Amorphous Polyester Urethane Networks Having Shape Memory Properties

The invention under consideration relates to cross-linked, preferably biodegradable polyester urethanes with shape memory properties.

STATE OF THE ART

Biodegradable, covalent polymer networks with shape memory properties are usually obtained by means of free radical polymerization of, e.g., macrodimethacrylates. This method of production comprises a total of three steps: synthesis of macrodiols, methacrylation of the terminal groups and radical cross-linking.

The radical reaction mechanism is subject to a random process in which the microscopic structure of the cross-link points can be regulated only to a limited degree, so that structural heterogeneities can arise in the networks. Furthermore, with a chain reaction of that type, regulation and checking of the reaction is difficult, so that even if the starting materials in the network itself are very uniform, widely varying areas may be present, e.g., areas having a high cross-link density and areas having a lower cross-link density. This affects the use of materials of this type in some application areas, however. At the same time, such heterogeneities can also lead to variability in the physical properties.

OBJECT OF THE INVENTION

The object of the invention under consideration is, therefore, to provide a new material and accompanying method for production with which the disadvantages of the state of the art can be overcome.

SHORT DESCRIPTION OF THE INVENTION

The object described above was solved by means of the polyurethane network according to Claim 1, as well as by means of the method defined in Claim 10. Preferred embodiments are specified in the sub-claims.

DETAILED DESCRIPTION OF THE INVENTION

In order to avoid structural heterogeneities in the networks, the invention under consideration provides a novel system of amorphous polymer networks comprising one or several segments with shape memory properties. The networks are preferably composed of biodegradable and biocompatible components and they open up the possibility for use in the medical domain. The systemic character of the materials allows the thermal and mechanical properties, as well as the decomposition behavior, to be adjusted in a specific manner. In particular, the invention under consideration makes it possible to produce polyphase amorphous networks.

In contrast to the already developed biodegradable, covalent polymer networks with shape memory properties, which are obtained by means of free radical polymerization of, for example, macro-dimethacrylates, the invention under consideration calls for the use of a different method of production, namely polyaddition. In this process, a total of only two synthesis steps are necessary: synthesis of macrotriols or macrotetrols and polyaddition.

The networks according to the invention are based on star-shaped prepolymers with hydroxyl terminal groups, which are produced using known methods. This procedure makes it possible to produce structurally uniform networks (particularly even on a larger scale). By means of starting the production with multifunctional prepolymers, it is possible to ensure a very high degree of homogeneity of the networks, because the essential parameters of the networks can be specified just by the comparably low-molecular parent compounds as a result of the number of possible coupling points and the chain lengths of the prepolymers, which simplifies the control. At the same time, the cross-link points themselves are also already pre-shaped, which further facilitates the control.

The networks according to the invention comprise multifunctional constitutional units (derived from the abovementioned prepolymers), preferably trifunctional and/or tetrafunctional constitutional units, each of which preferably has a hydroxyfunctionality at the reactive ends or an equivalent grouping before the production of the network. The production of the network then takes place by reaction with a suitable diisocyanate or another suitable compound, preferably with a slight excess of diisocyanate.

The multifunctional constitutional units (prepolymers) comprise a central unit, which corresponds to the later cross-link points in the network. This central unit is preferably derived from suitable low-molecular multifunctional compounds, preferably with three or more hydroxyl groups, in particular, three to five and, more preferably, three or four hydroxyl groups. Suitable examples are pentaerythritol and 1,1,1-tris(hydroxymethyl)ethane. An appropriate number of prepolymer chains (corresponding, for example, to the number of hydroxyl groups) is bound to this central unit, wherein these chains preferably comprise monomer units bound by ester bonds and/or monomer units bound by ether bonds. Preferred examples are chains on the basis of lactic acid, caprolactone, dioxanone, glycolic acid and/or ethylene glycol or propylene glycol.

Preferred in this case are, in particular, chains of lactic acid (D or L or DL), optionally in combination with one of the other abovementioned acid constitutional units (as block copolymers or as statistical copolymers, wherein statistical copolymers are preferred). Alternatively, the chains comprise segments from the acid constitutional units (in the possible combinations mentioned above), together with segments from the ether constitutional units, wherein a combination with a polypropylene glycol segment is particularly preferred here. Preferably, such constitutional units possess two segments in each chain: a polyester segment and a polyether segment (particularly polypropylene glycol), wherein it is preferred for the polyether segment to be provided at the central unit, with the polyester segment affixed thereto, so that the chain ends are formed by the polyester segment.

The prepolymers normally have a number-average molecular weight (determined by GPS) of from 1,000 to 20,000 g/mol, preferably from 2,500 to 15,000 g/mol, particularly from 5,000 to 12,000 g/mol and furthermore preferably from 8,000 to 11,000 g/mol. In the case of prepolymers with segments of polyether units, the segments of polyether units preferably have a number-average molecular weight of from 1,000 to 6,000, and the polyester segments coupled thereto have a number-average molecular weight of from 1,000 to 12,000 g/mol, so that these prepolymers altogether again have a number-average molecular weight as described above.

Because prepolymers of this type can be produced by means of easily controlled methods, the prepolymers used in accordance with the invention preferably have a relatively large degree of homogeneity (PD), preferably in the range of from 1 to 2, particularly from 1 to 1.5. A good degree of homogeneity of this type also gives the networks according to the invention a good degree of homogeneity.

It is particularly preferred if the prepolymers have lactic acid units (lactate units). If further acid constitutional units are present, the lactate units preferably account for the greater portion of the acid units in the polyester segment. For the other abovementioned acid constitutional units, preferred proportions, in addition to lactate units, are as follows:

• • Glycolate: 0 to 55% by mass, preferably 10 to 30% by mass.
  • Caprolactone or dioxanone: 0 to 45% by mass, preferably 10 to 25% by mass, particularly roughly 15% by mass.

    
    
    

    The respective proportions can easily be adjusted by checking the quantity of monomers in the production of the prepolymers.

The prepolymers constructed as described above are reacted into the networks according to the invention by a polyaddition reaction. In this process, the reaction with the diisocyanates results in a chain linkage to the hydroxyl groups at the ends of the multifunctional prepolymers, so that the chains are then connected via diurethane units. Because of the hydrolysis sensitivity of the individual segments, this results in the development of a network that can be biodegradable, particularly in the physiological area. The selection of the components for the prepolymers furthermore particularly also allows the production of amorphous networks. In particular, the use of lactic acid (preferably DL form) and the use of atactic polypropylene glycol allow the production of completely amorphous networks.

In this process, the decomposition behaviour can be controlled by means of the proportion of individual monomers. Glycolate units, caprolactone units and dioxanone units generally delay the decomposition reaction.

Furthermore, the mechanical property profile of the network can also be controlled by means of the chain length and the respective proportion of monomers. Low molar masses of the prepolymers normally lead to networks with a high cross-link density, which can possibly have low mechanical stabilities, however. In return, the swelling capacity of such networks is limited.

The introduction of glycolate units, caprolactone units and/or dioxanone units furthermore allows control of the transition temperature and therefore the switch temperature for the shape memory effect (the shape memory effect is already extensively described in the state of the art; in this context, therefore, reference is merely made to the already existing literature, e.g., further patent applications made by the Mnemoscience company). In this way, desired switch temperatures can be selectively adjusted for an application.

The prepolymers according to the invention additionally also allow the production of phase-segregated networks, which is advantageous for some application areas. The following strategies lend themselves to the production of such phase-segregated networks.

• 1. Prepolymers according to the invention having only polyester segments are reacted with diisocyanate in the presence of polyether macromonomers with unsaturated terminal groups. These polyether macromonomers are then photochemically cross-linked, resulting in an IPN.
• 2. Prepolymers according to the invention having both polyester segments and polyether segments are reacted with diisocyanate. The result is a network with segregated phases.
• 3. Prepolymers according to the invention having only polyester segments are reacted with diisocyanate with prepolymers with only polyether segments. The result is a network with segregated phases, wherein, unlike in 2., polyester segments and polyether segments are not present in one prepolymer, but instead in separate prepolymers, coupled via diurethane units.
• 4. Prepolymers according to the invention having only polyester segments are reacted with diisocyanate. The resulting network is swollen in the presence of acrylate monomers and the acrylate monomers intercalated in this way are then photochemically cross-linked into a network, resulting in an IPN.

  
  
  

  Preferred molecular weights for the macromonomers (1.) correspond to the values specified above for the polyether segment in the prepolymer. Also preferred here is a polypropylene glycol segment.

Preferred acrylate monomers for option 4. are ethyl acrylate, butyl acrylate, hexyl acrylate and hydroxyethyl acrylate, as well as the corresponding methacrylates. The total mass proportion in the resulting IPN for these monomers preferably amounts to from 1 to 35% by mass, more strongly preferred from 8 to 25% by mass. Hydroxyethyl acrylate particularly allows an adjustment of the hydrophilicity of the IPN.

Preferred networks according to the invention are as follows:

• • Type I: Polymer networks of triols or tetrols and diisocyanate,
  • Type II: Polymer networks of triols and tetrols and diisocyanate,
  • Type III: Polymer networks of triols or tetrols with diisocyanate and an interpenetrating network of a macrodimethacrylate,
  • Type IV: Sequential interpenetrating polymer networks of a network of triols or tetrols with diisocyanate and subsequently polymerized low-molecular acrylates.

    
    
    

    The networks according to the invention can be used in all areas in which biocompatible or degradable materials are used, e.g., in the medical area.

The networks according to the invention can possess additional constituents, such as filling substances, biologically active substances, colouring substances, diagnostics, etc. The use of such additional constituents depends on the particular purpose.

SHORT DESCRIPTION OF THE FIGURES

FIG. A shows the glass temperature of the polyurethane networks (Type 1) with oligo[(rac-lactate)-co-glycolate] segments having various segment lengths.

FIG. B illustrates the restoration behaviour (shape memory effect) of a previously elongated network (Type 1) with oligo[(rac-lactate)-co-glycolate] segments in the heating process.

FIG. C shows the glass temperature of the polyurethane networks (Type 1) with oligo(lactate-co-hydroxycaproate) and oligo(lactate-hydroxyethoxy acetate) segments with variable lactate content.

FIG. D illustrates the restoration behavior (shape memory effect) of several polyurethane networks (Type 1) from FIG. C in the heating process.

FIG. E represents the thermal properties of the multiphase polymer networks (Type 1) with oligo(propylene glycol) and oligo(lactate-co-glycolate) segments.

FIG. F is a schematic depiction of the fixation of a pre-IPN by the subsequent cross-linking of the additional component (Type III).

FIG. G shows the swelling capability of an IPN (Type IV) in water with a variable proportion of 2(hydroxyethyl) acrylate.

PRODUCTION OF THE NETWORKS

The networks according to the invention can be simply obtained by means of the reaction of the prepolymers with diisocyanate in solution, e.g., in dichloromethane, and subsequent drying (Types 1 and II). In the production of the IPN with a second network of acrylate monomers, the network according to the invention is swollen in monomers after the production, whereupon the cross-linking of the monomers (Type IV) follows. In the case of the IPN with a second network of polypropylene glycol macromonomers, the network according to the invention is produced in the presence of the macromonomers (in solution, as described above), which are subsequently cross-linked (Type III). In principle, mass polymerization is also possible, i.e., crosslinking reactions without the use of a solvent. This option is particularly useful in view of a processing of the materials according to the invention in injection moulding, because the thermoplastic starting materials are shaped in this process, whereupon the crosslinking into the desired shape follows.

EXAMPLES

The following examples illustrate the invention under consideration.

Abbreviated designations of the oligomers and the polymer networks

Cooligomers of the rac-dilactide

• X Initiator of the ring-opening polymerization

E Ethylene glycol

P Pentaerythrite

T 1,1,1-Tris(hydroxymethyl)ethane

• L rac-lactate
• Y Comonomer units

C ε-hydroxycaproate

D β-hydroxyethoxy acetate

G Glycolate

• μ_Y Proportion by mass of the comonomer Y according to ¹H-NMR relative to the total mass of the repeating units without initiator segment in % by mass
• Z According to the initial weight of the reactands, expected number-average molar mass of the oligomers in g·mol⁻¹ rounded to 1,000 g·mol⁻¹

  
  
  

  Oligo(propylene glycol)

F-PPG-Z

• F Terminal groups

D Diol

M Dimethacrylate

T Triol

• PPG Oligo(propylene glycol)
• Z Number-average molar mass of the hydroxyfunctional oligomers according to manufacturer's information, in g·mol⁻¹; exception: M-PPG-560: in this case, Z is the number-average molar mass of the macrodimethacrylate according to manufacturer's information, in g mol⁻¹

  
  
  

  Star-{oligo(propylene glycol)-block-oligo[(rac-lactate)-co-glvcolate]}triols

T-PPG-Z-b-LG-Z

• T-PPG Commercially obtainable oligo(propylene glycol)triol prepared by initiation with glycerin
• Z Number-average molar mass of the oligo(propylene glycol)triol used according to manufacturer's information, in g·mol⁻¹
• b Block sequence structure
• LG Oligo[(rac-lactate)-co-glycolate] segment with 15% by mass glycolate according to initial weight
• Z According to the initial weight of the reactands, expected number-average molar mass of the star-{oligo(propylene glycol)-block-oligo[(rac-lactate)-co-glycolate]}triol, in g·mol⁻¹

Networks (Except for Interpenetrating Polymer Networks)

The designations for the prepolymers used with the prefix N apply.

An exception is given by the networks that are produced by polyaddition of mixtures of oligo(propylene glycol)triols, oligo[(rac-lactate)-co-glycolate] tetrols and TMDI. In this case, the following abbreviated designations apply:

N-T-PPG(μ_PPG)-Z-LG

• N Network
• T-PPG Commercially obtainable oligo(propylene glycol)triol prepared by initiation with glycerin
• μ_PPG Proportion by mass of the oligo(propylene glycol) triol used, relative to the total mass of the prepolymers, in % by mass
• Z Number-average molar mass of the oligo(propylene glycol) triol according to manufacturer's information, in g·mol⁻¹
• LG Oligo[(rac-lactate)-co-glycolate] tetrol P-LG(17)-10000

The networks N-EA, N-BA and N-HEA form additional exceptions. These are networks that are obtained by means of photochemically initiated polymerization of ethyl acrylate, butyl acrylate or (2-hydroxyethyl)acrylate. A volume of 0.5% by volume of the oligo(propylene glycol)dimethacrylate M-PPG-560 and the photoinitiator 2,2′-dimethoxy-2-phenylacetophenone (10 mg/mL) is added to the acrylates.

Interpenetrating Polymer Networks

N-LG-ipX-N-Y(μ_Y)-Z

• N-LG Network of N-P-LG(17)-10000 and TMDI
• ip Interpenetrating polymer network
• X Number of steps in which swelling and radiation take place (optional); if X=1, not explicitly mentioned
• N-Y Network of oligo(propylene glycol)dimethacrylate and the component Y:

  • EA Ethyl acrylate
  • BA Butyl acrylate
  • HEA (2-hydroxyethyl)acrylate
  • M-PPG Oligo(propylene glycol)dimethacrylate

• μ_Y Proportion of the component Y in % by mass; in the case of in situ sequential IPNs, according to the initial weight of oligo(propylene glycol)dimethacrylate
• Z Molar mass of the oligo(propylene glycol)diol used in the synthesis of the macrodimethacrylate; if M-PPG-560 is used, not explicitly mentioned

In the case of interpenetrating systems whose components Y are prepared in a non-cross-linked form, (pre-IPNs), the auxiliary N is dropped in front of this component.

Prepolymers (Macrotriols and Macrotetrols)

The preparation of star-shaped prepolymers such as oligo[(rac-lactate)-co-glycolate]triol or -tetrol is done by means of ring-opening copolymerization of rac-dilactide and diglycolide in the melting of the monomers with hydroxyfunctional initiators, with the addition of the catalyst dibutyltin (IV) oxide (DBTO). This synthesis path had proven to be suitable in the literature on the production of linear and branched oligomers with defined molar mass and terminal group functionality (D. K. Han, J. A. Hubbell, Macromolecules 29, 5233 (1996); D. K. Han, J. A. Hubbell, Macromolecules 30, 6077 (1997); R. F. Storey, J. S. Wiggins, A. D. Puckett, J. Polym. Sci.: Part A: Polym. Chem. 32, 2345 (1994); S. H. Kim. Y.-K. Han, Y. H. Kim, S. I. Hong, Makromol. Chem. 193, 1623 (1992)). Ethylene glycol, 1,1,1-tris(hydroxy-methyl)ethane or pentaerythrite are used as initiators of the ring-opening polymerization.

Oligo(lactate-co-hydroxycaproate) tetrols and oligo(lactate-hydroxyethoxy acetate) tetrols, as well as [oligo(propylene glycol)-block-oligo(rac-lactate)-co-glycolate)] triols are produced in a similar fashion.

TABLE 1

Composition and molecular weight of the prepolymers oligo[(rac-lactate)-co-glycolate]s. χ_G molar

proportion of glycolate units, μ_G mass proportion of glycolate units, number-average

relative molar mass M_n and polydispersity PD, according to ¹H-NMR spectroscopy (¹H-NMR), vapour

pressure osmometry (VPO) and gel permeation chromatography (GPC). The proportion by

mass of glycolate used in the reaction batch is μ_G—R and M_calc is the number-average molar

mass expected on the basis of the initial weight of the reactands.

M_n^b)

M_n

M_n

μ_G—R

χ_G^b)

μ_G^b)

M_calc

(¹H-NMR)

(VPO)

(GPC)

PD

Oligomer^a)

% by mass

mol %

% by mass

g · mol⁻¹

g · mol⁻¹

g · mol⁻¹

g · mol⁻¹

(GPC)

E-LG(15)-1000

15

18

15

1100

1100

n.d.

1200

1.56

E-LG(17)-2000

15

20

17

2100

2000

1800

2300

1.63

E-LG(15)-5000

15

18

15

5100

5000

n.d.^c)

5600

1.44

E-LG(17)-7000

15

20

17

7100

6200

4200

5400

1.67

E-LG(16)-9000

15

19

16

9100

9500

5600

7900

1.60

E-LG(15)-12000

15

18

15

12000

12500

4400

6200

1.75

T-LG(17)-1000

15

20

17

1100

980

n.d.^c)

970

1.49

T-LG(15)-2000

15

18

15

2100

2300

1900

2800

1.40

T-LG(17)-5000

15

20

17

5100

4500

3100

4400

1.43

T-LG(17)-7000

15

20

17

7100

6000

4200

7200

1.41

T-LG(16)-9000

15

19

16

9200

7900

7700

9600

1.42

T-LG(16)-10000

15

19

16

10100

9200

4700

6400

1.60

T-LG(18)-12000

15

21

18

12200

11700

6,000

7600

1.64

P-LG(17)-1000

15

20

17

1100

820

1300

760

1.92

P-LG(18)-2000

15

21

18

2100

2500

n.d.^c)

5400

1.11

P-LG(15)-5000

15

18

15

5100

4900

4000

7600

1.23

P-LG(15)-7000

15

18

15

7100

7300

4700

8000

1.30

P-LG(16)-9000

15

19

16

9100

8200

4200

6300

1.91

P-LG(17)-10000

15

18

17

10100

10500

5100

10800

1.60

P-LG(12)-12000

15

15

12

12100

10100

8700

14400

1.24

P-LG(0)-10000

0

0

0

10100

9200

6700

11100

1.21

P-LG(8)-10000

8

10

8

10100

11600

9200

13400

1.13

P-LG(13)-10000

10

16

13

10100

10500

9700

14000

1.27

P-LG(30)-10000

30

35

30

10100

10700

7400

9200

1.41

P-LG(48)-10000

50

53

48

10100

9700

6100

10800

1.36

P-LG(52)-10000

50

57

52

10100

9900

7800

12600

1.21

^a)Explanation of the abbreviations: see above.

^b)The molar proportion of glycolate units χ_G is calculated using the¹H-NMR spectra and converted into proportions by mass μ_G. The determination of the composition of the oligomers and the calculation of M_n according to ¹H-NMR are described in Chap. 12.2.1.

^c)n.d.: not determined

E = Ethylene glycol

P = Pentaerythrite

T = 1,1,1-tris(hydroxymethyl)ethane

TABLE 1a

Molar χ_D or mass proportion μ_D of β-hydroxyethoxy acetate, number-average molar mass

M_n, and polydispersity PD of the oligo[(rac-lactate)-co(β-hydroxyethoxy acetate)]s according

to ¹H-NMR spectroscopy (¹H-NMR), vapour pressure osmometry (VPO) and gel permeation chromatography

(GPC). The proportion by mass of β-hydroxyethoxy acetate used is μ_D—R and M_calc is the number-average

molar mass expected on the basis of the initial weight of the reactands according to Eq. 4.2.

The prepolymers are prepared by initiation with pentaerythrite.

M_n^b)

M_n

M_n

μ_D—R

χ_Db)

μ_D^b)

M_calc

(¹H-NMR)

(VPO)

(GPC)

PD

Oligomer^a)

% by mass

mol %

% by mass

g · mol⁻¹

g · mol⁻¹

g · mol⁻¹

g · mol⁻¹

(GPC)

P-LD(12)-1000

15

9

12

1100

980

1200

1300

1.58

P-LD(15)-2000

15

11

15

2100

2600

1800

2900

1.39

P-LD(13)-5000

15

10

13

5200

5900

3300

7100

1.32

P-LD(13)-7000

15

10

13

7200

7300

3500

8700

1.32

P-LD(12)-10000

15

9

12

10100

9500

4100

12300

1.37

P-LD(8)-10000

10

6

8

10100

6500

3900

11200

1.26

P-LD(17)-10000

20

12

17

10100

6300

4100

12300

1.37

P-LD(20)-10000

20

15

20

10100

7200

n.d.^c)

n.d.^c)

n.d.^c)

P-LD(25)-10000

30

19

25

10100

6900

4400

10900

1.29

P-LD(45)-10000

50

37

45

10100

10100

3200

11100

1.25

P-LD(65)-10000

70

56

65

10100

10000

2500

9400

1.21

^a)See above.

^b)The molar proportion of β-hydroxyethoxy acetate units χ_D is calculated by evaluating the ¹H-NMR spectra and converted into proportions by mass μ_D. The determination of the composition of the oligomers and the calculation of M_n according to ¹H-NMR.

^c)n.d.: not determined.

TABLE 2b

Proportion by mass μ_PPG of oligo(propylene glycol), number-average molar mass M_n according to ¹H-NMR

spectroscopy (¹H-NMR) or gas permeation chromatography (GPC) and polydispersity PD of

the star-{oligo(propylene glycol)-block-oligo[(rac-lactate)-co-glycolate]}

triols and the macroinitiators. M_calc is the number-average molar mass that is expected due to the

initial weight of the reactands. The number-average molar mass of the oligo[(rac-lactate)-co-

glycolate] segments is M_b-LG and the proportion of converted terminal groups of the oligo(propylene

glycol) triols D_P. The mass proportion of oligo(propylene glycol) used in the reaction batch is μ_PPG-R.

M_n^b)

M_n

μ_PPG-R

μ_PPG^b)

M_calc^c)

(¹H-NMR)

(GPC)

PD

M_b-LG^b)

D_P^b)

Oligomer^a)

% by mass

% by mass

g · mol⁻¹

g · mol⁻¹

g · mol⁻¹

(GPC)

g · mol⁻¹

%

T-PPG-1000

100

100

1000

930

1200

1.03

—

0

T-PPG-1000-b-LG-2000

50

41

2000

2300

2700

1.09

440

95

T-PPG-1000-b-LG-4000

25

22

4000

4200

6000

2.35

1100

>99

T-PPG-1000-b-LG-6000

17

14

6000

6500

6600

1.33

1900

>99

T-PPG-1000-b-LG-9000

11

10

9000

9000

8500

1.34

2700

>99

T-PPG-3000

100

100

3000

3400

3600

1.07

—

0

T-PPG-3000-b-LG-4000

75

82

4000

4200

6100

1.01

250

95

T-PPG-3000-b-LG-6000

50

54

6000

6500

11400

2.80

1000

98

T-PPG-3000-b-LG-9000

33

38

9000

9100

8700

1.41

1900

92

T-PPG-6000

100

100

6000

5600

7000

1.44

—

0

T-PPG-6000-b-LG-9000

67

60

9000

9300

13400

1.65

1300

86

T-PPG-6000-b-LG-12000

50

48

12000

11700

7600

2.56

2000

76

^a)See above.

^b)The determination of μ_PPG, D_P and M_n (¹H-NMR) is done using¹H-NMR spectroscopy.

^c)M_n of the macroinitiators according to the manufacturer's information is the basis for the values n_I and M_I.

Networks

The network synthesis takes place by means of polyaddition of the star-shaped macrotriols and tetrols with an aliphatic diisocyanate as a bifunctional coupling reagent (Type 1). Work is done here in solutions in dichloromethane. In standard experiments, an isomer mixture of 2,2,4 and 2,4,4 trimethylhexane-1,6-diisocyanate (TMDI), for example, is used as the diisocyanate. The intended purpose of the use of the isomer mixture is to prevent possible crystallization of diurethane segments. Also suitable are other diisocyanates.

Alternatively, mixtures of different prepolymers can be reacted with a diisocyanate, e.g., oligo(rac-lactate)-co(glycolate) tetrol with oligo(propylene glycol)triol and TMDI (Type II).

A different synthesis strategy is applied in the case of networks of Type III. In this case, a mixture of a tetrol, an oligo(propylene glycol)dimethacrylate and TMDI is produced. First the tetrol and the TMDI react together into a first network (pre-IPN). Subsequently, the radical cross-linking of the dimethacrylate is initiated by means of UV radiation, by means of which a second network is created (sequential IPN). As a result of the use of pre-IPNs, the permanent shape of the shape memory materials can be relatively easily and quickly adjusted to special requirements and geometries by means of UV radiation (FIG. F).

Another synthesis strategy consists of swelling a polyurethane network of Type I in an acrylate, and subsequently triggering a radical polymerization using UV light. Suitable are ethyl, butyl, hexyl or (2-hydroxyethyl)acrylate. In this way, one obtains an IPN of Type IV. Regardless of the acrylate used, two glass transitions are usually observed. When 2-(hydroxyethyl)acrylate is used, it is possible to adjust the hydrophilicity of the material (FIG. G). The bandwidth of medical applications of the prepared materials is expanded because of this possibility.

TABLE 2

Gel content G and degree of swelling Q in chloroform as well as

glass transition temperature T_g according to DSC (2^nd heating

process) of networks of P-LG(17)-1000 or P-LG(17)-10000 with various

diisocyanates or isomer mixtures of diisocyanates (Type 1).

M_n (prepolymer)

according to ¹H-

NMR

G

Q

T_g

Diisocyanate

Isomers

g · mol⁻¹

% by mass

% by vol.

° C.

—

820

100

n.d. ^d)

59

10500

96 ± 1

490 ± 0 

54

820

n.d. ^d)

160 ± 40

66

10500

98 ± 2

690 ± 70

53

820

100

n.d. ^d)

72

10500

98

470 ± 10

57

820

99

n.d. ^d)

75

10500

98

460 ± 10

57

820

97 ± 1

n.d. ^d)

80

10500

100

480

57

^a) Isomer mixture of 2,2,4 and 2,4,4-trimethylhexane-1,6-diisocyanate;

^b) cis/trans mixture of the isophorone diisocyanate,

^c) cis/trans mixture of the 4,4′-methylene-bis(cyclohexyl isocyanate),

^d) n.d.: not determined. Networks of P-LG(17)-1000 are destroyed during the swelling in chloroform, so that determination of G and Q are only possible with restrictions.

TABLE 2a

Gel content G and theoretical number-average molar mass M_c-ideal of the segments

of networks of oligo[(rac-lactate-co-(β-hydroxyethoxy acetate)] tetrols and TMDI

(Type 1). The values for M_C-ideal are calculated with the number-average molar mass of

the oligomers according to¹H-NMR spectroscopy. The number-average molar mass of the

free elastic chains M_c-affin and M_C-Phantom is determined by using the degree of

swelling Q in chloroform, on the basis of the affine or phantom network model.

G

Q

M_c-ideal

M_c-affin ^b)

M_C-Phantom ^b)

Network ^A)

% by mass

% by vol.

g · mol⁻¹

g · mol⁻¹

g · mol⁻¹

N-P-LD(12)-1000

100^c)

n.d. ^d)

700

n.d. ^d)

n.d. ^d)

N-P-LD(15)-3000

100

310

1500

1700

1100

N-P-LD(13)-5000

100

590

3200

7200

4200

N-P-LD(13)-7000

100

500 ± 10

3900

5000 ± 200

3000 ± 100

N-P-LD(12)-10000

92 ± 1

860 ± 50

5000

15400 ± 1600

 8700 ± 1000

N-P-LD(8)-10000

98 ± 0

610

3400

7600

4500

N-P-LD(17)-10000

93 ± 1

820 ± 10

3400

14000 ± 300 

8000 ± 200

N-P-LD(20)-10000

97 ± 1

560

3700

6400

3800

N-P-LD(25)-10000

91 ± 2

690 ± 30

3800

9900 ± 900

5700 ± 500

N-P-LD(45)-10000

93 ± 1

760 ± 30

5300

12000 ± 1000

6900 ± 500

N-P-LD(65)-10000

 90

870 ± 80

5200

15800 ± 2900

 8900 ± 1600

^a) See above.

^b) The solubility parameter δ_P is only insubstantially influenced by the β-hydroxyethoxy acetate content. For PPDO, a value of 19.0 MPa^0.5, which corresponds to the value for PDLLA, is determined according to the group contribution method with molar attraction constants according to Small. All calculations therefore take place with a value for the interaction parameter x of 0.34. The density of the amorphous networks ρ_p is always set equal to 1.215 g · cm⁻³.

^c) The determination of G is done by means of extraction with a mixture of diethyl ether and chloroform in a proportion by volume of roughly 1:1.

^d) n.d.: not determined. Networks are destroyed during the swelling process in chloroform.

TABLE 3b

Gel content G and mass-related degree of swelling S in chloroform

of networks of star-{oligo(propylene glycol)-block-oligo[(rac-

lactate)-co-glycolate]} triols and TMDI (Type I).

G

S

Network ^a)

% by mass

% by mass

N-T-PPG-1000

97 ± 2

n.d. ^b)

N-T-PPG-1000-b-LG-2000

97 ± 2

350 ± 10

N-T-PPG-1000-b-LG-4000

93 ± 4

870 ± 60

N-T-PPG-1000-b-LG-6000

94 ± 0

960 ± 10

N-T-PPG-1000-b-LG-9000

90 ± 1

1390 ± 130

N-T-PPG-3000

98 ± 1

700 ± 10

N-T-PPG-3000-b-LG-4000

94 ± 1

1330 ± 400

N-T-PPG-3000-b-LG-6000

73

3670

N-T-PPG-3000-b-LG-9000

58

3650 ± 780

^a) See above.

^b) n.d.: not determined, is destroyed during swelling in chloroform.

TABLE 2c

Gel content G and mass-related degree of swelling S in chloroform,

proportion by mass μ_PPG-R of oligo(propylene glycol) in reaction

batch and proportion by mass μ_PPG determined by means of¹H-NMR-

spectroscopy in networks of P-LG(17)-10000, oligo(propylene glycol)

triols of varying molar weight and TMDI (Type II).

μ_PPG-R

μ_PPG ^b)

G

S

% by

% by

% by

% by

Network ^a)

mass

mass

mass

mass

N-P-LG(17)-10000

—

—

98 ± 2

830 ± 80

N-T-PPG(10)-1000-LG

10

n.d. ^c)

98 ± 8

680 ± 70

N-T-PPG(20)-1000-LG

20

10

91 ± 1

740 ± 20

N-T-PPG(30)-1000-LG

30

28

94 ± 1

720 ± 30

N-T-PPG(50)-1000-LG

50

39

94 ± 7

 830 ± 130

N-T-PPG(70)-1000-LG

70

68

79 ± 3

1750 ± 70 

N-T-PPG-1000

100

n.d. ^c)

97 ± 2

n.d. ^c)

N-T-PPG(10)-3000-LG

10

n.d. ^c)

96 ± 8

810 ± 40

N-T-PPG(20)-3000-LG

20

16

92 ± 1

770 ± 40

N-T-PPG(30)-3000-LG

30

28

 92 ± 10

970 ± 20

N-T-PPG(50)-3000-LG

50

57

902 ± 12

1340 ± 90 

N-T-PPG(70)-3000-LG

70

n.d. ^c)

67

2640

N-T-PPG-3000

100

n.d. ^c)

98 ± 1

700 ± 10

^a) See above.

^b) Determined by means of¹H-NMR spectroscopic examinations after reaction of the contained networks with deuterated trifluoroacetic acid.

^c) n.d.: not determined.

TABLE 2d

Mass-related degree of swelling S in chloroform and proportion

by mass μ_PPG-R of oligo(propylene glycol) in reaction batch

of interpenetrating polymer networks of P-LG(17)-10000, TMDI and

M-PPG-560. For comparison, the mass-related degree of swelling

of the network N-P-LG(17)-10000 (Type III) is also shown.

μ_PPG-R

S ^b)

IPN ^a)

% by mass

% by mass

N-P-LG(17)-10000

0

830 ± 80

N-LG-ip-N-M-PPG(10)

10

 690 ± 190

N-LG-ip-N-M-PPG(20)

20

630 ± 30

N-LG-ip-N-M-PPG(30)

30

640 ± 40

N-LG-ip-N-M-PPG(50)

50

540 ± 20

^a) See above.

^b) IPNs break during the swelling.

TABLE 2e

Mechanical properties of network systems at 25° C. that are obtained by means of

coupling oligo[(rac-lactate)-co-glycolate] tetrols with TMDI and oligo(propylene

glycol) dimethacrylates before and after UV radiation has taken place. E is the E

module, σs the yield stress, ε_s the apparent yield point, σ_b the breakage

stress and ε_b the elongation at break.

E

σ_S

ε_s

σ_b

ε_b

Network ^a)

MPa

MPa

%

MPa

%

N-P-LG(17)-10000

340 ± 60

40.0 ± 5.0

 8 ± 3

36.2 ± 5.9

250 ± 210

N-LG-ip-M-PPG(10)

115 ± 40

17.1 ± 3.2

24 ± 8

15.1 ± 3.2

370 ± 115

N-LG-ip-M-PPG(20)

20 ± 3

—

—

11.5 ± 3.4

660 ± 200

N-LG-ip-M-PPG(30)

 15 ± 10

—

—

 8.4 ± 1.3

635 ± 115

N-LG-ip-M-PPG(50)

 1.5 ± 0.3

—

—

 2.2 ± 0.2

500 ± 125

N-LG-ip-N-M-PPG(10)

350 ± 10

35.4 ± 1.7

13 ± 3

27.5 ± 3.2

260 ± 110

N-LG-ip-N-M-PPG(20)

415 ± 90

39.3 ± 1.3

10 ± 2

36.2 ± 2.9

230 ± 20 

N-LG-ip-N-M-PPG(30)

270 ± 80

32.4 ± 3.5

17 ± 2

33.3 ± 6.8

225 ± 45 

N-LG-ip-N-M-PPG(50)

150 ± 30

23.2 ± 4.6

24 ± 3

28.1 ± 3.5

105 ± 20 

N-M-PPG-560

22 ± 7

—

—

 3.1 ± 1.0

15 ± 5 

^a) See above.

TABLE 3

Glass transition temperatures T_g1 and T_g2 (DSC, 2^nd heating process

at a heating rate of 30 K · min⁻¹) and changes to the isobaric heat

capacity ΔC_p1 and ΔC_p2 at the glass transitions of IPNs that are

produced by swelling the network N-P-LG(17)-10000 in acrylate solutions

and subsequent radiation (Type IV). For comparison, the thermal

properties of the networks N-EA, N-BA and N-HEA are listed.

T_g1

ΔC_p1

T_g2

ΔC_p2

Network^a)

° C.

J · K^−1· g⁻¹

° C.

J · K^−1· g⁻¹

N-P-LG(17)-10000

—^b)

—^b)

61

0.50

N-LG-ip-N-EA(15)

—^b)

—^b)

56

0.34

N-LG-ip-N-EA(19)

—^b)

—^b)

56

0.39

N-LG-ip-N-EA(38)

0

0.02

56

0.16

N-LG-ip-N-EA(55)

1

0.12

45

0.04

N-EA

−7

0.40

—^b)

—^b)

N-LG-ip-N-BA(8)

—^b)

—^b)

62

0.39

N-LG-ip-N-BA(14)

—^b)

—^b)

58

0.35

N-LG-ip-N-BA(19)

—^b)

—^b)

57

0.37

N-LG-ip-N-BA(36)

−43

0.08

57

0.21

N-LG-ip3-N-BA(81)

−36

0.49

57

0.07

N-BA

−38

0.61

—^b)

—^b)

N-LG-ip-N-HEA(30)

−4

0.10

51

0.31

N-LG-ip-N-HEA(50)

−2

0.06

51

0.15

N-LG-ip-N-HEA(59)

2

0.11

51

0.13

N-LG-ip-N-HEA(61)

9

0.04

53

0.09

N-HEA

−1

0.31

—^b)

—^b)

^a)See above.

No thermal transition is detected in the case of the network system N-LG-ip2-N-BA(56).

^b)A second glass transition is not detected.

Shape Memory Properties

TABLE 4

Elongation fixation ratio R_f(N), elongation restoration ratio R_r(N) and E module E(N)

(70° C.) in cycle N of networks of oligo[(rac-lactate)-co-glycolate] triols or

tetrols with constant glycol content and TMDI at the reached stretching ε_m in controlled-

position, cyclic thermomechanical experiment under standard condition.

ε_m

R_f(1)

R_r(1)

R_f(2-5)

R_r(2-5)

E(1)

E(2-5)

Network^a)

%

%

%

%

%

MPa

MPa

N-T-LG(17)-5000

 50^b)

91.3

98.5

94.6 ± 2.7

98.6 ± 0.9

2.04

1.68 ± 0.25

N-T-LG(17)-7000

100

94.3

>99

94.3 ± 0.1

99.3 ± 0.4

1.00

0.71 ± 0.13

N-T-LG(16)-9000

100

95.5

>99

91.2 ± 0.3

98.8 ± 0.5

0.89

0.69 ± 0.02

N-T-LG(18)-12000

100

91.8

97.3

91.7 ± 0.1

96.9 ± 0.4

0.70

0.35 ± 0.10

N-P-LG(15)-5000

 50^b)

90.3

>99

91.1 ± 2.4

96.4 ± 1.3

1.68

1.75 ± 0.12

N-P-LG(15)-7000

100

92.0

>99

92.3 ± 0.1

>99

1.63

1.60 ± 0.03

N-P-LG(16)-9000

100

95.8

>99

96.8 ± 2.1

98.6 ± 1.6

0.53

0.52 ± 0.01

N-P-LG(17)-10000

100

96.5

92.6

95.0 ± 0.0

90.1 ± 0.9

2.03

1.70 ± 0.12

N-P-LG(12)-12000

100

92.8

94.8

94.6 ± 2.7

90.9 ± 3.5

1.18

0.78 ± 0.11

^a)See above.

^b)The samples break when the value of ε_m is 100%.

The examples according to the invention demonstrate that the networks of the invention are shape memory materials that can be selectively produced, wherein good control of the network properties is possible. Preferred networks are amorphous and biodegradable and/or phase-segregated.