greater and quicker bone densification in the cyst cavity
treated with the mixture $TCP + insoluble and soluble extracted biopolymers than in the second cavity, in which
the granules of $TCP are apparent, where only osteoconduction is expressed, whereas in the cyst cavity, osteoinduction is concomitant with osteoconduction,
indicating that the $TCP has acquired a novel property.
Forms of the Invention Forms of the present invention include: 1. Pulverulent semisynthetic material, derived from a natural marine biomaterial, with addition of insoluble and soluble biopolymers and calcium carbonate transformed by carbonation. 2. Semisynthetic material according to Form 1, characterized in that the natural marine biomaterial is the aragonitic inner layer of the shell of bivalve molluscs selected from the group comprising Pinctadines, notably Pinctada maxima, margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus porcelanus, said aragonitic layer being in pulverulent form. 3. Semisynthetic material according to Form 1 or 2, characterized in that the natural biomaterial in pulverulent form has a granulometry from 5 nm to 100 pm, preferably from 20 nm to 50 pm, even more preferably from 50 nm to 20 pm. 4. Semisynthetic material according to any one of Forms 1 to 3, characterized in that the insoluble and soluble biopolymers are extracted from the aragonitic inner layer and/or from the calcitic outer layer of the shell of the bivalve molluscs selected from the group comprising Pinctadines, notably Pinctada maxima, margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus porcelanus. 5. Semisynthetic material according to any one of Forms 1 to 4, characterized in that the calcium carbonate transformed by carbonation is derived from a natural terrestrial, natural marine or precipitated calcium carbonate, or from the inorganic fraction of the aragonitic layer after extraction of the insoluble and soluble biopolymers.
6. Semisynthetic material according to any one of
Forms 1 to 5, characterized in that it is bioabsorbable.
7. Method for preparing a material according to any
one of Forms 1 to 6, comprising mixing a ground natural
biomaterial, insoluble and soluble polymers extracted from
the aragonitic inner layer and/or from the calcitic outer
layer of the shell of the bivalve molluscs selected from
the group comprising Pinctadines, notably Pinctada maxima,
margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus
hippopus, Hippopus porcelanus, and calcium carbonate
transformed by carbonation.
8. Method of preparation according to Form 7,
characterized in that the ground natural biomaterial is
obtained by grinding the aragonitic inner layer of the
shell of the bivalve molluscs selected from the group
comprising Pinctadines, notably Pinctada maxima,
margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus
hippopus, Hippopus porcelanus.
9. Method of preparation according to Form 7 or 8,
characterized in that it comprises a spherification step
after grinding.
10. Method according to any one of Forms 7 to 9,
characterized in that the insoluble and soluble biopolymers
are extracted respectively by supercentrifugation, and by
tangential ultrafiltration coupled to reverse osmosis after
hydrolysis.
11. Method according to Form 10, characterized in that
the aragonitic inner layer and/or the calcitic outer layer
of the shell of the molluscs is(are) crosslinked before
extraction.
12. Method according to Form 10 or 11, characterized
in that the aragonitic inner layer and/or for the calcitic outer layer of the shell of the molluscs is(are) ground and sieved to a granulometry between 250 pm and 50 pm before extraction.
13. Use of the pulverulent semisynthetic material
according to any one of Forms 1 to 6, or obtained according
to the method of one of Forms 7 to 12 as bone substitute
for extemporaneous formulation, for healing and
regeneration of losses of substance, for treating burns,
sores, ulcers, or erythematous skin lesions or in the
manufacture of devices or moulded implants.
14. Use of the pulverulent semisynthetic material
according to any one of Forms 1 to 6, or obtained according
to the method of one of Forms 7 to 12, in the manufacture
of devices or moulded implants with controlled
bioabsorption comprising suture threads with bioabsorption
staggered over time.
15. Use of the pulverulent semisynthetic material
according to any one of Forms 1 to 6, or obtained according
to the method of one of Forms 7 to 12, for formulation of
preparations for bone substitutes for extemporaneous use,
for extrudable bone substitutes, notably packaged in a
syringe under vacuum, bone substitutes with a porous
collagen support, bone substitutes with a mineral structure
of animal or human origin, bioabsorbable osteosynthesis
devices and moulded implants, devices with controlled
bioabsorption, cements for sealing endoprostheses, and
injectable cements for minimally invasive surgery in
vertebroplasty and kyphoplasty.
16. Use of the calcium carbonate that has undergone
carbonation employed in the material according to any one
of Forms 1 to 6, as additive that is plastic, modellable
and adhesive, in compositions comprising calcium salts,
natural or synthetic polymers, collagen, and mineral
structures of bone tissues of animal or human origin.
17. Use of the insoluble and soluble extracted
biopolymers employed in the material according to any one of Forms 1 to 6, as additives in pulverulent compositions
comprising calcium salts, natural or synthetic polymers,
collagen, and mineral structures of bone tissues of animal
or human origin.

Claims (11)

1. Use of insoluble and soluble biopolymers extracted from the organic fraction of the aragonitic inner layer and/or of the calcitic outer layer of the shell of bivalve molluscs selected from the group comprising Pinctadines, notably Pinctadamaxima, margaritifera,and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, Hippopus porcelanus, as additives of pulverulent composition comprising calcium salts, natural or synthetic polymers, collagen, mineral structures of bony tissues of human or animal origin, wherein the pulverulent composition is a pulverulent semisynthetic material derived from a natural marine biomaterial, said natural marine biomaterial being the aragonitic inner layer of the shell of bivalve molluscs selected from the group consisting of Pinctadines, notably Pinctada maxima, margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus, and Hippopus porcelanus.
2. Use of insoluble and soluble biopolymers according to Claim 1, wherein the pulverulent composition further comprises calcium carbonate transformed by carbonation.
3. Use of insoluble and soluble biopolymers according to Claim 2 in the manufacture of devices, moulded implants or bone substitutes formulated for extemporaneous use.
4. Use of insoluble and soluble biopolymers according to Claim 2 or Claim 3 in the manufacture of devices or moulded implants with controlled bioabsorption, comprising suture threads with bioabsorption staggered over time.
5. Use of insoluble and soluble biopolymers according to Claim 2 for the formulation of preparations for bone substitutes for extemporaneous use, for extrudable bone substitutes, notably those packaged in a syringe under vacuum, bone substitutes with a porous collagen support, bone substitutes with a mineral framework of human or animal origin, bioabsorbable osteosynthesis devices and moulded implants, devices with controlled bioabsorption, cements for sealing endoprostheses, and injectable cements for minimally invasive surgery in vertebroplasty and kyphoplasty.
6. Insoluble and soluble biopolymers extracted from the organic fraction of the aragonitic inner layer and/or of the calcitic outer layer of the shell of bivalve molluscs selected from the group consisting of Pinctadines, notably Pinctadamaxima, margaritifera,and Tridacnes, notably Tridacnagigas, maxima, derasa, tevaroa, squamosa, crocea, Hippopus hippopus and Hippopus porcelanus combined with calcium carbonate transformed by carbonation, for their use for the healing of hard tissues such as bone and cartilage and of soft tissues such as skin, muscles and mucous membranes.
7. Pulverulent semisynthetic material obtained from a natural marine biomaterial with addition of insoluble and soluble biopolymers extracted from the organic fraction of the aragonitic inner layer and/or of the calcitic outer layer of the shell of bivalve molluscs selected from the group consisting of Pinctadines, notably Pinctada maxima, and margaritifera, and Tridacnes, notably Tridacna gigas, maxima, derasa, tevaroa, squamosa, and crocea, and Hippopus hippopus and Hippopus porcelanus, and calcium carbonate converted by carbonation, for its use for the healing and regeneration of losses of substance or for the treatment of burns, sores, ulcers and erythematous skin lesions.
8. Use of insoluble and soluble biopolymers according to Claims 2 to 5, or pulverulent semisynthetic material for its use according to Claim 7, wherein the pulverulent semisynthetic material has a granulometry of 5 nm to 100 [m.
9. Use of insoluble and soluble biopolymers according to Claim 8, wherein the pulverulent semisynthetic material has a granulometry of 20 nm to 50 m.
10. Use of insoluble and soluble biopolymers according to Claim 9, wherein the pulverulent semisynthetic material has a granulometry of 50 nm to 20 m.
11. Use of insoluble and soluble biopolymers according to any one of Claims 2 to 5 or Claim 8, or pulverulent semisynthetic material for its use according to Claim 7 or Claim 8, wherein the calcium carbonate transformed by carbonation derives from a natural terrestrial, natural marine or precipitated calcium carbonate, or from the inorganic fraction of the aragonitic layer after extraction of the insoluble and soluble biopolymers.
MBP (Mauritius) Ltd Patent Attorneys for the Applicant/Nominated Person SPRUSON & FERGUSON
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