The Experimental Study on Promoting the Ilizarov Distraction Osteogenesis by the Injection of Liquid Alg/nHAC Biocomposites

Liu, Xinhui; Yu, Di; Xu, Jieyan; Zhu, Chao; Feng, Qingling; Hou, Chuanyong; Wang, Hua; Yang, Yelin; Guan, Guoping

doi:https://doi.org/10.1155/2014/238247

International Journal of Polymer Science

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Polymeric Scaffolds for Tissue Engineering

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Research Article | Open Access

Volume 2014 | Article ID 238247 | https://doi.org/10.1155/2014/238247

The Experimental Study on Promoting the Ilizarov Distraction Osteogenesis by the Injection of Liquid Alg/nHAC Biocomposites

Xinhui Liu,¹Di Yu,¹Jieyan Xu,¹Chao Zhu,¹Qingling Feng,²Chuanyong Hou,¹Hua Wang,¹Yelin Yang,¹and Guoping Guan¹

Academic Editor: Xiaoming Li

Received07 Feb 2014

Accepted07 Mar 2014

Published14 Apr 2014

Abstract

Limb lengthening is frequently utilized in treating limb length inequalities, angulation deformities, nonunions, complex fractures, and deficiencies after tumor resection in more recent year. The procedure of limb lengthening pioneered by Ilizarov is now a widely accepted method for correcting limb length inequality and short stature as well as for bridging large defects in long bones. In order to promote bone healing during distraction osteogenesis and reduce the complications caused by limb lengthening pioneered, an alginate/nanohydroxyapatite/collagen (Alg/nHAC) composite was fabricated. General observation, histologically morphological observations, X-ray examination, biomechanical test, bone density, and the percentage area of bone trabecula were used to assay the ability of Alg/nHAC composite to promote bone healing. The present study demonstrates that the injection of liquid Alg/nHAC composites can significantly promote distraction osteogenesis. Alg/nHAC composite is promising for clinical application, solving the healing problem of backbone osteotomy and the fixing problem of metaphyseal backbone.

1. Introduction

Corrective limb lengthening is frequently utilized in treating limb length inequalities, angulation deformities, nonunions, complex fractures, deficiencies after tumor resection, and, in more recent years, persons of short stature. During the last two decades, many developments were achieved in the field of limb lengthening surgery, in which the main goal was to increase patients’ acceptance and comfort during lengthening [1]. Among them, the adaptation of bone during distraction osteogenesis (DO) is reliable and predictable [2], which is a surgical procedure used to promote tissue regeneration in long bones. It is used to lengthen limbs, repair major bone defects caused by infections or tumours, and correct congenital or acquired craniofacial defects [3, 4].

The procedure of limb lengthening pioneered by Ilizarov is now an accepted method for correcting limb length inequality and short stature as well as for bridging large defects in long bones. Limb lengthening is associated with numerous complications: infections [5, 6], stiff joints [6, 7], pseudarthrosis [6–8], early union [7, 8], and neurological sequela [7–9]. The bone healing problems associated with the other methods of limb lengthening have largely been resolved. Even though external systems have been improved over the years, problems with soft tissue transfixation, neurovascular injuries, pin track infections, malalignment, joint stiffness, pain, and poor cosmetic results are still frequent [10, 11]. A further study about lengthening is necessary.

Along with the development of tissue engineering, bone tissue engineering was applied to treat bone defect. Large amounts of material systems have been developed to mimic the natural extracellular matrix (ECM) and induce bone formation [12–15]. Researches had demonstrated that nHA had ability to promote ossification and bone regeneration [16–19] and collagen was a natural polymer with excellent biocompatibility and bioactivity [20–24]. The combination of bone tissue engineering and DO technology is promising. In this research, a liquid Alg/nHAC composite was injected into the extension area of rabbits’ tibia to study the effect on bone healing.

2. Materials and Methods

2.1. Materials

Acid-soluble type I collagen gel (solid content: 1%) was produced by Beihua Fine Chemicals Co., Ltd., Beijing. Sodium phosphate and calcium sulfate were produced by Yili Fine Chemicals Co., Ltd., Beijing. Sodium alginate was produced by Guoyao Chemical Reagent Co., Ltd. Calcium carbonate was produced by Beijing Modern Oriental Fine Chemicals Co., Ltd. Kirschner wire (12 mm) was produced by Jinlu Medical Equipment Company, Jiangsu. The New Zealand rabbits were obtained from laboratory animal center of Hebei Medical University.

2.2. Equipment

Philips 500mAX film machine (Germany), IPP (Image-Pro Plus IPP) Mediaplayer (USA), DEXAUNIT-2000 dual-energy X-ray absorptiometry instrument (Beijing, China), USS biomechanical testing machine (Shenyang, China), automatic dehydrator TP1020 (Germany), slicer 2125 (Germany), automatic paraffin embedding machine TKY-BM (Hubei, China), roast machine HI1220 (Germany), pushing machine HI1210 (Germany), Olympus camera binocular microscope CX31 (Japan), and image analysis system (Beijing, China) were used in this research.

2.3. Methods

2.3.1. Preparation of Alg/nHAC

A small amount of sodium alginate was mixed with sodium alginate (Na₃PO₄12H₂O) and dissolved in deionized water. After stirring for 20 minutes, a pale yellow aqueous solution of completely dissolved alginate was obtained. Calcium sulfate and deionized water were mixed in a beaker according to the setting proportion to obtain a slurry of calcium sulphate. The slurry was stirred until no significant particles can be seen and then kept more than 24 h to remove static. A certain amount of bone meal (nHAC) which was prepared according to the research of Li et al. [25] was dissolved in water and stirred to obtain sufficient bone paste. Then, the bone paste was mixed with the aqueous solution of sodium alginate and stirred to produce an intermixture. Next, the slurry of calcium sulphate was mixed with the intermixture and stirred to obtain a new intermixture. The new obtained intermixture was kept alone for about 15 min. The solid bone repair materials were got after the internal situ crosslinking reaction. Finally, the materials were sterilized with Co60 irradiation (2.5 Mrad) for the next experiments.

2.3.2. Manufacture of External Fixation Devices

In the experiment, we made use of self-made and improved Ilizarov full-ring external fixation with an outer diameter of 90 mm, an insider diameter of 60 mm, thickness of 4 mm, and 14 holes through the ring. The diameter of each is 6.5 mm. The diameter of each screw rod is 6 mm and the length is 105 mm. The screw pitch is 1 mm/lap, so 1 mm extension length can be achieved by extending one lap of the screw rod. The fixed needle is medical Klinefelter needle with diameter of 1.2 mm and 1.0 mm, respectively.

2.3.3. The Preparation of Animal Model of Rabbit Tibia Limbs’ Elongation

We selected big-ear white New Zealand rabbits (2–2.5 Kg) as the experimental animal. The rabbits were banned from food intake before operation and their left hind shins were reserved. Then we anaesthetized the rabbits by intravenous injection of 1% pentobarbital sodium after that disinfected the bed sheets and put the rabbit back on the rabbit platform. We drilled two 1.2 mm Kirschner wires across in the location 1.0 cm above tubercles of tibia. A ring of preassembled external fixation was installed and the Kirschner wire would be fixed on the steel ring. Two 1.0 mm Kirschner wires were drilled across in the distal of tubercles of tibia in order to correspond with proximal Kirschner wire, and the steel needle would be fixed on the steel ring using screw bolt meanwhile. Adjust external fixation to be firm and parallel. Under aseptic conditions, we made anterior lateral tibial longitudinal incision which was as deep as periosteum between the upper and lower two sets of needles. Moreover, the incision was peeled in the periosteum and the upper tibial appeared. Pry the lower end of the fibula into two parts and truncate tibia fully in tubercles of tibia by fretsaw. Adjust external fixation to make two ends of the fracture close and keep the anatomical paraposition. Then tighten all the nuts in order to avoid any accidental. Wash the wound and close the incision after the suture of periosteum. To prevent infection, making penicillin 400000 U intramuscular injection for 5 days is necessary after operation. We should make an Anerdian wet compress on the blade and needle tract at the same time. It started to extend at the speed of 1 mm/day after 5 days of operation. Finally, it would extend 20 mm by 2 times in 20 days. It should be kept fixed for 9 weeks after lengthening. Raise the rabbits under the same conditions, and the rabbits are free to move in the cage. Rabbits were executed at particular period and the specimens were obtained. The animal model of rabbit tibia elongation was shown in Figure 1.

(a)

(b)

2.3.4. Animal Grouping

60 New Zealand rabbits (2–2.5 Kg) were classified into two groups equally, namely, group A and group B. After the end of the extension, liquid Alg/nHAC was injected into rabbits of group A in the region of elongation. Rabbits of group B were not given any treatment as control. Groups A and B were molded and raised under the same conditions and the rabbits are free to move in the cage. Rabbits were executed at particular period and obtained the specimen.

2.4. Observations and Tests

2.4.1. General Observation

The general observation should include the following contents: the conditions of postoperative wound healing, daily activities of rabbits, and general bone formation of specimens in the extension area and whether the needle track was infected.

2.4.2. Histological Observation

We executed rabbits and acquired specimens at the following periods: medium term of bone elongation, termination of bone elongation at 2, 4, and 8 weeks after termination of bone elongation, respectively. The acquired specimens were fixed by 10% formaldehyde, and ossified specimens were decalcified for 2 weeks. Then we embedded sections by paraffin, conducted HE staining, and made an observation under light microscope after fixing sections.

2.4.3. X-Ray Observation

We took photos of bone elongation at three periods, respectively: after operation, termination of bone elongation, and 2, 4, and 8 weeks after termination of bone elongation. By means of these photos in different periods, we could observe the condition of bone formation of extended position and formation of poroma. The camera model was Philips 500mAX, and conditions of exposure were 50 KV, 4 ms.

2.4.4. Measurement of the Percentage Area of Bone Trabecula

We observed the tissue slices under the microscope and acquired images and measured the percentage area of trabecular bone using IPP (Image-Pro Plus IPP) Mediaplayer measurement software.

2.4.5. Bone Density Test

Five rabbits were killed in each group for obtaining the samples after 8 weeks, five rabbits were killed in each group to obtain the samples of termination of bone elongation. We determined the bone density using dual-energy X-ray bone densometer.

2.4.6. Biomechanical Test

Three-point bending experiment was conducted in elongation area of rabbit tibia at 2, 4, and 8 weeks, respectively. Five specimens in each group (groups A and B) were prepared at each period and 5 specimens from normal contralateral tibia were obtained and set as control group. For the specimens, intermediate point was support point and both ends were fixed with a span of 30 mm. Then a loading was imposed slowly at the constant speed of 0.5 mm/min until specimens fractured. The average stress value was taken and compared with the maximum stress value of each group.

2.4.7. Statistical Methods

All acquired data were statistically analyzed by statistical software SPSS10.0.

3. Results

3.1. General Observation

The rabbits had regular diet and normal activities after operation. Affected limbs were slightly swelled, the swelling would be reduced in 1-2 weeks, and all the incisions would also be healed normally. In the course of experiment, 15 rabbits died because of diarrhea and 2 rabbits fractured in the Kirschner wire fixation. Except the rabbits mentioned above, which were excluded in this experiment, all the other rabbits survived. External fixation was fixed so reliably that it made no adverse effects to animals. We acquired 3 specimens after termination of bone elongation. Via the observation of elongation region, dense fibrous connective tissue was found in the region of elongation, and the material quality was soft and tough without the appearance of ossification.

Five rabbits of each group were executed, and a total of 10 rabbits were put to death for obtaining specimens after 2 weeks of termination of bone elongation. Most of the elongation region in group A was ossified, and it was difficult to cut poroma using operating knife blade. As to group B, elongation region was ossified slightly; however, a majority of fibrous connective tissue still existed.

Five rabbits of each group were executed, and a total of 10 rabbits were put to death for obtaining specimens after 4 weeks of termination of bone elongation. For group A, elongation region was totally ossified, but the intensity of elongation region was weaker than the uninjured side and it could be broken easily. As to group B, elongation region was ossified basically, and the intensity of callus was not high and it was practicable to cut using operating knife blade.

Five rabbits of each group were executed, and a total of 10 rabbits were put to death for obtaining specimens after 8 weeks of termination of bone elongation. The elongation regions of groups A and B were ossified entirely. The appearance of group A was similar to normal bone and it was very hard to fracture, while group B was prone to fracture. Compared with uninjured lateral tibia, operation side lateral tibia extended 2 cm (Figure 2).

3.2. Histologically Morphological Observations

Five rabbits were killed at each medium term and termination of elongation, respectively, and a total of 10 rabbits were killed for obtaining specimens. The elongation region was filled with dense fibrous connective tissue, and bone tissues were not found (Figure 3).

Five rabbits of each group were executed and a total of 10 rabbits were put to death for obtaining specimens after 2 weeks of termination of bone elongation. The material implanted into group A was separated by fibrous connective tissue; fibrous connective tissue and blood vessel grew into the transplanted material. Osteoid formation mainly comprised of fibrous callus could be seen in most of the material, but a few osseous calluses appeared around separated materials (Figure 4).

(a)

(b)

Five rabbits were executed and a total of 10 rabbits were put to death for obtaining specimens after 4 weeks of termination of bone elongation. For group A, most mature bone could be seen, bone lacuna and the amount of endoskeleton cells increased obviously, and transplanted materials decreased obviously (Figure 5(a)). For group B, lots of osteoid appeared, woven bone was formed, and trabecular bone got mature gradually; part of osteoblast grew into osteocyte gradually, trabecular bone increased compared to 2 weeks of termination of bone elongation, and immature trabecular bones were still in the the major (Figure 5(b)).

(a)

(b)

Five rabbits of each group were executed and a total of 10 rabbits were put to death for obtaining specimens after 8 weeks of termination of bone elongation. As to group A, injected material disappeared basically, only very small amount of material existed in the center, and massive mature bony callus was formed (Figure 6(a)). As to group B, generous fibrous callus and bony callus accounted for the bulk, and a few mature bone lacuna and osteocyte emerged (Figure 6(b)).

(a)

(b)

3.3. X-Ray Examination

The X-ray examination after the surgery showed that the tibial osteotomy is complete, the fibula is also disconnected, and the site and lines of the osteotomy are well matched (Figure 7(a)). The X-ray examination done at 10 days after surgery showed that the tibial osteotomy had been apart and the line of osteotomy matched well (Figure 7(b)). The X-ray examination done after lengthening showed that a range about 2 cm existed and the line of osteotomy matched well. The extended area was of low density development and no calcification could be observed (Figure 7(c)). Besides, the Alg/NHAC used in group A, which is a liquid injection, is also of low density development (Figure 7(d)).

(a)

(b)

(c)

(d)

At 2 weeks after lengthening, large amounts of high density development formed and filled in the extension area in group A (Figure 8(a)). A small amount of high density development could be observed, namely, a few of new bones formed in group B (Figure 8(b)). At 4 weeks after the lengthening, the high density development in extension area of group A obviously increased (Figure 8(c)). The callus volume of group B increased when compared to group B at two weeks but less than group A at the same period (Figure 8(d)). At 8 weeks after lengthening, X-ray examination showed that the imaging performance of group A had been close to normal bone, with a connected marrow and similar bone density between cortical bone of extension area and normal bone upper and lower (Figure 8(e)). The elongation areas were all ossification in group B, but the bone mineral densities were lower and bone masses were less (Figure 8(f)).

3.4. Measurement of the Percentage Area of Trabecular Bone

30 specimens were obtained by three times, of which, 10 specimens (group A: 5, group B: 5) were obtained at week 2, 8 specimens (group A: 5, group B: 5) were obtained at week 4, and the last 10 specimens (group A: 5, group B: 5) were obtained at week 8.

The statistical analysis showed that the percentage areas of the two groups were significantly different in 2, 4, and 8 weeks, . The percentage area of trabecular bone in group A was significantly higher than in group B, as shown in Table 1.

3.5. Measurement of the Bone Density

In this study, 13 specimens were obtained: (group A: 6, group B: 7) at week 8. The contralateral normal tibial bone was set as group C and measured.

BMD of groups A, B, and C was (), (), and () separately. The BMD of group A is higher than group B, and a significant difference existed () at week 8.

The bone density in group A was to recover to 70.29 percent when compared to normal bone, while that of group B was to recover to 49.29%. There was a significant difference () between the two groups.

3.6. Biomechanical Test

In this test, 13 specimens were obtained: (group A: 6, group B: 7) at week 8. Five contralateral normal tibial bones were set as group C and measured.

The maximum bending stress in groups A, B, and C was () N, () N, and () N separately.

The maximum bending stress of group A is higher than that of group B at week 8, and a significant difference () existed. The biomechanical property of group A was to recover 68.94%, while that of group B was to recover 33.33%. There was a significant difference () between the two groups.

4. Discussion

Although the Ilizarov method is regarded as a revolution in the history of orthopedic therapeutics, the bone healing is relatively slow and there are more complications existing. Besides, the pull speed can just be 1.0 mm a day, considering the bone healing time of extended area, and each extension of 1.0 mm needs about one or two months [26]. Therefore, many scholars have explored the mechanism and method to promote bone healing. The biological mechanism of limb lengthening was regarded as osteotylus lengthening. Ilizarov [27] has described the biological characteristics of broken ends of fractured bone in the traction state. It was discovered that the connection of the collagen fibers in bone gap and the fusion of the trabecular of new bone were an ongoing repair process which contained new bone formation and the translation of matrix to matrix. In the extension of the human tibia, cancellous bone and bundle bone were clearly observed and finally turned to osteocyte, which was a process that looked like fetal growth and development. The discovery of tumor-related gene c-fos and c-jun in the early stages of limb lengthening, which was related to the fetal development, further proved the theory that distraction osteogenesis can make some process that usually took place in the stage of fatal development repeat in adult tissue.

The biological theory of distraction-traction osteogenesis (DO) offered the theory support for limb lengthening and changed the biological mechanism of limb lengthening. The application of DO concept significantly improved the quality of bone growth and reduced incidence of nonunion complications. Limb lengthening was not just a simple extension of bone length, but the interaction of bone, soft tissue, joint, and systemic factors in the overall. Polo and domestic scholars [28, 29] have shown that nerves, blood vessels, and muscle tissue have the same adaptation and regeneration potential just like the osteocyte. Striated muscle cells which have stopped regenerating and splitting in adult tissue, differentiated into muscle stem cells along with the proliferation of stellate cells, and finally formed the new muscle tissue in the slow pulling process. The research has shown that slow pulling process can also induce the regeneration of new nerve tissue [30]. Thus, limb lengthening is a combination of modern histology, biochemistry, and other systemic factors which influence each other. Its meaning based on the concept DO has a new extension, which should be the regeneration and rebuilding of limb composite tissue under a slow pulling process, namely, distraction histogenesis (DH).

In limb lengthening surgery, the speed and time of lengthening process, the site and method of osteotomy, patient age, and other factors will affect the bone healing process. First, the extension rate is one of the most important factors which influence bone healing process [31]. A large number of clinical and animal experiments confirmed that 1.0 mm/d is the most reasonable and beneficial extension rate to the healing of bone and soft tissue adaptation. Second, the osteotomy site is also one of the most important factors which affect bone healing process. Due to the ability of blood supply and bone formation, different osteotomy sites have different bone osteotomy healing rate. In metaphyseal extension, the bone formation is faster because of the rich blood supply, while the fixture is easy to lose, which have serious impact on joint function and even cause permanent barriers. Backbone osteotomy is far away from the joint, which has light effect on the joint in the lengthening process, and the function of joint can be restored through the exercise. Because of the poor blood circulation here and the smaller diameter of bone, the healing time and fixing time should be increased. In comparison, the backbone of the bone ends is the ideal osteotomy site. Due to the osteotomy line which is farther away from the joint and has light effect on the joint, the change of the joint function in the lengthening process can be restored through exercise after surgery. Besides, the blood circulation here is closed to the bone end and the osteogenesis rate is faster than that of the backbone. Third, osteotomy method also affects bone healing of extension area. Frierson et al. [32] compared different osteotomy method and found that the simple cortex osteotomy has no significant differences with the common osteotomy. Fourth, bone healing can be affected when the delay extension or immediate extension method is used. Yasui et al. [33] have proved that the delay extension method is superior to immediate extension because the blood can be rebuilt and the soft tissue damaged after osteotomy surgery can be restored in the delay extension process.

The Alg/nHAC composite actually promotes the Ilizarov distraction osteogenesis and there maybe two reasons as follows. On one hand, nHAC composite can promote bone healing according to the research done before [25]. The microstructure of nHA may increase surface areas of implant. The microstructured calcium phosphate materials could concentrate more proteins, which may influence the attachment, proliferation, and differentiation of cells. These proteins may include bone-inducing proteins, which could differentiate inducible cells to osteogenic cells that form inductive bone. On another hand, the introduction of algorithm which stabilizes collagen as a cross-linker and preserves its helical structure creates a favorable microenvironment for the regeneration of tissue.

In order to promote bone healing, great amounts of researches had been done [34–38]. By the development of the modern medical technology, minimally invasive technology has aroused people’s attention. The combination of clinical treatment and minimally invasive technology is promising. All in all, a further study about DO is rather necessary.

5. Conclusion

In this study, the liquid Alg/nHAC was injected into the extension area of tibia. The group which was injected into the liquid composite has more regenerated calluses than the control group through general observation and histological observation. The X-ray observation showed that the high density area in the experimental group is superior to the control group in different period. The results of bone density test and biomechanical test also demonstrated that the degree of bone healing and the strength of bone are much more better than the control group. Alg/nHAC was an ideal material for limb lengthening. The present study demonstrates that the injection of liquid calcium alginate/nHAC composites can significantly promote distraction osteogenesis. Alginate/nHAC is promising to be used for clinical application to solve the healing problem of backbone osteotomy and the fixing problem of metaphyseal backbone which has bad effect on the closed joint and causes complication.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

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Copyright © 2014 Xinhui Liu et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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