The present invention relates to materials based on organically modified silicic acid (hetero) polysilicates for use as crowns, inlays, onlays, 3-unit bridges, repair system for crowns, basic prosthesis materials, dentures, and veneer material.
For the long-term maintenance of severely damaged teeth, the previously prepared tooth stumps normally receive metal, veneer or all-ceramic crowns. Plastic-based full crowns are primarily used in dental technology as temporary replacements due to the fact that the materials can only withstand chewing pressure for a short period. Thus, they have not previously been worth considering for high-quality long-term care as a result of serious mechanical deficiencies. In contrast, “classic” tooth replacement materials are not possible for easily applicable (Chair-side treatment), high-quality long-term care due to serious deficiencies in the fabrication and processing technology. For this reason, a time-consuming, i.e. multiple costly treatments, the integration of a temporary crown, two traumas involving the tooth, two applications of local anesthetics, as well as an expensive fabrication of the final full crown by dental technicians in a dental laboratory have been necessary up to this point. Retouching or repairs are only possible to a certain degree or not at all without removing the tooth replacement, which would normally cause it to be destroyed and to have to be remade. Many orders have been sent abroad to lower-wage countries for years in order to keep preparation prices low.
However, the desire for digitalization (e.g. digital impressioning) using tooth replacement materials with the highest esthetics/functionality is increasingly growing. In 2007, the expenditure of statutory health insurance providers in Germany was over 10 billion euros with the trend rising. The resulting cost pressure on the healthcare system can only be confronted with inexpensive, though high-quality tooth replacement systems. This ambitious plan means providing an innovative tooth replacement material for crowing vital/non-vital tooth stumps and, thus, definitive, i.e. long-term care of severely damaged teeth in order to maintain them for a long period. The material must allow the dentist to produce and use the fully-anatomically formed crown or respective other components for restoration or cosmetic needs during a patient's visit (chair-side treatment) with the aid of a computer (particularly with the help of CAD/CAM procedures) after gathering the data (oral scanner). Multiple patient treatments involving a dental laboratory with the integration of a temporary tooth replacement, such as a crown, should be eliminated. The costs for this type of fabrication are far below that of a conventional metal, veneer or all-ceramic crown because the time consumption is significantly lower and dental technicians (dental laboratory) are not necessary. However, the need for the “chair-side” processing of the material basis and the final properties under oral conditions has not been able to be met with the classic material basis for crowns.
If CAD/CAM technology is intended to be used, the tooth replacement is primarily produced in three steps:
The target group of the chair-side concept is dentists or assisting personnel under their supervision. If possible, the tooth replacement should be made directly after tooth preparation and a final intra-oral measurement at the office and the patient should be cared for at the same visit. The factors of time and material expense are reduced through intra-oral digitalization.
The objective of the invention is providing materials for the aforementioned purposes, particularly for crowns, inlays, onlays, 3-unit bridges, repair systems for crowns, basic prosthesis materials, dentures, and veneer materials. In solving these problems, these materials can meet the following requirements due to the composition selected pursuant to the invention:
The objective of the invention is solved through the provisioning of an optionally filled silicic acid (hetero) polycondensate for use in “chair-side” applications, particularly as a repair material, basic prosthesis material, and veneer material, as well as the use of a filled, preferably thermally cross-linked silicic acid (hetero) polycondensate as a molding for “chair-side” crowns, inlays and onlays, and dentures, preferably in a surgical or therapeutic procedure to be conducted by a dentist. Particularly preferably, this occurs pursuant to one of the Claims 1 or 7 as well as one of the Claims dependent thereon.
According to the invention, the term used in the Claims “fully anatomical” as an attribute of a form means this form already has the final dimensions for insertion into the mouth of the patient or must only be minimally readjusted (e.g. subsequently cut), e.g. for the production of an optimal chew level. Likewise, according to the invention, the term “reduced” used there as an attribute of a form means that this form is dimensioned slightly too small. Both terms are standard terms in the field of the present invention.
The silicic acid (hetero) polycondensates used pursuant to the invention represent a common material basis for all aforementioned materials. Thus, they can be combined better, whereas properties such as esthetics, impact strength, breaking strength, modulus of elasticity, abrasion, and the like can be adjusted depending on the individual indication for a precise composition of the selected resin matrix, the type of filler material, and their shares to each other. As such, e.g. a modulus of elasticity can be randomly adjusted between, e.g. 1 GPa and 22 GPa, according to the requirements of the specific application and thus also the modulus of elasticity to be preferably achieved for the invention in the range of at least 4 GPa and in particular cases of at least 10 GPa. A similar situation applies for the breaking strength, which should favorably be at least at 80 MPa, in some embodiments at least at more than 90 MPa. Peak values of up to 150 MPa and even higher can be achieved.
The silicic acid (hetero) polycondensates used pursuant to the invention are mostly known from the state of the art. They all have a radical in common that is bonded to silicon via carbon, which normally bears at least one organically polymerizable group or one reactive ring. An organically polymerizable group presently means that this group is accessible to a polyreaction, for which reactive double bonds or rings transform into polymers (addition polymerization or chain-growth polymerization) under the influence of heat, light, ionizing radiation or redox-induced (e.g. with an initiator (peroxide or the like) and an activator (amine or the like)). During this polymerization, neither a separation of molecular components occurs nor a migration or rearrangement. Moreover, these groups should particularly preferably be accessible to a thiol-ene polyaddition when a thiol is added; even primary and secondary amines (particularly with at least two, though even three, four or more amino groups) should be able to be deposited. Alternatively, they can be accessible to a ROMP (ring opening metathesis polymerization). Examples for this are norbornene groups. The reactive double bond(s) of this group can be randomly selected, for example, a vinyl group or component of an allyl or styryl group. Preferably, it/they are a component of a double bond, which is accessible to a Michael addition, thus containing an activated methylene group as a result of the proximity to a carbonyl group. In turn, preferred among these are acrylic acid and methacrylic acid groups or derivatives. The organically polymerizable group normally contains at least two and preferably up to approx. 100 carbon atoms. It can be bonded to the carbon network of the Si—C bonded radical directly or via a random linkage group.
The term “(meth)acrylic . . . ” presently means that in each case it can be dealing with the respective acrylic or the respective methacrylic compound or a mixture of both. The present (meth)acrylic acid derivatives comprise the acids themselves, potentially in an activated form—esters, amides, thioesters, and the like.
The organically modified silicic acid polycondensates of the present invention may be exclusively silicon-based; however, instead they may have additional metal atoms in the inorganic framework as well, such as is known from the state of the art. These will be designated at present as silicic acid hetero polycondensates. The term “silicic acid (hetero) polycondensates” should comprise both variations. The condensates contain organic radicals bonded to silicon via carbon.
Examples for silicic acid hetero polycondensates usable pursuant to the invention, which are by no means limited, can be produced from the following silanes.
Silanes of a general formula (A):
{XaRbSi[R′(A)c](4-a-b)}xB (A)
wherein said radicals have the following meaning:
X: hydroxy, alkoxy, acyloxy, alkylcarbonyl, alkoxycarbonyl or —NR″2;
R: alkyl, alkenyl, aryl, alkylaryl or arylalkyl;
R′: alkylene, arylene or alkylenarylene;
R″: hydrogen, alkyl or aryl;
B: straight-chain or branched out organic radical that is derived from a compound with at least two C═C double bonds and 5 to 50 carbon atoms,
a: 1, 2 or 3;
b: 0, 1 or 2;
c: 0 or 1;
x: whole number, the maximum value of which corresponds to the number of double bonds in the compound B minus 1,
Such silanes and polycondensates produced therewith are revealed in DE 40 11 044 A1.
Silanes of a general formula (B):
B{A-(Z)d—R1(R2)—R′—SiXaRb}c (B)
wherein said radicals and indices have the following meaning:
B=straight-chain or branched out organic radical with at least one C═C double bond and 4 to 50 carbon atoms;
R=alkyl, alkenyl, aryl, alkylaryl or arylalkyl;
R′=alkylene, arylene, arylenalkylene or alkylenarylene with respectively 0 to 10 carbon atoms, wherein these radicals can be interrupted by oxygen and sulfur atoms or by amino groups;
R1=nitrogen, alkylene, arylene or alkylenarylene with respectively 1 to 10 carbon atoms, wherein these radicals can be interrupted by oxygen or sulfur atoms or by amino groups;
X=hydrogen, hydroxy, alkoxy, acyloxy, alkylcarbonyl, alkoxycarbonyl or —NR″2;
R″=alkyl or aryl;
Z═CO or CHR, with R equal to H, alkyl, aryl or alkylaryl;
a=1, 2 or 3;
b=0, 1 or 2;
c=1, 2 or 3
d=0 or 1
Such silanes and silicic acid polycondensates produced therewith are revealed in DE 44 16 857 C1.
Silanes of a general formula (C)
wherein said radicals and indices have the following meaning:
B=organic radical with at least one C═C double bond;
R=alkyl, alkenyl, aryl, alkylaryl or arylalkyl;
Ro and R′ respectively=alkylene, alkenylene, arylene, alkylenarylene or arylenalkylene;
X=hydroxy, alkoxy, acyloxy, alkylcarbonyl, alkoxycarbonyl or —NR″2 with R″ equal to hydrogen, alkyl or aryl;
a=1, 2 or 3
b=1, 2 or 3, with a+b=2, 3 or 4;
c=0 or 1;
d=1, 2, 3, 4, 5, 6, 7, 8, 9 or 10;
e=1, 2 or 3 or 4; with e equal to 1 for c=0.
Said silanes of formula (C) and silicic acid polycondensates capable of being derived thereof are revealed in DE 199 10 895 A1. Silanes of a general formula (D):
{B′—Z′—R1(B)—R—}a(R)bSiX4-a-b (D)
wherein said radicals and indices have the following meaning:
R is an alkylene, arylene or alkylenarylene group, which can be interrupted by one or more oxygen or sulfur atoms or carboxyl or amino groups, or can carry such atoms/groups on its end facing away from the silicon atom;
R1 is an alkylene, arylene or alkylenarylene group substituted by Z′, which can be interrupted by one or more oxygen or sulfur atoms or carboxyl or amino groups, or can carry such atoms/groups on one of its ends;
R′ is an alkyl, alkenyl, aryl, alkylaryl or arylalkyl group;
B and B′ can be equal or different; both radicals have the meaning of a straight-chain or branched organic group with at least one C═C double bond and at least two carbon atoms;
X is a group, which can enter a hydrolytic condensation reaction through the formation of Si—O—Si bridges (with the exception of hydrogen and halogen);
Z′ have the meaning —NH—C(O)O—, —NH—C(O)— or —CO(O)—, wherein both of the initially mentioned radicals are bonded to radical B′ by an NH group, while a carboxylate group can point in both directions;
a represents 1 or 2 and
b is 0 or 1;
Such silanes and polycondensates capable of being derived thereof are revealed in DE 103 49 766 A1.
Silanes of a general formula (E):
(XaRbSi)m[—{B}—([O]oP[O]pR′cYd)n]4ab (E)
wherein said groups, radicals, and indices have the following meaning:
B is at least a double-bonded, straight-chain or branched group with at least one organically polymerizable radical and at least 3 carbon atoms,
X is a radical or OH capable of being hydrolyzed off a silicon atom (with the exception of hydrogen and halogen),
R and R′ are independent and potentially substituted alkyl, alkenyl, aryl, alkylaryl or arylalkyl,
a is 0, 1, 2 or 3,
b is 0, 1 or 2, wherein a+b together are 1, 2 or 3,
c is 0, 1 or 2,
d is 0, 1 or 2,
c+d together are 2,
m is at least 1, with the stipulation that m is not greater than 1 if a+b represents 1 or 2,
n is at least 1,
o is 0 or 1, and
p is 0 or 1,
Silanes of formula (E) and silicic acid polycondensates derived thereof are revealed in DE 101 32 654 A1.
Silanes of a general formula (F):
wherein said radicals and indices are equal or different and have the following meaning:
R is hydrogen, R2—R1—R4—SiXxR33-x, carboxyl, alkyl, alkenyl, aryl, alkylaryl or arylalkyl,
R1 and R2 are independent alkylene, arylene, arylenalkylene or arylenalkylene,
R3 is alkyl, alkenyl, aryl, alkylaryl or arylalkyl,
R4 is —(CHR6—CHR6)n— with n=0 or 1, CHR6—CHR6—S—R5—, —C(O)—S—R5—, CHR6—CHR6—NR6—R5, —Y—C(S)—NH—R5, —S—R5, —Y—C(O)—NH—R5—, —C(O)—O—R5—, —Y—CO—C2H3(COOH)—R5—, —Y—CO—C2H3(OH)—R5— or —C(O)—NR6—R5,
R5 is alkylene, arylene, arylenalkylene or arylenalkylene,
R6 is hydrogen, alkyl or aryl with 1 to 10 carbon atoms,
R9 is hydrogen, alkyl, alkenyl, aryl, alkylaryl or arylalkyl,
X is hydroxy, alkoxy, acyloxy, alkylcarbonyl or alkoxycarbonyl;
Z is —O— or —(CHR6)m with m equal to 1 or 2;
a is 1, 2 or 3, with b=1 for a=2 or 3
b is 1, 2 or 3, with a=1 for b=2 or 3
c is a whole number from 1 to 6,
x is 1, 2 or 3 and
a+x are 2, 3 or 4.
These silanes and silicic acid polycondensates derived thereof are revealed in DE 196 27 198 A1.
Additional silicic acid (hetero) polycondensates usable pursuant to the invention comprise (meth)acrylic radicals and either sulfonate or sulfate groups that are respectively bonded directly or indirectly to a silicon atom via a non-substituted or substituted hydrocarbon group with a C—Si bond. These condensates can be produced, for example, from silanes of a formula (G),
R1aR2bSiZ4-a-b (G)
wherein R1 is a hydrolytically condensable radical, R2 is substituted or non-substituted, straight-chained, branched or a cycle having alkyl, aryl, arylalkyl, alkylaryl or alkyl/arylalkyl or is a respective alkenyl, a carbon chain of may be interrupted in any event potentially by —O—, —S—, —NH—, —S(O)—, —C(O)NH—, —NHC(O)—, —C(O)O— —C(O)S, —NHC(O)NH— or C(O)NHC(O) groups, which may potentially point in both possible directions, Z is a radical, in which at least one (meth)acrylic group and at least either one sulfonate or one sulfate group is bonded directly or indirectly to a silicon atom via a non-substituted or substituted hydrocarbon group with a C—Si bond, a is 1, 2 or 3, b is 0, 1 or 2, and a+b together are 2 or 3. Specific silanes of said formula (G) have a following formula (G′)
wherein
R3 is an alkylene, which is non-substituted or substituted with a functional group, straight-chained, branched, or having at least one cycle,
A represents a linkage group,
R4 represents an alkylene, which is potentially interrupted by O, S, NH or NR8 and/or potentially functionally substituted,
M is hydrogen or a monovalent metal cation or a respective share of a polyvalent metal cation, preferably selected from Na, K, ½Ca, ½Mg and ammonium,
R5 and R6 independently have either the meaning of R1 or are alkyl, aryl, arylalkyl, alkylaryl or alkyl/arylalkyl, which are substituted or non-substituted, straight-chained, branched, or having at least one cycle; as an exception, however, may instead be a respective alkylene, arylalkylene or alkylenaryl,
R7 is a hydrocarbon group bonded to a silicon atom via a carbon atom, as was described further above,
R8 is C1-C6-alkyl or (meth)acrylic,
B is vinyl, 2-allyl or, in the case of e>1, an organic radical having e vinyl groups, which are respectively bonded to a group within the curly brackets
Y is a nitrogen atom, —O—CH═, —S—CH═ or —NH—CH═, wherein said oxygen atom, sulfur atom or said NH group has a bond to the neighboring C(O) group,
b=0 or 1
c=0 or 1
with the stipulation that, for the combination of Y equal to a nitrogen atom, b=0 and c=0 of said radical R3, as well as the stipulation that, for the combination of Y equal to a nitrogen atom, b=0 and c=1 of said radical R4 represents an alkylene interrupted by O, S, NH or NR8, and which is potentially functionally substituted,
d=0 or 1, and
e=1, 2 or 3.
Such materials are revealed in application DE 10 2011 050 672.1, which has not yet been published.
Additional silicic acid (hetero) polycondensates usable pursuant to the invention can be produced through a process, wherein a silane or siloxane having a radical bonded via a carbon atom to a silicon atom, which bears at least two functional groups, wherein a first functional group of the two is an unsaturated, organically polymerizable group and a second functional group of the two is selected from (a) additional unsaturated, organically polymerizable groups, (b) COOR8 or
—(O)bP(O)(R5)2 and (c) —OH, with R8 equal to R4 or M1/xx+, wherein Mx+ is hydrogen or an x-fold positively charged metal cation, and b=0 or 1, is converted with a compound of a formula (H)
X—W—(Z)a (H)
wherein X is SH, NH2 or NHR4, Z is OH, a carboxylic acid radical —COOH or a salt or an ester of this radical or a silyl radical, W is a substituted or non-substituted hydrocarbon radical, the chain of which can be interrupted by —S—, —O—, —NH—, —NR4—,
—C(O)O—, —NHC(O)—, —C(O)NH—, —NHC(O)O—, —C(O)NHC(O)—, —NHC(O)NH—, —S(O)—, —C(S)O—, —C(S)NH—, —NHC(S)—, —NHC(S)O—, and a represents 1, 2, 3, 4 or a greater whole number, wherein R4 is a non-substituted or substituted hydrocarbon radical or OR6, R6 is hydrogen or a non-substituted or substituted hydrocarbon radical. The product of the first reaction is then converted in a second reaction with a compound (J)
Y—(W)k—(R1)b (J)
wherein Y is NCO, epoxy or—said radical or radicals Z is/are (a) hydroxy group(s) in the product of the first reaction—COA′, W is defined for compound (H) as above, R1 is unsaturated, organically polymerizable group, A′ is hydroxy, a halogenide or —OC(O)R4 with R4 equal to a non-substituted or substituted hydrocarbon radical, k=0 or 1, wherein k=0 is only possible in the event that Y represents COA′ and b=1 or greater than 1.
This process is described in patent application DE 10 2011 053 865.8, which has not yet been published. If, in the process, silanes are used as output materials, a hydrolytic condensation will occur prior to, during or after any of the specified process steps.
The materials pursuant to the invention involve either masses comprised of organically polymerizable silicic acid (hetero) polycondensates, which, e.g. may be modified to achieve a higher degree of organic cross-linking—potentially with organic compounds (e.g. organic polymers) or other materials, or composites, i.e. polymerizable silicic acid (hetero) polycondensates potentially modified with organic compounds/materials, which are filled with filler materials. The filler materials can have any form and be especially particle-like and/or fibrous (particularly short fibers). The filler materials, for example, that are described in DE 196 43 781, DE 198 32 965, DE 100 184 05, DE 100 41 038, DE 10 2005 061 965, and DE 10 2005 018 305 are suitable. In necessary, a very high filler material content can be achieved.
The condensates are hardened via the above-presented polymerization reaction of groups containing double bonds and/or have rings. As an initiator for the thermal hardening, dibenzoyl peroxide (DBPO) is normally released in the respective resin system; other suitable hardeners are naturally likewise possible, such as those known from the state of the art. An organic cross-linking may occur through the addition of dimeric or oligomeric organic compounds to respective C═C double bonds, e.g. of thiols or amines with two or more thiol or amino groups. If thiols or amines in the deficit with regard to the available double bonds are used, remaining double bonds can be subsequently hardened.
For the incorporation of the filler, e.g. a three-roll mill or a planetary mixer can be used depending on the viscosity of the mixture. As such, the following methods were taken for the concrete design examples:
The invention will be explained in further detail based on the following design examples:
Synthesis of Resin System A (from DE 44 16 857)
For receiving 125.0 g (0.503 mol) of 3-Glycidyloxypropyltrimethoxysilane, triphenylphosphine (as a cat.), BHT (as a stabilizer), and then 47.35 g (0.550 mol) of methacrylic acid are added drop-wise in a dry atmosphere and stirred at 80° C. (approx. 24 hrs.). The reaction can be followed by the decrease in the concentration of carboxylic acid via acid titration and the epoxy conversion can be followed via Raman spectroscopy/epoxy titration. The band of epoxy silane characteristic for the epoxy group appears in the Raman spectrum at 1256 cm−1. The epoxy or carboxylic acid conversion is at ≧99% or ≧89% (→because 1:1.1 is a carboxylic acid surplus). After adding acetic ester (1000 ml/mol of silane) and H2O for hydrolysis with HCl (as a cat.), it is stirred at 30° C. The progress of the hydrolysis is respectively followed via water titration. Processing occurs approximately after multiple days of stirring through repeated extraction with aqueous NaOH and with water and filtration via hydrophobized filters. A rotary evaporator is used first and then an oil pump vacuum is used for suctioning. This results in a liquid resin without the use of reactive thinners (monomers) having a very low viscosity of approx. 3-6 Pas at 25° C. (heavily dependent upon exact hydrolysis and processing conditions) and 0.00 mmol of CO2H/g (no free carboxyl groups).
Synthesis of Resin System B (from DE 103 49 766.8)
For receiving 53.1 g from Resin System A and 0.20 g of BHT, 21.7 g of methacrylic acid isocyanatoethyl ester are added drop-wise while stirring in a dry atmosphere at 30° C. and continually stirred at 30° C. The result is a liquid resin having a viscosity of approx. 22-28 Pas at 25° C. (heavily dependent upon precise synthesis and processing conditions, particularly the preliminary stages).
For receiving 174.2 g (0.65 mol) of Resin System A and 0.51 g of DABCO, 70.1 g of methacrylic acid anhydride are added drop-wise while stirring and continually stirred at 60° C. The reaction can be followed via NMR and by the decrease of anhydride bands via IR spectrum. Following the usual processing for separating the methacrylic acid released upon being added as well as the extraction of volatile components with the oil pump vacuum, a liquid resin emerges having a viscosity of approx. 2.1-2.4 Pa·s at 25° C. (heavily dependent upon precise synthesis and processing conditions, particularly the preliminary stages).
For receiving 80.4 g (0.18 mol) of Resin System A and potentially 0.17 g of triethylamine, 8.96 g (0.276 mol) of 3-Mercaptopropane-1,2-diol are added drop-wise while stirring. The reaction can be followed via NMR and by the decrease of an HS band via IR spectrum. The band characteristic for said HS group appears in the Raman spectrum at 2566 cm−1. The result is a liquid resin having a viscosity of approx. 16-18 Pas at 25° C. (depending on the exact synthesis and processing conditions of the preliminary stages). Additional processing is normally not necessary.
For receiving 41.8 g from the example of the 1st stage and potentially 0.12 g of BHT, 27.2 g (1.25 mol) of methacrylic acid isocyanatoethyl ester are added drop-wise while stirring in a dry atmosphere at 30° C. and continually stirred at 30° C. The result is a liquid resin.
For receiving 129.2 g (0.52 mol) of 3-Glycidyloxypropyltrimethoxysilane, triphenylphosphine (as a cat.), BHT (as a stabilizer), and then 47.35 g (0.550 mol) of methacrylic acid are added drop-wise in a dry atmosphere and stirred at approx. 80° C. (approx. 24 h). The reaction can be followed by the decrease in the concentration of carboxylic acid via acid titration and the epoxy conversion can be followed via Raman spectroscopy/epoxy titration. The band of epoxy silane characteristic for the epoxy group appears in the Raman spectrum at 1256 cm−1. After adding acetic ester (1000 ml/mol of silane) and H2O for hydrolysis with HCl (as a cat.), it is stirred at 30° C. and 22.2 g (0.10 mol) of methacryloxy-methyltrimethoxysilane are added slowly drop-wise. The progress of the hydrolysis is respectively followed via water titration. Processing occurs after two days of stirring through repeated extraction with aqueous NaOH and with water and filtration via hydrophobized filters. A rotary evaporator is used first and then an oil pump vacuum is used for suctioning. This resulted in a liquid resin without the use of reactive thinners (monomers) having a viscosity of approx. 45.6 Pas at 25° C. (heavily depending upon the exact synthesis and processing conditions).
Resin System E differs from Resin System A by the fact that the output materials subjected to hydrolytic condensation additionally have methacryloxy-methyltrimethoxysilane, which leads to a stronger inorganic cross-linking of the resulting system.
For receiving 26.8 g (0.10 mol) of Resin System A, e.g. DBTL (as a cat.), BHT (as a stabilizer) are added drop-wise in a dry atmosphere (oxygen) at room temperature subsequently while stirring 1.68 g (0.01 mol) of hexamethylene-1,6-diisocyanate and stirred at 30° C. The reaction can be followed by the decrease of the OCN band via IR spectrum. The band characteristic for the OCN group appears in the IR spectrum at 2273 cm−1. The result is a liquid resin having a viscosity of approx. 27 Pas at 25° C. (heavily dependent upon precise synthesis and processing conditions, particularly the preliminary stages).
The addition of hexamethylene-1,6-Diisocyanate leads to a stronger organic cross-linking of the resulting system.
Essential aspects are:
50% of Resin System A by weight+2% of DBPO
50% of Silmikron 810-10/1 filler material by weight (comprised of SiO2 by nearly 99% by weight), primary particle size: 0.5 μm, non-silanized (company: Quarzwerke)
Incorporation of the filler: 3 passes in a three-roll mill
Thermal hardening for 4 hours at 100° C.; 1 day of dry storage at 40° C.
Breaking strength: 100±5 MPa
Modulus of elasticity: 4.5±0.11 GPa
50% of Resin System A by weight+2% of DBPO
50% of Silbond 960-943 MST filler material by weight (comprised of SiO2 by nearly 99% by weight), primary particle size: 1.2 μm, silanized (company: Quarzwerke)
Incorporation of the filler: 3 passes in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
Breaking strength: 101±11 MPa
Modulus of elasticity: 5.1±0.08 GPa
50% of Resin System A by weight+2% of DBPO
50% of Silbond FW 600 MST filler material by weight (comprised of SiO2 by nearly 99% by weight), primary particle size: 4 μm, silanized (company: Quarzwerke)
Incorporation of the filler: 3 passes in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
Breaking strength: 113±8 MPa
Modulus of elasticity: 5.40±0.05 GPa
40% of Resin System A by weight+2% of DBPO
60% of Silbond FW 600 MST by weight (comprised of SiO2 by nearly 99% by weight), primary particle size: 4 μm, silanized (company: Quarzwerke)
Incorporation of the filler: 2× three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
Breaking strength: 126±10 MPa
Modulus of elasticity: 7.3±0.11 GPa
40% of Resin System A by weight+2% of DBPO
60% of a filler material mixture by weight (company: Quarzwerke)
40% of Resin System A by weight+2% of DBPO
60% of Silmikron 810-10/1 filler material by weight (comprised of SiO2 by nearly 99% by weight), primary particle size: 0.5 μm non-silanized (company: Quarzwerke)
Incorporation of the filler: 3 passes in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
Breaking strength: 148±8 MPa
Modulus of elasticity: 6.4±0.17 GPa
71.4% of Resin System A by weight+2% of DBPO
28.6% of Silmikron 810-10/1 by weight (comprised of SiO2 by nearly 99% by weight), primary particle size: 0.5 μm, non-silanized (company: Quarzwerke)
Incorporation of the filler: 1 pass in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
71.4% of Resin System A by weight+2% of DBPO
28.6% of Trisopor 4000 filler material by weight, non-silanized, porous glass, (267 nm pore size), amorphous, at least 90% of SiO2 (company: VitraBio)
Incorporation of the filler: 3 passes in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day dry at 40° C.
71.4% of Resin System A by weight+2% of DBPO
28.6% of Ultrafine filler material by weight, primary particle size: 0.40 μm, silanized (55% of SiO2 by weight,
25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) (Schott glass GM 27884)
Incorporation of the filler: 1 pass in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
71.4% of Resin System A by weight+2% of DBPO
28.6% Trisopor 400 filler material by weight, non-silanized, porous glass (40 nm pore size), amorphous, mind. 90% SiO2) (company: VitraBio)
Incorporation of the filler: 2 passes in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
50% of Resin System A by weight+2% of DBPO
50% of nanofine filler material by weight, primary particle size: 0.18 μm, silanized (55% of SiO2 by weight,
25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) (Schott glass GM 27884)
Incorporation of the filler: 1 pass in a three-roll mill, subsequently: vacuum process
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
75% of Resin System A by weight+2% of DBPO
25% of spray-dried nanoparticle filler material by weight, primary particle size: 70 nm, non-silanized (produced pursuant to DE 10 2005 061965). Incorporation of the filler: 1 pass in a three-roll mill
Thermal hardening for 4 hours at 100° C., 1 day of dry storage at 40° C.
30% of Resin System E by weight+2% of DBPO
70% of a filler material mixture by weight, silanized (65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight) (Schott glass G018-307), comprised of:
30% of Resin System E by weight+1% of Lucirin TPO
70% of a filler material mixture by weight, silanized (65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight) (Schott glass G018-307), comprised of:
30% of Resin System F by weight+1% of Lucirin TPO
70% of a filler material mixture by weight, silanized (65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight) (Schott glass G018-307), comprised of:
30% of Resin System B by weight+1% of Lucirin TPO
70% of a filler material mixture by weight, silanized (65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight) (Schott glass G018-307), comprised of:
15% of Resin System A by weight+1.5% of DBPO
85% of a filler material mixture by weight, silanized (55% of SiO2 by weight, 25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by (Schott glass GM 27884), comprised of:
12.5% of Resin System C by weight+1.5% of DBPO
One particularity of Resin System C is its relatively low viscosity—as a result, a higher filler material content is possible.
87.5% of a filler material mixture by weight, silanized (55% of SiO2 by weight, 25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) (Schott glass GM 27884), comprised of
18% nanofine, primary particle size: 0.18 μm (1 pass in a three-roll mill)
14% ultrafine, primary particle size: 0.40 μm (2 passes in a three-roll mill)
68% K6, primary particle size: 3.0 μm (2×15 min. in a planetary mixer, 20 RPM, temperature control 60° C.)
Thermal hardening according to temperature program I (depicted in
Breaking strength: 166±12 MPa
Modulus of elasticity: 13.8±0.65 GPa
Vicker hardness: 95 HV 0.5; 30 seconds
30% of Resin System B by weight+2% of DBPO
70% of a filler material mixture by weight, silanized (50% of SiO2 by weight, 1% of BaO by weight, 20% of SrO by weight, 15% of B2O3 by weight, 15% of Al2O3 by weight) (Schott glass GM 32087); from that
16% of Resin System B by weight+3% of DBPO
84% of a filler material mixture by weight, silanized (55% of SiO2 by weight, 25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) (Schott glass GM 27884); from that
16% of Resin System B by weight+2.5% of DBPO
84% of a filler material mixture by weight, silanized (55% of SiO2 by weight, 25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) (Schott glass GM 27884); from that
16% of Resin System B by weight+2% of DBPO
84% of a filler material mixture by weight, silanized (55% of SiO2 by weight, 25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) (Schott glass GM 27884); from that
30% of Resin System B by weight+2% of DBPO
70% of a filler material mixture by weight, silanized (65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight) (Schott glass G018-307), comprised of:
30% of Resin System F by weight+2% of DBPO
70% of a filler material mixture by weight, silanized (65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight) (Schott glass G018-307), comprised of:
100% of Resin System D by weight+1.2% of camphor chinon+1.8% of DABE
Photo-initiated hardening for 100 seconds on both sides, 1.5 days of dry storage at 40° C.
Breaking strength: 130±4 MPa
Modulus of elasticity: 2.7±0.09 GPa
100% of Resin System D by weight+1% of Lucirin TPO
Photo-initiated hardening for 100 seconds on both sides, 1.5 days of dry storage at 40° C.
Breaking strength: 132±4 MPa
Modulus of elasticity: 2.7±0.11 GPa
a/3b and 4a/4b respectively show a cut and polished crown.
15% of Resin System A by weight (basic NHB-1840)+1.5% of DBPO
85% of a filler material mixture by weight, silanized (55% of SiO2 by weight, 25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) (Schott glass GM 27884), comprised of:
18% nanofine, primary particle size: 0.18 μm (1 pass in a three-roll mill)
14% ultrafine, primary particle size: 0.40 μm (1 pass in a three-roll mill)
68% K6, primary particle size: 3.0 μm (2×15 min. in a planetary mixer, 20 RPM)
Thermal hardening for 3 hours at 100° C.
The obtained crowns are opaque with a certain translucency.
(Image of the crowns in
30% of Resin System A by weight (basic NHB-2304)+2% of DBPO
70% of filler material by weight, non-silanized 0.7 μm (65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight) (Schott glass GO 18-307)
Incorporation of the filler: Combination of the three-roll mill and planetary mixer
Thermal hardening for 4 hours at 100° C.
The obtained crowns are more translucent than those obtained pursuant to Example 4a.
(Image of the crowns in
As a composite for the production of the block, a composite made of Resin System A (p. 14 of the Description), 2% (dibenzoyl peroxide) of DBPO, and 72% of a filler material mixture by weight comprised of: 18% nanofine 180 (primary particle size 0.18 μm), 14% ultrafine 400 (primary particle size 0.40 μm), 68% K6 (primary particle size 3.0 μm), (GM 27884, company: Schott, composition: 55% of SiO2 by weight, 25% of BaO by weight, 10% of B2O3 by weight, 10% of Al2O3 by weight) was used. The filler materials were incorporated with respectively 3 passes in the three-roll mill at 130 RPM. The crown composite was then polymerized (i.e. thermally hardened) into blocks for 4 hours at 100° C. A bracket for the CAD/CAM device was adhered to the blocks.
In the next step, a steel tooth stump (for the pressure test) was scanned with the aid of the CAD/CAM device. With the software, a fully anatomical crown was virtually modeled from each block and then milled down from the present crown composite blocks. Subsequently, the milled down crowns were blasted with corundum (250 μm grain size) with 2 bar of pressure at a distance of 1 cm from the surface, coated with a bonding agent, and thermally activated. The use of a bonding agent is not compulsory. In lieu of using a bonding agent, the crown may undergo, for example, a strong abrasion. A combination of both methods is possible.
For the second, more translucent layer, a pasty material was made from Resin System A, 1% of Lucirin TPO, and 70% of a filler material mixture by weight, comprised of: 25% ultrafine 400 (primary particle size 0.40 μm), 75% K5 (primary particle size 5.0 μm), (G018-307, company: Schott, composition: 65% of SiO2 by weight, 15% of B2O3 by weight, <5% of Al2O3 by weight, 5% of K2O by weight, 10% of Cs2O3 by weight, 5% of La2O3 by weight, <5% of ZrO2 by weight). The filler materials were incorporated with respectively 3 passes in the three-roll mill at 130 RPM. The material was excessively applied to the previously milled down crowns and polymerized using a dental blue light halogen spotlight and thus hardened. The crowns prepared in this manner were then reinserted into the CAD/CAM device and milled fully anatomically.
Example 5 was repeated with the modification that the crown composite was milled fully anatomically and no second, translucent coating was applied.
With the processes specified for Examples 5 and 6, a fully anatomically milled crown was produced from commercially available feldspar ceramic.
Due to the 2-layer design, the crowns produced pursuant to Example 5 have a significantly higher esthetic than crowns pursuant to Example 6.
To determine the load capacity of the crowns produced according to the examples and the comparison example, a pressure test (see
For the crowns pursuant to Example 5, the maximum test force after being dry stored for 3 days at 40° C. was 2280±120 N. The crowns broke cohesively, i.e. a spalling of the outer, subsequently applied coating was not be detected.
The maximum test force of fully anatomical crowns pursuant to Example 6 force after being dry stored for 3 days at 40° C. was 2590 N±420 N.
The maximum test force of fully anatomical crowns made from commercially available feldspar ceramic was 2400 N±540 N directly after being produced.
Number | Date | Country | Kind |
---|---|---|---|
102011054444.5 | Oct 2011 | DE | national |
102012202005.5 | Feb 2012 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2012/070042 | 10/10/2012 | WO | 00 | 4/9/2014 |