BONE CEMENT INCLUDING A CELL GROWTH STIMULANT
The present invention relates to a bone cement which is useful for healing bone f actures, repairing bone defects and stablisation of prosthetic implants.
It is conventional to use bone cement in the fixation of prosthesis to bone in joint replacement surgery. One of the main problems associated with joint replacement using conventional bone cement, such as polymethyimetha- crylate (PMMA) is aseptic loosening which is generally related to failure at the bone-cement interface. Post¬ operative changes occur at the bone-cement interface which can lead to a gap occurring between the bone and the cement. Eventually remodelling of the bone occurs. Any stimulus to remodelling or improvement in the qua- lity of the bone-cement interface would be a distinct advantage in cemented joint replacement.
It is also normal practice to use a physiologically ac¬ ceptable cement in healing fractured bones. The cement is applied to the fractured surfaces so that the frac- tured bones are kept in correct position until the heal¬ ing process is finished and the fracture has grown to¬ gether.
The cement may be mixed with antibiotics, such as Gen- tamicin, in order to avoid infections.
It has also been suggested to incorporate a bone or- phogenetic protein (BMP) in the cement in order to induce formation of new bone in viable tissue, cf. US P No. 4 526 909. In the specification of this patent is disclosed a PMMA bone cement containing BMP. The composition may be supplemented with other agents as desired, such. as fillers and antibiotics.
It is known that the protein BMP stimulates differentia¬ tion of connective tissue into bone cells, i.e. stimulate cartilage cells to turn into bone cells.
The present invention is based on the discovery that growth hormone stimulates proliferation of bone cells by increasing the level of IGFl in the "target" cells, and that this effect causes the bone cells to multiply, grow, produce matrix and penetrate into the cement phase.
According to the present invention there is provided a bone cement, comprising a combination of physiologi¬ cally acceptable reaction resin and a cell growth stimu¬ lant, preferably selected from the group consisting of somatotropins, somatomedines, parathyroid hormone (PTH), vitamin D and sex steroids.
Useful cell growth stimulants may be selected from the following groups:
1. Bone derived bone factors
2. Local regulators of bone metabolism
3. Growth regulator hormones 4. Calcium regulating hormones
5. Bone proteins
More specific examples of useful cell growth stimulants are:
PREDOMINANT EFFECTS ON RESORPTION ON FORMATION
Calcium-regulating hormones
Parathyroid hormone + + 1 , 25-dihydroxyvitamin D + - , ( +
Calcitonin 0
Systemic hormones
Growth hormone 0
Glucocorticoide ( + ) Thyroid hormones +
Insulin 0
Estrogens ( - ) :-)
Local factors
Prostaglandin E~ Interleukin-1
Interferon-
Insulin-line growth factor 1
Transforming growth factor-b +
The preferred cell growth stimulant to be used in the invention is human growth hormone (hGH). It has been shown that hGH, when it is incorporated in the cement, will increase the rate of healing of a bone fracture considerably and give a joint of increased strength.
The term "reaction resin" is used in the present concept to designate any casting resin in fluid, semi-liquid dough-like or ouldable form, capable of being cured or hardened at the temperature of application, usually between 30°C and 45°C, to form a strong, hard or flexible solid.
A preferred reaction resin is a polymerizing resin, such as a mixture of monomeric methyl methacrylate and pow¬ dered polymethyl methacrylate. This composition also
contains a catalyst and an accelerator. Examples of other useful resins are unsaturated polyesters or other liquid or mouldable polymerizing unsaturated compounds. Still other examples are ceramics and biodegradable organic galss.
Instead, a polycondensation resin can be used, such as a liquid high viscosity epoxy resin or a mixture of a di- or tri-isocyanate and a di- or trioi, producing a- polyurethane resin. Some polyurethane formulations will give a foamed resin, having increased flexibility and a high loading capacity for growth hormone or a similar cell growτth stimulant.
In order to reduce the shrinking of the reaction resin during the curing process it can be mixed with a filler, such as Plaster of Paris or inorganic pigments or fibres. Also other additives, conventionally used in the plas¬ tics field, may be added.
According to a specific embodiment of the invention, the reaction resin may be a monomeric cyano acrylate. This material will polymerize very fast at a hydrophiiic surface to a solid having a high bonding strength.
Used in total hip replacement surgery, the incorporation of hGH or a similar cell growth stimulant will result in increased bone remodelling and bone formation at the cement surface, leading to increased strength at the bone-cement interface. There is reduced risk of aseptic loosening and improved life time of the prosthesis.
The cement of the invention can be used in knee, elbow and schoulder replacement surgery or in small joint re- placement, such as fingers, wrists or toes.
Instead of incorporating the hGH in the cement mixture,
the hGH can be applied to the bone-cement interface using supplying means, such as drainage tubes. For example, a bone fracture can be treated in the usual way using a plastic foam. A drainage tube could be inserted and after operation a solution of hGH could be introduced to the cement through the drainage tube at a controlled rate.
The cement loaded with hGH can also be used to fill and repair bone defects and osteotomies. The release of hGH from the material can lead to new bone cell formation in these areas. This application may require the use of a biodegradable _polymer loaded with hGH-growth factors. The release of hGH will cause increased bone cell forma¬ tion, the biodegradable polymer will eventually be resorbed and the defect will be filled with new bone.
hGH-loaded resin, such as PMMA, can be used to repair bone fractures, give joint increased strength and cause increased bone remodelling in conjunction with devices such a a plate, screw or intermedullary pin.
The invention will be further described with reference to the following examples and the drawings, considered illustrative but not limiting of the invention.
EXAMPLE 1
A material was made from the following substances:
Powder polymethylmethacrylate polymer 20 g Liquid methylmethacrylate monomer 10 ml Sterilized human growth hormone (Lypophilised powder) 6 mg
To make the material, the sterile human growth hormone in powder form was added to the powder polymer component
of PMMA bone cement and mixed thoroughly. The liquid monomer component was then added to the mixture and mixed using a plastics spatula until a "dough-like" consistency was formed. The material was then inserted into a pre- viously prepared bone cavity.
The growth hormone loaded cement was implanted into one femur of adult sandy lop rabbits, with plain cement in the contralateral femur as a control. One month after surgery, the rabbits were sacrificed and the bone-cement interface examined using transmission electronmicroscop . In the plain cement the zirconium dioxide (radiopague agent) could be seen in' discreet pockets and the cement appeared clear (Fig. 1). In the growth hormone loaded cement, some invasion of the cement surface could be seen and new mineral deposited in the cement (Fig. 1).
These findings were confirmed using X-ray microanalysis, and the spectra for growth hormone loaded cement gave calcium and phosporous peaks (Fig. 3), whereas spectra for the plain cement gave no calcium and phosphorous peaks (Fig. 4). These findings indicate that certain appropriate changes occur at the bone-cement interface when growth hormone loaded cement is used _in vivo.
EXAMPLE 2
Animal Study Using Growth Hormone Loaded PMMA
In order to examine the jLn vivo effects of the use of growth hormone loaded cement, on the cement/bone inter¬ face, an animal model was employed.
Adult New Zealand White Rabbits between 2.5 kg and 5 kg were used. Under sterile conditions one vial human growth hormone (4.1 U) was added to each 10 gram pack of PMMA polymer component of Palacos bone cement. The cement was mixed as described above and inserted into
a 10 ml sterile syringe before insertion into the knee.
A medial parapatellar incision was made and access to the knee patella was dislocated laterally to expose the intercondylar area. Using 4 mm diameter drill bit the femoral medullary cavity was reamed to depth of 2 cm. Approximately 0.5 ml of cement was injected into each knee. On one side the cement was loaded with growth hor¬ mone (see above); plain cement was injected into the • contralaterial femur to act as a control. Further con- trols were used where both femura received plain PMMA cement. The patellae were reduced and wounds closed with sutures. Post-operatively rabbits were kept unrestrained in sized cagoes (40 x 40 x 01).
The rabbits were divided into three groups which were sacrificed using an overdose of Euthatal (100 mg in 5 ml) after 1 month, 2 mohths and 4 months, respectively. The femora were removed and processed for histology.
Histology of the Bone-Cement Interface
The sections were prepared to include undecalcified bone and intact bone cement making it possible to examine the bone-cement interface intact. Examination of the histology sections revealed that viable bone was growing in direct contact with the PMMA bone cement. When con¬ sidering PMMA as a drug delivery system it is important to establish whether the "target" tissue was in contact with the cement, this was clearly the case.
Electronmicroscopy studies revealed that viable bone cells were growing in direct contact with the growth hormone loaded cement.
One month after surgery:
The bone-cement interface was found to be composed of
between 14-21% mineralised bone, 28-52% osteoid bone and 41-60% cells. In all cases the knee containing growth hormone loaded PMMA contained a higher percentage of osteoid at the bone-cement interface than in the knee containing plain bone cement. This was statistically significant (P<0.01).
At two and four months the difference between the hGH loaded and plain cement interface became gradually less.
Findings
1. Viable bone cells grow along the cement surface and any GH released will reach the "target" bone cells.
2. Blood vessels are seen in the mineralised bone close to the cement interface - therefore remodelling of the bone can be expected.
3. Remodelling of the bone occurs over a period of 4 months after surgery.
4. A significantly higher percentage of osteoid is formed at the hGH loaded cement interface, one month after surgery, as compared with the control knees containing unloaded cement. The healing is accelerated.
The results of this preliminary trial indicate that there was an early response of the osteoblast cells to growth hormone, resulting in increased formation of osteoid one month after implanting the cement. These findings may be important because early stimulation of bone remodel¬ ling will bring skeletal cells and matrix to the cement surface thus strengthening the bond at the bone-cement interface.
The _in vivo results of the rabbits experiments may be
important to the problem of aseptic loosening. The pre¬ cise mechanism of early loosening is not fully under¬ stood, but it has been postulated that the primary cause is the shrinkage of cement in the bone cavity and acco p- anying bone necrosis. Under such circumstances, it would initiate a rapid synthetic response following prosthetic replacement. This was clearly seen in the growth hormone loaded cement series when analysed after one month.