ANHYDROUS BIOCOMPATIBLE COMPOSITE MATERIALS

Abstract

The invention is directed to biocompatible composite materials for medical applications such as tissue regeneration. In particular, the present invention is directed to biocompatible composite materials that may be used for the treatment of lost bone or bone defects. According to the invention there is provided an anhydrous biocompatible composite material comprising a biodegradable polymeric material and a granular synthetic material, wherein the polymeric material essentially consists of at least one block copolymer that comprises at least one hydrophilic block and at least one hydrophobic block.

Claims

1. Anhydrous biocompatible composite material comprising a biodegradable polymeric material and a granular synthetic material, wherein the polymeric material essentially consists of at least one block copolymer, wherein at least one block copolymer is a polymer according to formula (I) ##STR00002## wherein; A and B are independently methylene oxide, ethylene oxide, propylene oxide, butylene oxide, dioxanone or phenyl oxide, preferably ethylene oxide or propylene oxide; X is a polyamide, polyester, polyurethane, polycarbonate or polyester unit, preferably a polyester unit, more preferably hydroxybutyrate, lactic acid, glycolide, -butyrolactone, -valerolactone or -caprolactone, most preferably lactic acid; l is 0 or 1, preferably 0; m is 1 to 25; n is m or 0; p is 2 to 150; q is 0 to 100; and l+n is more than 0.

2. Anhydrous biocompatible composite material according to claim 1, wherein l is 0 and n is m.

3. Anhydrous biocompatible composite material according to claim 1, wherein l is 1 and n is 0.

4. Anhydrous biocompatible composite material according to any of the previous claims, wherein m is 2 to 10, preferably 3 to 7; p is 6 to 100, preferably 40 to 50; and/or q is 0 to 50, preferably 0 to 19.

5. Anhydrous biocompatible composite material according to claim 1, wherein the granular synthetic material is osteoconductive and preferably osteoinductive.

6. Anhydrous biocompatible composite material according to any of the previous claims wherein the granular synthetic material comprises calcium phosphate.

7. Anhydrous biocompatible composite material according to any of the previous claims, wherein the actual ratio (n+m) to (p+q), as determined by .sup.1H NMR, is less than 0.36, preferably less than 0.30, more preferably between 0.01 and 0.25, even more preferably between 0.05 and 0.15, most preferably about 0.10.

8. Anhydrous biocompatible composite material according to any of the previous claims wherein the polymeric material essentially consists of a blend of two or more block copolymers, which are preferably according to the formula as defined in claim 1, more preferably wherein m is n; l and q are 0.

9. Anhydrous biocompatible composite material according to any of the previous claims that is an injectable, malleable and/or kneadable no-sticky putty that retains its shape at a typical temperature of 15 to 40 C.

10. Anhydrous biocompatible composite material according to claim 9, that is sterilized by -rays or electron beams.

11. Anhydrous biocompatible composite material according to any of the previous claims for use as a medicament, preferably for tissue-engineering, in particular for the treatment of connective tissue and/or bone loss or defect.

12. Method for sterilization of a biodegradable polymeric material essentially consists of one or more block copolymer comprising at least one hydrophilic block and at least one hydrophobic block, wherein the biodegradable polymeric material is irradiated by -rays or electron beams.

13. Method to treat bone loss or defect, by shaping the anhydrous biocompatible composite material according to any of claims 1-10 in a desired shape and placing it at the site of bone loss or defect.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0015] FIGS. 1 and 2 show images of dissolution of various of the block copolymer blends over time as carried out in Example 3.

[0016] FIG. 3 shows images of dimensional change of block copolymer blends over time as carried out in Example 4.

[0017] FIG. 4 shows a images of composition forming a polymer ball and quickly releases granules as carried out in Example 4.

[0018] FIG. 5 illustrates the dissolution behavior of the various composition over time from an experiment as carried out in Example 4.

[0019] FIG. 6A-C show dissolution rate in PBS at 37 C. of block copolymer blends over time as carried out in Example 4.

[0020] FIG. 7 shows a detailed microscope pictures for composite materials and

[0021] histological analysis from dog 2 obtained in Example 6.

[0022] FIG. 8 shows main endpoints of a dissolution test as carried out in Example 7.

[0023] FIGS. 9 and 10 show DSC curves and for physical appearance of three co-polymer formulations obtained in Example 8.

[0024] FIG. 11 shows the relationship between the lactic acid units (hydrophobic block) over ethylene oxide units (hydrophilic block)) ratio, the melting point (Tm), the PEG length and the hardness of compositions.

[0025] FIG. 12 shows 1H-NMR spectra's of polylactide-poly(ethylene glycol)-based block copolymers.

DETAILED DESCRIPTION

[0026] The present invention is an anhydrous biocompatible composite material comprising a biodegradable polymeric material and a granular synthetic material, wherein the polymeric material essentially consists of at least one block copolymer, wherein at least one block copolymer is a polymer according to formula (I)

##STR00001## [0027] wherein; [0028] A and B are independently methylene oxide, ethylene oxide, propylene oxide, butylene oxide, dioxanone or phenyl oxide, preferably ethylene oxide or propylene oxide; [0029] X is a polyamide, polyester, polyurethane, polycarbonate or polyester unit, preferably a polyester unit, more preferably hydroxybutyrate, lactic acid, glycolide, -butyrolactone, -valerolactone or -caprolactone, most preferably lactic acid; [0030] l is 0 or 1, preferably 0; [0031] m is 1 to 25; [0032] n is m or 0; [0033] p is 2 to 150; [0034] q is 0 to 100; and [0035] l+n is more than 0.

[0036] In the representation of formula (I), A.sub.p and B.sub.q are hydrophilic blocks and X.sub.n and X.sub.m are hydrophobic blocks. The block copolymer of the present invention thus comprises at least one hydrophilic block and at least one hydrophobic block.

[0037] The term essentially consisting means that the polymeric material typically consists of at least 90 wt %, more preferably at least 95 wt %, most preferably at least 99 wt % of one or more of said block copolymers.

[0038] For sake of conciseness, the anhydrous biocompatible composite material is herein also referred to as composite material. The granular synthetic material is herein also referred to as granules.

Granular Synthetic Material

[0039] The anhydrous biocompatible composite material in accordance with the present invention is applicable as a medicament in for instance the field of tissue repair. The composite material may in particularly be applied for the treatment of connective tissue and/or bone loss or defects.

[0040] Preferably, the granular synthetic material is osteoconductive. The inventors surprisingly found that the polymeric material is particularly suitable to be combined with osteoconductive granular synthetic material because the polymeric material does, i.a. due to is biodegradation properties, not inhibit bone regeneration and osteoinduction.

[0041] In a further preferred embodiment, the anhydrous biocompatible composite material is osteoinductive. This means that the anhydrous biocompatible composite material comprises one or more material that are osteoinductive. Osteoinductive properties of the anhydrous biocompatible composite material may for instance be achieved by addition of bone morphogenetic proteins (BMP) and/or other growth factors. In an even further preferred embodiment, the granular synthetic material is intrinsically osteoinductive. This means that the granular synthetic material itself stimulates the formation of osteoblast and thus formation of new bone even in non osseous environments (e.g. osteoinductive ceramics, demineralized bone matrix-DBM).

[0042] WO 2015/009154, which is incorporated herein in its entirety, describes granular synthetic materials based on calcium phosphate CaP that are osteoinductive. It was found that in particular the biodegradable polymeric material of the present invention is suitable to maintain the osteoinductive properties of the granular synthetic materials as described in WO 2015/009154.

[0043] The granular synthetic material in accordance with the present invention may comprise calcium phosphate, bioactive glass and the like. Rahaman et al. Acta Biomateralia 2011(6)2355-2373 reviews a variety of synthetic materials for tissue-engineering that are suitable for the present invention. The granular synthetic materials may be granular ceramic material. Preferably, the granular synthetic material comprises calcium phosphate. Such granular synthetic materials have proven to be particularly suitable for tissue regeneration.

[0044] The osteoinductive properties of certain granular synthetic materials are commonly attributed to their specific micro- and sub-microsurface structure. Water may affect this structure and thereby affect the osteoinductive properties of the granular synthetic material. Also other properties of the granular synthetic material may be affected by the presence of water because the synthetic materials may be for instance partially dissolved by the water. Moreover, it is known that water may also affect the osteoinductive potential of other agents, i.e. BMPs and DBM. Therefore, the biocompatible composite material is anhydrous in order to prevent or limit reduction of e.g. the osteoconductive and osteoinductive properties. Anhydrous in the present invention therefore means that the environment granular synthetic material is sufficiently anhydrous for the granular synthetic material to sufficiently retain the chemical and structural properties to limit reduction of the biological activity of the granular synthetic material such that the biocompatible composite material remains effective and thus applicable. This is in contrast to for instance hydrogels which can also be formed with the polymeric material of the present invention.

Biodegradable Polymeric Material

[0045] The biodegradable polymeric material in accordance with the present invention degrades under physiological conditions in preferably less than 48 hours. From Davison N. L. et al. (Acta Biomaterialia, 2012 July; 8(7): 2759-2769) and Barbieri D, et al. (Acta Biomaterialia, 2011 May; 7(5): 2007-2014) it is known that the osteoinductive properties of the granular synthetic material are not lost if the biodegradable polymeric material degrades within 48 hours. Also for osteoconduction it is preferred that the polymeric material degrades within 48 hours. For the composite material, the biodegradable polymeric material typically fills up the voids between the granular synthetic material and the voids within the granules that are the result of the micro- and submicro-structure of the material. For the purpose of bone regeneration, it is essential that e.g. the osteoblast and osteoprogenitor cells, but also blood cells and other cell that are required for bone regeneration can penetrate said voids to form the new bone structure. If the degradation occurs within one hour, there may not be sufficient time to apply the anhydrous biocompatible composite material at the site of treatment which is typically a wet environment. Therefore, more preferably, polymeric material is degraded in more than 10 minutes, most preferably in a time between hour and 48 hours.

[0046] Biodegradation of the polymeric material means that the polymeric material is degraded, disintegrated, resorbed and/or dissolved at the site of application in such a way that it will not prevent the effectiveness of the granular synthetic material. The precise mechanism of biodegradation, e.g. whether bacteria, cells and/or enzymes are involved or not, is irrelevant. The biodegradation may for instance simply occur in only the presence of water. The time required for the degradation may be determined by a test wherein the composite material in accordance with the present invention is immersed in a phosphate-buffered saline (PBS) or another equivalent isotonic solution at a temperature of about 37 C. without shaking. The biodegradation of the composite material may be monitored by visual inspection.

[0047] The anhydrous biocompatible composite material according to the present invention is preferably an injectable, malleable and/or kneadable non-sticky putty that retains its shape at a typical temperature of 15 to 40 C. Such a putty is particularly advantageous when the composite material is used for bone repair. The physical properties of the composite material may be determined by subjecting the composite material in a blind test, that may involve a scoring of the composite material according to the parameters set out in Table 1. The blind test is typically carried out by three or more skilled persons and for each person the Final Score (FS) is calculated as FS=M+R+H+S+O+RG. Preferably, the Final Score is higher than 15, more preferably higher than 20, most preferably higher than 22. When more than one person carried out the test, the average of all Final Scores is calculated and used to evaluate the putty. Hence, it will be appreciated that when more than one skilled person carried out the blind test, the Final Score in an average of all Final Scores.

TABLE-US-00001 TABLE 1 Scoring for blind test of injectable, malleable and/or kneadable non-sticky putties Parameter Score description Mouldability (M): is the 1 impossible to shape it; composite material easily 2 hard to shape (for any reason); malleable, i.e. can it be 3 shapeable, but can be softer; given any shape? 4 shapeable, good; Scale 1-5 5 excellent. Recovery (R): after shaping and 1 impossible to recover it without spreading it onto a surface, can losses; it be completely recovered 2 recover with lot of losses; easily? 3 recover with minimal losses; Scale 1-5 4 recover completely, but sticky; 5 recover completely with no problem. Hardness (H): is the composite 1 a stone or completely loose; material soft, hard or a 2 little deformable, but either very balance in between? hard or very soft; Scale 1-5 3 deformable, with some difficulties (e.g. a bit sticky); 4 deformable, good; 5 excellent. Stickiness (S): is the composite 1 completely sticky; material sticky onto the gloves? 2 sticky, moldable with some difficulty; Scale 1-5 3 sticky, with good moldability; 4 not sticky, good; 5 excellent. Oiliness (O): during the shaping, 1 gloves are oily but sticky; are the gloves getting oily? 2 gloves are oily but not sticky; Scale 1-5 3 oily, but not excessively; 4 minimally oily; 5 not oily at all, dry gloves. Retaining granules (RG): during 1 completely loose before shaping; the shaping, are the granules 2 all granules are dispersed during retained in the putty? shaping; Scale 1-5 3 lot of granules are lost during shaping; 4 a few granules are lost during shaping; 5 no granule loss

[0048] In another embodiment of the present invention, the composite material may be used to treat connective tissue such as skin. Upon aging of connective tissue, it typically starts to show pronounced sagging, wrinkles and/or fine lines. The anhydrous biocompatible composite material of the present application may be a dermal filler that may be used to treat or prevent signs of aging of the connective tissue. The physical properties of the dermal filler may be the same or different compared to the injectable, malleable and/or kneadable non-sticky putty. Besides the biodegradable polymeric, the dermal filler may further comprise other components typically used in the treatment of connective tissue. Examples of these are collagen, hyaluronic acid fillers and other components found in known dermal fillers such as Restylane, Sculptra and Rediesse (M. H. Gold, Clin. Interv. Aging 2007 September; 2(3): 369-376).

[0049] It was surprisingly found that the biodegradable polymeric material that essentially consists of one or more block copolymer comprising at least one hydrophilic block and at least one hydrophobic block is particularly resistant to -radiation and electron beam radiation for sterilization purposes. This i.a. means that the handling properties of the composite material (as e.g. determined by the blind test of Table 1) were not significantly changed after irradiation. This is in strong contrast with other polymeric materials that are not based on block copolymers, for instance those disclosed in WO 2011/009635. It is known that poly(ethylene glycol) (PEG) cross-links upon -irradiation while for instance polylactide (PLA) and carboxymethyl cellulose (CMC) disintegrates upon -irradiation. Blends of PEG and PLA are also not stable links upon -irradiation. Cross-linking and disintegration typically results in unacceptable changes of physical properties, e.g. brittleness (e.g. for PLA-based or PEG-based homopoylmers), softening or even liquefaction of the material (e.g. for CMC-based homopolymers). Surprisingly, a block copolymer of both polymers is able to resist sterilization by -irradiation and/or electron beam irradiation. This is particularly advantageous for anhydrous composite materials since the alternative sterilization method is steam treatment. Steam treatment for sterilization of the composite materials in accordance with the present application is not preferred because the polymeric material may (partially) degrade by the steam. Moreover, the granular synthetic material can not withstand steam because their particular structure will disintegrate leading to loss of the bioactivity as explained herein above. The granular synthetic material would thus need to undergo a separate sterilization procedure.

[0050] A further aspect of the present invention is a method for sterilization of a biodegradable polymeric material that essentially consists of one or more block copolymer comprising at least one hydrophilic block and at least one hydrophobic block, wherein the biodegradable polymeric material is irradiated by -rays and/or electron beams using standard doses for medical devices, i.e. 10-50 kGy for -rays and/or electron beams, more preferably 25-45 kGy.

[0051] In another embodiment, the anhydrous composite material as a whole is sterilized by irradiation by -rays and/or electron beams.

[0052] The hydrophilic block in accordance with the present invention typically comprises a polyether, preferably a polyoxymethylene, poly(ethylene glycol), poly(propylene glycol), polytetrahydrofuran, polydioxanone, polyphenyl ether, a poloxamer or combinations thereof. More preferably, the hydrophilic block comprises poly(ethylene glycol) or a poloxamer.

[0053] When a block is said to be hydrophilic, this means that the block may be soluble in water such that it may be cleared from the site of application by dissolution. When the hydrophilic block comprises e.g. poly(propylene glycol), polytetrahydrofuran, polydioxanone and/or polyphenyl ether, the hydrophilic block typically also comprises polyoxymethylene and/or poly(ethylene glycol) to make the block hydrophilic, i.e. soluble in water. A poloxamer (i.e. a polyether comprising poly(ethylene glycol) and poly(propylene glycol) is an example of such an embodiment. By using standard experimental techniques, the person skilled in the art may readily determine whether the hydrophilic block is soluble in water in accordance with the present invention.

[0054] The hydrophobic block in accordance with the present invention typically comprises a polyamide, polyester, polyurethane, polycarbonate or combinations thereof, preferably polyglycolide or polylactide.

[0055] The present inventors found that short hydrophobic blocks result in better physical properties of the polymeric material. Examples of such increase physical properties are higher melting points (typically more than 40 C.), which is beneficial for storage purposes, combined with waxy, moldable, tacky characteristic as well as a biodegradability of more than 15 minutes and less than 48 hours.

[0056] Particularly good results were obtained for a preferred embodiment, wherein the block copolymer in accordance with the present invention may be a polymer represented by formula (I) as described above, wherein m is 2 to 10, preferably 3 to 7; p is 6 to 100, preferably 40 to 50; and/or q is 0 to 50, preferably 0 to 19.

[0057] From formula (I) it may be appreciated that the block copolymer's termini may be hydrophilic blocks (i.e. l is 1 and n is 0) or hydrophobic blocks (i.e. l is 0 and n is m). Preferably, the polymer termini are hydrophobic. In such an embodiment is the block copolymer typically obtained by providing a hydrophilic polymer B.sub.q-A.sub.p-B.sub.q which is then reacted in a polymerization reaction with monomers that form the hydrophobic blocks X.sub.n and X.sub.m. In case of a cyclic ester, this reaction is typically a ring-opening polymerization reaction. The polyethers poly(ethylene glycol) and poly(propylene glycol) are typical made out of the monomers ethylene oxide (EO) and propylene oxide (PO) respectively. In the context of the present invention, polymers based on ethylene oxide and/or propylene oxide are the same as polymers based on ethylene glycol and/or propylene glycol, respectively.

[0058] For sake of clarity and conciseness the A, B and X are herein defined by and named after the monomer from which the blocks are made of.

[0059] In case lactide is used, any isomer (i.e. L-lactide, D-lactide and meso-lactide) may be used. Preferably, the lactide is substantially one isomer, more preferably substantially D- or L-lactide and most preferably substantially L-lactide. Substantially means here that the block typically consists of more than 90 wt %, preferably more than 95 wt %, even more preferably more than 99 wt % of the isomer used.

[0060] In a specific embodiment wherein A.sub.p is poly(propylene glycol) and B.sub.q is poly(ethylene glycol), the synthesis of the block copolymer may be initiated by polyoxamers that are commercially available. The polyoxamers that known as Pluronics may in particular be used. A large variety of Pluronic type polymers such as e.g. P65, F127, are commercially available. Pluronic P65 may for instance be represented by the formula EO.sub.11PO.sub.16EO.sub.11, while Pluronic F127 is EO.sub.100PO.sub.65EO.sub.100.

[0061] As is typically the case in polymer chemistry, the number of monomer units given is an average number of the number of monomers based on the amount of monomers the synthesis of the polymer was performed with. The polydispersity index (PDI) is typically used as a measure of the distribution of molecular mass (and thus also a measure of the distribution of the number of monomers) in a given polymer sample.

[0062] It has been found that certain properties, in particular the handling properties according to the blind test of Table 1 and the biodegradation properties can be influenced by the molar ratio of monomers contained in the hydrophobic block(s) and monomers contained in the hydrophilic block(s). In case the block copolymer may be represented by formula I, this ratio may theoretically be calculated by dividing (n+m) over (p+q). If the parameters n, m, p and q are determined by the amount of material with which the polymerization reaction was started, a theoretical ratio is calculated. When the parameters n, m, p and q are empirically determined by e.g. .sup.1H NMR spectroscopy, an actual ratio may be calculated.

[0063] In FIG. 11, the relationship between the actual ratio L/EO (i.e. the ratio lactic acid monomers (hydrophobic block) over ethylene oxide monomers (hydrophilic block)), the melting point range (Tm), PEG length and hardness of the putty is depicted. This figure shows that the actual ratio influences the physical properties of the putty.

[0064] It has been found that, in particular when q is 0 and A is ethylene oxide, the actual ratio is preferably less than 0.36, preferably less than 0.30, more preferably between 0.01 and 0.25, even more preferably between 0.05 and 0.15, even more preferable between 0.08 and 0.12, most preferably about 0.10. It will be appreciated that for block copolymers that may not be represented by formula I, but do fall within the scope of the present invention, the molar ratio's (both the theoretic and actual ratio's) may be calculated in an analogues manner.

[0065] Lactide and lactic acid are herein used interchangeable to describe the monomers or building blocks of the polylactide or poly(lactice acid) blocks since these blocks are structurally the same. However, only the lactic acid monomer is used for calculating the ratio of monomers (e.g. L/EO) or the number of monomers (e.g. X.sub.n and X.sub.m in formula I) present in a block and/or copolymer.

[0066] In a further embodiment of the present invention, the biodegradable polymeric materials comprises two or more block copolymers, each comprising at least one hydrophilic block and at least one hydrophobic block. Hence, a blend of block copolymers may be used. When a blend of block copolymers are used, it is meant that two or more different type of block copolymers according to the present invention are used. These block copolymers may differ in mass, molar ratio of monomers and/or type of monomers and so forth.

[0067] By using a blend of block copolymers, it is possible to accurately optimize the desired properties of the biodegradable polymeric material, without much synthetic effort. It was found that also when a blend of block copolymers was used, the total molar ratio of monomers contained in the hydrophobic blocks and monomers contained in the hydrophilic blocks may be used to influence the properties of the biodegradable polymeric material. In this case, the total molar ratio may be calculated by using the actual ratio's of the individual block copolymers as determined by .sup.1H NMR.

[0068] A biodegradable polymeric material that essentially consists of a blend of two or more block copolymers, in particular a blend of two block copolymers, is preferred. This is particular the case when the polymer termini are hydrophilic and/or the hydrophilic block consists of poly(ethylene glycol). For instance, for polymers according to formula (I) wherein m is n; l and q are 0, it is preferred to use a blend of two block copolymers.

[0069] In another embodiment of the present invention, the anhydrous biodegradable composite material further comprises one or more drugs, e.g. an anti-biotic, an anti-inflammatory agent and the like. Such drugs may be beneficial for the tissue-regeneration treatment. The drug may be incorporated together with the granular synthetic material in the polymer material. Once, the polymer material degrades, the drugs are released.

[0070] The composite material in accordance with the present invention is particularly suitable for osteoinduction. Hence, a further aspect of the present invention is a method to treat bone loss or defect, by shaping the anhydrous biocompatible composite material according to the present invention in a desired shape and placing it at the site of bone loss or defect.

[0071] For the purpose of clarity and a concise description features are described herein as part of the same or separate embodiments, however, it will be appreciated that the scope of the invention may include embodiments having combinations of all or some of the features described.

[0072] The invention may be illustrated by the following examples and experimental results.

Example 1

[0073] In this example, the synthesis and characterization of a particular polymeric material in accordance with the present invention will be described.

1.1. Synthesis of Poly(L-Lactide)-Co-Poly(Ethylene Oxide)-Co-Poly(L-Lactide) Triblock Block Copolymers (i.e. LEOL)

[0074] The LEOL block copolymers were synthesized via ring-open polymerization of L-lactide monomer in presence of poly(ethylene oxide) as initiator and stannous octoate (SnOct.sub.2) as catalyst. All reactions were performed in argon saturated atmosphere. Poly(ethylene oxide) (EO) and L-lactide monomer were blended in a glass three-necked flask and gradually warmed to 130 C. under gentle stirring under an argon atmosphere. Afterwards, 4-5 drops (ca. 160-170 L) of the catalyst were added and the mixture was let reacting at the temperature of 130 C. and stirring rate of 50 rpm for 24 hours. Table 2 shows the synthesized block copolymers.

TABLE-US-00002 TABLE 2 Poly(ethylene glycol)-based block copolymers (LEOL)* block ratio's used during the synthesis. Copolymer Theoretical block Theoretical L/EO ID composition mol. ratio LL L.sub.2.5EO.sub.23L.sub.2.5 0.22 ML L.sub.5EO.sub.46L.sub.5 HL L.sub.10EO.sub.91L.sub.10 HM L.sub.15EO.sub.91L.sub.15 0.33 LH L.sub.5EO.sub.23L.sub.5 0.44 MH L.sub.10EO.sub.46L.sub.10 HH L.sub.20EO.sub.91L.sub.20 *the XY nomenclature is used. The letter X indicates the EO block length (e.g. L = EO.sub.23; M = EO.sub.46; H = EO.sub.91) and Y indicates the L-lactic acid/EO block mol. ratio (e.g. L = 0.22; M = 0.33; H = 0.44). Wherein the theoretical L/EO molar ratio is the theoretical ratio as described herein above for the lactic acid monomers over the ethylene oxide monomers.

1.2. Characterization of Poly(Ethylene Glycol)-Based Block Copolymers (LEOL)

1.2.1. Physical (Gross) Appearance

[0075] The block copolymers were analyzed by a stereomicroscope to detect any undesired inhomogeneity. Afterwards the block copolymers were characterized for their hardness first via pressing with steel tools and subsequent shaping by hands. Table 3 summarizes the observations.

TABLE-US-00003 TABLE 3 Physical observations (handling) on poly(ethylene glycol)-based block copolymers (LEOL). ID Observations LL White soft mass that melts as soon as kept in hands leaving a sticky layer of polymer. ML Transparent thick but malleable mass. Does not melt as fast as LL in hands: there is need to process it to get it spread on skin leaving a sticky layer of polymer. HL Hard and waxy. Resists better when worked in hands and gets softer leaving an oily effect. HM Very similar to HL. Additional lactide (compared to HL) is expected to enhance handling and increase hydrophobicity. LH Extremely soft gel, which immediately gets liquid once touched with hands. MH Harder than ML (i.e. need to scratch) but gets melted quicker when worked in hands. HH Very hard and waxy. Similar to HL.

[0076] Based on these observations, a trend seems to exist wherein a shorter EO block results in a the softer mass (e.g. LL vs. ML vs. HL).

1.2.2. Melting Point: Visual Estimation

[0077] A volume of roughly one mL of each block copolymer was put in glass vials immersed in cold water bath, which was warmed via a gentle temperature ramp. The temperature of the block copolymer was continuously monitored and the melting point range was recorded: the lowest temperature was the one at which the polymer visually started to change state while the highest temperature was taken when the polymer was completely melt. Table 4 shows the results.

TABLE-US-00004 TABLE 4 Melting range of poly(ethylene glycol)- based block copolymers (LEOL). Copolymer Melting point Appearance ID range [ C.] after melting LL 30-35 Clear liquid ML 45-50 Clear liquid HL 55-60 Clear liquid HM 40-60 Clear liquid LH <30 Clear liquid MH <40 Clear liquid HH <40 Clear liquid

[0078] The results show that LEOL block copolymers have increasing melting temperature ranges with the increase of EO block size, but it decreases when lactide block size increased. Therefore, a few conclusions may be drawn: [0079] 1) the shorter EO block, the lower the melting point (e.g. LL vs. ML vs. HL); [0080] 2) the longer L-lactide block, the lower melting point (e.g. LL vs. LH and ML vs. MH).

1.2.3. Composition: .SUP.1.H-NMR

[0081] Copolymers were dissolved in deuterated chloroform (i.e. CDCl.sub.3, at any concentration) and spectra (NMR-spectra 1, vide infra) were obtained via proton nuclear magnetic resonance (.sup.1H-NMR, 400 MHz) to determine the molecular composition of each copolymer. Peak integration was performed on raw spectra (i.e. without any processing) and the total area of EO block peak (A.sub.EO) and the total area of two L-lactide block peaks (X.sub.L) were recorded. The final block composition was then calculated basing on the molecular formula X.sub.nEO.sub.pX.sub.n where p{23,46,91}, and using p:A.sub.EO=2n:X.sub.L.

[0082] Table 5 compares the composition calculated from the measurements with those theoretical and reports the actual L/EO molecular ratio which can be calculated from the composition by .sup.1H-NMR: full synthesis of copolymers with higher lactide amounts was more difficult, leading to lower L/EO molecular ratios than those theoretical.

[0083] FIG. 12 depicts NMR-spectra-1 which include .sup.1H-NMR spectra's for the poly(ethylene glycol)-based block copolymers (LEOL). (a) LL, (b) ML, (c) HL, (d) LH, (e) MH and (f) HH. Indicated by arrow is the band for EO block (.sub.EO=3.55-3.80 ppm), while stars indicate the L-lactide block chemical shifts (.sub.L1=5.10-5.30 ppm, .sub.L2=1.40-1.70 ppm).

TABLE-US-00005 TABLE 5 Composition of poly(ethylene glycol)-based block copolymers (LEOL). Copolymer ID Theoretical Composition Actual L/EO composition by .sup.1H-NMR mol. ratio LL L.sub.2.5EO.sub.23L.sub.2.5 L.sub.2.3EO.sub.23L.sub.2.3 0.20 ML L.sub.5EO.sub.46L.sub.5 L.sub.4.3EO.sub.46L.sub.4.3 0.19 HL L.sub.10EO.sub.91L.sub.10 L.sub.8.1EO.sub.91L.sub.8.1 0.18 HM L.sub.15EO.sub.91L.sub.15 n/a n/a LH L.sub.5EO.sub.23L.sub.5 L.sub.4.5EO.sub.23L.sub.4.5 0.39 MH L.sub.10EO.sub.46L.sub.10 L.sub.9.1EO.sub.46L.sub.9.1 0.39 HH L.sub.20EO.sub.91L.sub.20 L.sub.16.3EO.sub.91L.sub.16.3 0.36
Wherein the actual L/EO molar ratio is the actual ratio as determined by .sup.1H NMR described herein above for the lactic acid monomers over the ethylene oxide monomers.

1.3. Preparation of Blends of Poly(Ethylene Glycol)-Based Block Copolymers (LEOL)

[0084] Each block copolymer was mixed with another one in the desired proportions via syringe. Table 6 shows the blends prepared, including the calculated L/EO mol. ratio based on those obtained from .sup.1H-NMR data (Table 5). Please note that in a blend one cannot strictly speak of a L/EO molecular ratio, but it can be used as an indicator for the L-lactic acid amount in the final blend.

TABLE-US-00006 TABLE 6 Prepared blends of poly(ethylene glycol)- based block copolymers (LEOL). Composition Theoretical L/EO [% v/v] Observations mol. ratio 25LL75ML Malleable 0.19 50LL50ML 0.19 25LL75HL 0.18 50LL50HL 0.18 25ML75HL 0.18 50ML50HL 0.18 50ML50HM Malleable n/a (theoretical: 0.25) 25LH75MH Hard 0.39 50LH50MH 0.39 25LH75HH 0.36 50LH50HH 0.36 25MH75HH 0.36 50MH50HH 0.37

[0085] Longer EO blocks seem to result in harder to another one with shorter EO block, the resulting binder seems to be harder blends. Moreover, blends containing block copolymers with higher L-lactic acid/EO block molecular ratio are very hard. The melting point of resulting blends is not very different than that of the component with longer EO block.

Example 2. Sterilization of Block Copolymers and Blends Thereof

[0086] The block copolymers and blends from Example 1 and listed below were sterilized with two different methods: -irradiation and e-beam. [0087] Copolymers: LL, ML, HL [0088] Blends: 25LL75HL, 25ML75HL, 50ML50HL
The materials were compared against their non-sterile counterparts on the basis of gross appearance (Table 7).

TABLE-US-00007 TABLE 7 Gross observations of block copolymers and blends after sterilization. ID Observations as compared to the non-sterile counterpart LL -irradiation: soft but thick cream (no observable changes). e-beam: soft but thick cream (no observable changes). ML -irradiation: hard mass (no observable changes). e-beam: hard mass (no observable changes). HL -irradiation: waxy mass (no observable changes). e-beam: waxy mass (no observable changes). 25LL75HL -irradiation: hard uniform mass (no observable changes). e-beam: hard uniform mass (no observable changes). 25ML75HL -irradiation: hard uniform mass (no observable changes). e-beam: hard uniform mass (no observable changes). 50ML50HL -irradiation: hard uniform mass (no observable changes). e-beam: hard uniform mass (no observable changes).

Example 3: In Vitro Bench Testing of Formulation of LEOL Copolymer Binders with Particles into Putty

3.1. Preparation of Putties

[0089] Based on positive handling evaluation, a subset of the block copolymer blends from Example 1 was selected as potential putty binders. Various putties were prepared with CaP ceramic granules (size 0.5-1 mm) and one binder in a binder/CaP volume ratio of 0.8. Accordingly, the polymer component was melt and mixed with CaP granules. Only those (non-sterile) putties that could retain granules have been further considered.

3.2. Characterization of Non-Sterile Puttie

3.2.1. Blind Test

[0090] The blind test was executed by third persons to evaluate the handling performance of the putties, which were scored according to the guidelines as described herein above and in Table 1. The final score (FS) of each material was calculated, where the worst performance was scored with 5 and the best one with 30. The results are summarized in Table 8.

3.2.2. Dissolution Test

[0091] Dissolution test was done by immersing roughly 1 mL of each putty in 11 mL of phosphate buffered solution (i.e. PBS) at 37 C. without shaking. At the time points of 1, 2, 4, 8, 16 and >16 minutes pictures were taken. FIGS. 1 and 2 show images of the dissolution during time, while Table 8 shows the results.

[0092] FIG. 1 shows results of dissolution the test for non-sterile samples in PBS.

[0093] All non-sterile LEOL-binders had a rapid start of dissolution (viz. within 30-60 minutes) and let the corresponding putties release granules. However, they had different dissolution rates as bulky bodies in the putties containing 25ML75HL, 50ML50HL, 25LL75HL, 50LL50HL, 50LH50HH and 25LH75MH were present after 32 min (see FIG. 2).

[0094] FIG. 2 shows more results of the dissolution test for non-sterile samples in PBS. [0095] Legend labels of materials: (A) 25ML75HL; (B) 50ML50HL; [0096] (C) 50LL50ML; (E) 25LL75ML; (F) 25LL75HL; (G) 50LL50HL; (H) [0097] 50LH50HH; (I) 25LH75MH; (J) 50LH50MH.

TABLE-US-00008 TABLE 8 Selected putties and results from the blind and dissolution tests. Composition binder/CaP vol ratio = 0.8 Blind test Dissolution test [min] 100LL n/a starts at 8 min, almost completely CaP granules dissolved at >16 min 100HL n/a starts at 16 min, almost completely CaP granules dissolved at >32 min 25LL75ML 21.4 starts at 16 min, partially dissolved CaP granules at >32 min 50LL50ML 20 starts at 1 min, partially dissolved CaP granules at >16 min 25LL75HL 24 starts at 16 min, almost completely CaP granules dissolved at >16 min 50LL50HL 22 starts at 16 min, almost completely CaP granules dissolved at >16 min 25ML75HL 23.6 partially dissolved at >16 min CaP granules 50ML50HL 20.8 partially dissolved at >16 min CaP granules 25LH75MH n/a (loss of starts at 2 min, almost completely CaP granules granules) dissolved at >16 min 50LH50MH n/a (loss of starts at 2 min, almost completely CaP granules granules) dissolved at >16 min 50LH50HH 22.2 the least dissolved at >16 min CaP granules

Example 4: Copolymer Synthesis with Central Block Different than PEG

[0098] Two families of L-lactide containing copolymers were prepared, differing in the type of their central block: one with poly(propylene glycol) (i.e. LPGL) and the other with Pluronic (LPUL). The central block could be with different molecular weight or different kinds of Pluronic. When the same central block was considered, different lactic acid/central block molar ratios were also considered.

4.1. Synthesis

[0099] All block copolymers were synthesized via ring-open polymerization of L-lactide monomer in presence of poly(propylene oxide) or Pluronic P65 as initiators and stannous octoate (i.e. SnOct.sub.2) as catalyst. All reactions were performed under an argon saturated atmosphere at 130 C. and stirring rate of 50 rpm for 24 hours. Table 9 shows the synthesized block copolymers.

TABLE-US-00009 TABLE 9 LPGL and PLUL block copolymers. Theoretical Copolymer Design L/PG Family ID Property mol. ratio LPGL PG4.sub.L L.sub.7.5PG.sub.68L.sub.7.5 0.22 poly(propylene PG4.sub.M L.sub.15PG.sub.68L.sub.15 0.44 glycol) based PG4.sub.H L.sub.22.5PG.sub.68L.sub.22.5 0.66 LPUL P65.sub.L L.sub.11P65L.sub.11 0.57 Pluronic based P65.sub.M L.sub.16.5P65L.sub.16.5 0.86 P65.sub.H L.sub.22P65L.sub.22 1.15 F127.sub.LL L.sub.11F127L.sub.11 0.11 F127.sub.M L.sub.87F127L.sub.87 0.87

[0100] Wherein the theoretical L/PG molar ratio is the theoretical ratio as described herein above for the lactic acid monomers over the ethylene oxide and propylene oxide monomers.

4.2. Characterization of Copolymers

4.2.1. Physical (Gross) Appearance of LPGL and LPUL Copolymers

[0101] The copolymers were observed with stereomicroscope to detect any presence of any undesired inhomogeneity. Afterwards they have been characterized regarding their hardness via pressing with steel tools first and with hands then. Table 10 summarizes the observations on LPGL copolymers and Table 11 refers to LPUL copolymers.

TABLE-US-00010 TABLE 10 Physical observations (handling) on poly (propylene glycole)-based block copolymers (LPGL). ID Notes PG4.sub.L At room temperature, viscous fluid tending to white color. PG4.sub.M Viscous and white semi-solid that quickly solidifies as soon as temperature drops from 130 C. PG4.sub.H White and thick fluid that quickly solidifies as soon as temperature drops from 130 C.

[0102] Basing on the gross observations, it may be said that the material hardens with the increase in L-lactide block size (e.g. PG4.sub.L VS. PG4.sub.M VS. PG4.sub.H).

TABLE-US-00011 TABLE 11 Physical observations (handling) on Pluronic-based block copolymers (LPUL). ID Notes P65.sub.L At room temperature is liquid. P65.sub.M At room temperature is liquid. P65.sub.H Soft mass F127.sub.LL Hard brownish solid mass. F127.sub.M Hard brownish solid mass.

4.2.2. Dissolution Test of LPGL Copolymers

[0103] Carefully weighed masses (m.sub.0) of PG4.sub.M and PG4.sub.H block copolymers were placed in 100 mL of distilled water, for one week at 371 C. and gently shaken. Three time points were considered (i.e. 1, 4 and 7 days; 1 replicate per time point), when the samples were harvested, excess water wiped away and their wet weight (mw) was measured. Then, each sample was photographed and then vacuum dried at 371 C. until stabilization of their weights. Therefore the dry weights (md) were taken. Fluid uptake (FU) and mass loss (ML) changes (in %) could be calculated, for each sample at each time point, as

[00001]$\mathrm{FU}=100*\left(m_w-m_d\right)/m_d$$\mathrm{ML}=100*\left(m_0-m_d\right)/m_0$

[0104] The dimensional change is determined by the variation of average diameter (in %) during time, where the average diameter is given by the average of diameters measured along different directions. Table 12 show the results for fluid uptake, mass loss and average dimension changes (FIG. 3).

TABLE-US-00012 TABLE 12 One-week degradation of poly(propylene glycol)-based block copolymers (LPGL). Mass Loss Fluid Uptake Dimension Change [%] [%] [%] Copolymer 1 day 4 days 7 days 1 day 4 days 7 days 1 day 4 days 7 days PG4M 1.6 1.5 2.6 4.9 3.5 3.0 17.1 7.5 2.6 PG4H 7.6 8.5 8.4 6.6 9.0 9.7 10.3 17.2 11.1

[0105] LPGL copolymers seem to change during time when in contact with PBS but they retain their bulky mass.

4.3. Preparation of LPGL- and LPUL-Based Putties and Dissolution Properties

[0106] Putties were prepared with CaP ceramic granules (size 0.5-1 mm) and one binder in a binder/CaP volume ratio of 0.8. Each putty underwent a dissolution test (see Example 3.2.2 for procedure): Table 13 and FIG. 4 show the results regarding LPGL-based putties.

TABLE-US-00013 TABLE 13 Physical observations (handling) on poly (propylene glycol)-based copolymer (LPGL) putties. ID Handling property Dissolution putty Loses granules, not Granules were released, PG4L malleable. but polymer is not dissolved. putty Very good handling. Putty retains shape and size PG4M over a week putty Good handling Putty retains shape and size PG4H characteristics. over a week

[0107] FIG. 4 shows that the PG4.sub.L-based putty quickly releases granules and forms a small polymer ball. As soon as the degrading medium was removed, the polymer ball lost shape. In contrast, PG4.sub.M- and PG4.sub.H-based putties kept the shape for the whole duration of the experiment (i.e. one week).

[0108] All LPUL-based putties were dissolvable in water and could release the ceramic granules (Table 14). It may be seen that those binders having less polylactide had a higher dissolution rate.

TABLE-US-00014 TABLE 14 Handling and dissolution properties of Pluronic-based block copolymer (LPUL) putties. ID Handling property Dissolution putty Loses granules, Dissolved in 5 minutes, P65.sub.L not malleable. with granules release. putty Good handling. Dissolved in 1.5-2 hours, P65.sub.M with granule release. putty Brittle putty. Partially dissolved over P65.sub.H 4 days.

Example 5: Sterilization Putties

5.1 Sterilization of LEOL Putties

[0109] Certain LEOL putties from Example 3.1 were sterilized with -irradiation (25-40 kGy) and evaluated on their capacity to retain granules and be shaped. A subgroup was then selected basing on the handling results and subjected to dissolution test. FIG. 5 illustrates the dissolution behavior of the selected putties, which seems similar to those not-sterile (FIG. 1).

[0110] From the figures at time T=0 min, one can see which putties were still able to retain granules and be shaped after sterilization (i.e. putties with LL, 75LL25HL, 50LL50HL, 25LL75HL and HL).

[0111] Certain other putties from Example 3.1 were sterilized with -irradiation and compared against their non-sterile counterparts on the basis of gross shapeabling properties (Table 15), while their dissolution rate in PBS at 37 C. was evaluated as well (FIG. 6).

[0112] Certain putties (e.g. putty ML) showed even slightly improved handling characteristics after sterilization.

[0113] FIG. 6A shows the initial shape and size of sterile putties. All have retained the granules after sterilization and kept the shape. However, as reported in table 15, they had different handling properties. FIG. 6B shows the putties after 32 minutes in PBS. Those putties with binders based on PEG started to disintegrate indicating a rapid triggering of binder dissolution. FIG. 6C shows the composite materials after one hour: all PEG-based putties released most of granules (observe the central block still standing: it will disappear during the next hour). Pluronic- and poly(propylene glycol)-based putties were not disintegrated at all and did not release any granule after one hour. They will still keep the same shape after two days.

TABLE-US-00015 TABLE 15 Handling of certain putties after -irradiation. ID of putties (CaP/binder v/v ratio = 1.2-1.3) Observations as compared to the binder formulation non-sterile counterpart putty A Non-sterile: consistent mass, looks hard but (25ML75HL) it is shapeable After -irradiation: softer, with good shapeability and not sticky putty ML (100ML) Non-sterile: shapeable, softer than putty A After -irradiation: good shapeability (even if a bit hard at the beginning) and not sticky putty HM (100HM) Non-sterile: hard and there is need to work it with hands before getting it shapeable After -irradiation: too hard putty NEW Non-sterile: consistent mass, looks hard but (50ML50HM) it is shapeable After -irradiation: harder but still shapeable

5.2 Sterilization of LPGL-Based Putties

[0114] Two preferred LPGL-based putties from Example 4 were sterilized with -irradiation (25-40 kGy). Table 16 shows the observations.

TABLE-US-00016 TABLE 16 Handling of poly(propylene glycol)-based copolymer (LPGL) putties after sterilization. ID Handling property after sterilization putty PG4.sub.M Non-sterile: excellent shaping properties After -irradiation: good shapeability, but a bit sticky. Retained granules and kept the shape, same handling properties were observed. putty PG4.sub.H Retained granules and kept the shape, same handling properties were observed. putty P65.sub.M Non-sterile: soft mass and sticky After -irradiation: too soft, with loss of granules

Example 6 In Vivo Biological Performances of Selected LEOL Putties in Osteoinduction Model

[0115] Four LEOL putties from Example 3.1 (Table 17) were implanted in back muscle of five dogs for 8 weeks to evaluate the effect of four different LEOL binders on the osteoinduction potential of calcium phosphate ceramic granules (size 0.5-1 mm). After harvesting and histoprocessing, they have been stained with methylene blue/basic fuchsin and sectioned.

TABLE-US-00017 TABLE 17 The LEOL-based putties implanted. Material description Notes A putty 25ML75HL binder with CaP granules (0.5-1 mm) in polymer/CaP volume ratio of 0.8 B putty 50ML50HL binder with CaP granules (0.5-1 mm) in polymer/CaP volume ratio of 0.8 F putty 25LL75HL binder with CaP granules (0.5-1 mm) in polymer/CaP volume ratio of 0.8 MH putty 100MH binder with CaP granules (0.5-1 mm) in polymer/CaP volume ratio of 0.8

[0116] Not much difference was seen among the four composite materials, and histological observations are comparable with each other.

[0117] For all composite materials bone formation was observed, mainly scattered in spots over the whole implant area. Osteoid, with a seam of osteoblast cells lining its border surface, was present indicating active bone formation. CaP ceramic debris was occasionally observed as dispersed in soft tissue matrix in the form of small particles (dimensions in the order of tens of microns). Many multinucleated giant cells, with CaP ceramic nano-particles phagocytized, were present on the surface of ceramic granules. When no bone was observed (i.e. one B, one F and one MH), very limited amount of cells were seen and soft tissue looked like fibrous. No inflammatory signs were observed in any explant and no fibrotic capsule was formed.

[0118] Visually comparing the putty samples, not much difference was observed indicating that all four gels performed similarly. When the putties were compared to CaP ceramics alone, it appeared that bit less bone formation occurred indicating a possible slight bone-hindering effect of the gels. However, osteoid and osteoblast cells indicate that, after 8 weeks implantation, bone formation is still ongoing and may lead to a larger bone volume at later stages. The presence of multinucleated giant cells and of ceramic residuals dispersed in the soft tissue matrix, and the simultaneous absence of any inflammation signs, indicate cell-driven resorption of the ceramic granules is active.

[0119] FIG. 7 shows a detailed microscope pictures for each composite material and histological analysis from dog 2. In (a) is the overview of putty A, (b) is overview of putty B, (c) is overview of putty F, and (d) is overview of putty MH. The scale bar in (a) applies for all overviews. Detailed images taken at higher magnification (10) are shown in (e) for putty A, (f) for putty B, (g) for putty F and (h) for putty MH. Circles in (e), (f), (g) and (h) in indicate ceramic debris dispersed in soft tissue matrix. The boxes in (e), (f), (g) and (h) indicate where images with further higher magnification (20) were taken: (i) is putty A, (m) is putty B, (n) is putty F and (o) is putty MH. Letter M stands for material (i.e. CaP ceramic granules), black stars indicate osteoid, black arrows show the seam of osteoblast cells and gray arrows show multinucleated giant cells phagocytizing on the surface of the granules.

Example 7. Selection of a Suitable Binder Formulation

[0120] In this example, additional blends of L-lactide/EO block copolymers were prepared and analyzed. The synthesis of the copolymers and the blends was carried out analogously to Example 1.1. The following blends of copolymers were prepared.

TABLE-US-00018 TABLE 18 Blends of copolymers Actual L/EO mol. ID Formulation ratio Blend A 26.4% wt. L-lactide + 18.4% wt. PEG2000 + 0.18 55.2% wt. PEG4000 Blend C 15% wt. L-lactide + 21.25% wt. PEG1000 + 0.10 63.75% wt. PEG2000 Blend W 15% wt. L-lactide + 23.4% wt. PEG1000 + 0.11 59.5% wt. PEG2000 + 2.1% wt. PEG3000 Blend Z 25% wt. L-lactide + 37.5% wt PLU85 + <0.05 37.5% wt PEG4000

[0121] Wherein the actual L/EO molar ratio is the actual ratio as determined by .sup.1H NMR described herein above for the lactic acid monomers over the ethylene oxide monomers.

7.1. Characterization of the Blends

[0122] The melt point was determined as described in Example 1 (1.2.2.), and the intrinsic viscosity was measured with Ubbelohde viscometer (25 C., 0.33 g/dL.). Physical observations were conducted as described in previous examples.

The results of the blend characterization are reported in Table 19

TABLE-US-00019 TABLE 19 Characterization of the blends Melt Intrinsic range viscosity ID [ C.] [dL/g] Observations Blend A 41-43 0.16 hard-to-semi hard waxy mass Blend C 49-52 0.10 soft waxy mass Blend W 49-51 0.13 soft waxy mass Blend Z 45-47 0.18 sticky moldable creamy mass

7.2. Suitability of the Blends for Putty

[0123] Putties were prepared by mixing the different copolymers with calcium phosphate ceramic granules (1-2 mm) as described in example 3.1. A blind handling test in dry air was conducted on the resulting putties: [0124] Blend A: hard putty, which needs to be warmed up in hands for some minutes to get softness and be shapeable; [0125] Blend C: malleable putty, without need to be warmed; [0126] Blend W: malleable putty, very similar to the one prepared with Blend C; [0127] Blend Z: weak material, that breaks down easily as soon as shaped.

[0128] The malleability of the four putties has been evaluated also in wet conditions, i.e. they were shaped in water: Blend A and Blend Z disrupted quickly losing their malleability and could not retain ceramic granules. Conversely, Blend C and Blend W retained ceramic granules while being shaped, and could be shaped for a longer time.

[0129] The putties have also been evaluated in a dissolution test over a time period. The putties were cut into discs and placed on one extreme of a glass slide. These slides were then placed in tubes filled with 50 mL PBS, which were kept 45 inclined at 37 C. FIG. 8 shows the main endpoints of the dissolution test of the putties. All putties dissolved in an acceptable manner. Blend C and Blend W had faster dissolution leading to quicker putty disruption as compared to Blend A (PEGs with higher molecular weight) and Blend Z (presence of Pluronic P85, which presents hydrophobic poly(propylene glycol) in its structure).

Example 8Effect of L/EO Ratio (i.e. Role of Lactide Content in the Formulation)

[0130] The effect of L/EO ratio on the copolymer physical properties was evaluated. Three formulations, based on Blend C, were prepared with different lactide content as summarized in Table 20. The melt temperature of the three materials has been determined with differential scanning calorimetry (DSC) in the range 25-65 C. with a temperature increase rate of 10 C./min. The results are shown in Table 20 and FIG. 9, the latter showing DSC curves for the three formulations: the decrease of melt temperature with the increase of lactide content is clearly visible. FIG. 10 shows the physical appearance of the formulations according to the lactide content.

TABLE-US-00020 TABLE 20 Characterization of the blends prepared with different lactide content Actual L/EO Melt Observations mol temp. (see also ID Formulation ratio [ C.] FIG. 10) High 70% wt. L-lactide + 0.93 n/a liquid to semi- 7.5% wt. PEG1000 + liquid mass. 22.5% wt. PEG2000 When shaped, it spreads on the surface Middle 15% wt. L-lactide + 0.10 47.1 soft waxy mass 21.25% wt. PEG1000 + that, when 63.75% wt. PEG2000 shaped, keeps the consistency and can be recovered Zero 25% wt PEG1000 + 0 55.4 brittle mass, 75% wt PEG2000 no shaping is possible

[0131] Varying the content of lactide resulted in blends with different physical characteristics. This example demonstrates the relationship between the actual ratio LEO (i.e. the ratio lactic acid units (hydrophobic block) over ethylene oxide units (hydrophilic block)), the melting point (Tm), the PEG length and the hardness of the putty, as depicted in FIG. 11.