The immature goat as an animal model for Legg-Calvé-Perthes disease

A novel animal model of osteonecrosis of the femoral head based on 3D printing technology

BACKGROUND

Osteonecrosis of the femoral head (ONFH) is a prevalent orthopedic condition characterized by the disruption of blood supply to the femoral head, leading to ischemia of internal tissues, subchondral bone fractures, necrosis, and eventual collapse of the weight-bearing portion of the femoral head. This condition results in severe functional impairment, pain, and even disability of the hip joint. Existing animal models of ONFH have limitations in replicating the natural disease progression accurately. Thus, there is a critical need to develop a novel animal model capable of better simulating localized pressure on the human femoral head to facilitate ONFH-related research.

METHODS

In this study, we present a novel approach for modeling ONFH, which involves integrating stress factors into the modeling process through the utilization of 3D printing technology and principles of biomechanics. A total of 36 animals were randomly assigned to six groups, where they received either the novel modeling technique or the traditional hormone induction method. Subsequently, an 8-week treatment period was implemented, followed by conducting micro-CT scans and histological evaluations to assess tissue outcomes.

RESULTS

The study evaluated the cytotoxicity of the material used in the new model, and it was observed that the material did not exhibit any cytotoxic effects on cells. Additionally, the novel model successfully replicated the pathological features of ONFH, including femoral head collapse, along with a substantial presence of empty bone lacunae, cartilage defects, and subchondral bone fractures in the subchondral bone region.

CONCLUSION

In conclusion, our study provides evidence that the new model shows the ability to simulate the progression of the disease, making it a valuable tool for research in this field and can contribute to the development of better treatment strategies for this debilitating condition. It holds great promise for advancing our understanding of the pathogenesis of ONFH and the potential therapeutic interventions for this challenging clinical problem.

[Experimental induction of Perthes disease in lambs]

OBJECTIVE

To establish a simple, reproducible and safe experimental model, for the development of ischemic vascular necrosis of the hip in the lamb.

MATERIAL AND METHODS

We used 15 lambs (10 males and 5 females) aged four weeks, divided into a control group (7 animals) and an experimental group (8 animals) producing ischemia in the proximal femur. Standard radiography and MRI were performed. The animals were euthanised at the 4th, 8th and 12th weeks after surgery. The femoral heads were extracted and measured and a histological analysis was performed with hematoxylin-eosin staining.

RESULTS

Decreased height and increased width of the femoral head was observed in the X-Rays, particularly after the 4th week. We did not observe any changes in the height of the lateral pillar or trochanteric distance. The experimental group showed macroscopical hypertrophy and progressive flattening of the head. At 4 weeks necrotic areas in articular cartilage were observed, bone marrow was dense and the growth cartilage height was lower. The vessels were thickened by proliferation of the medial and adventitia layers. At 8 weeks, we found fibrosis in the subchondral bone with thinned and devitalized angiogenesis fat areas. The articular cartilage showed irregularities. At 12 weeks the closure of the physis was noted, as well as chondral areas in the trabecular bone and fat cells in the methaphysis.

CONCLUSION

Although the histological changes are consistent with necrosis of the femoral head, the images obtained did not resemble Perthes disease, so we do not advise this experimental model for the study of this disease.

Scanning and transmission electron microscopic observation of femoral head feeding vessels in stroke-prone spontaneously hypertensive rats

Stroke-prone spontaneously hypertensive rats (SHRSP) are known to show necrosis of the femoral head with a frequency of about 50%. This rat has thus been used as an animal model for necrosis of the femoral head in many studies. In a detailed investigation of feeding vessel disorders that cause femoral head necrosis, we observed changes over time in the feeding vessels using scanning electron microscopy and transmission electron microscopy. In scanning electron microscopy of vascular casts, abnormal findings in feeding vessels of SHRSP with aging from the immature stage included contortion and bending in the lumen with overall narrowing. Under transmission electron microscopy, decreased numbers of smooth muscle cells and increased amounts of collagen fibers were marked, and these changes with hypertrophy of vascular walls might be similar to those of arteriolosclerosis. The structural changes first revealed by transmission electron microscopic observation might cause the friability of the feeding vessels so that contortion and bending occurred, suggesting transient obstruction of blood flow to the femoral head and subsequent induction of femoral head necrosis. These findings should help in understanding the causes of femoral head necrosis in humans, including Perthes' disease.

An animal model of femoral head osteonecrosis induced by a single injection of absolute alcohol: an experimental study

Background

The lack of an experimental animal model that can reliably mimic all stages of osteonecrosis of the femoral head has hindered progress toward the successful prevention and treatment of the disease.

Material/Methods

A goat model of osteonecrosis of the femoral head (ONFH) was established and observed from the early to the intermediate-to-late stage of mechanical failure. Absolute alcohol was injected slowly into the center of bilateral femoral heads in 12 adult Small Tail Han goats. Postoperatively, the femoral heads were harvested and examined using macrostructural and histological analyses and radiographic and MRI examinations at weeks 4, 8, 12, and 25.

Results

Macrostructural and radiographic examinations revealed that the contour of both femoral heads was deformed slightly at 12 weeks, but a contour deformation with joint space narrowing was observed at 25 weeks. Histologically, a strong concordance with the natural history of ONFH in humans was found. The present model demonstrated bone trabeculae, marrow necrosis, a reconstruction deficiency and destruction of the microcirculation.

Conclusions

Among quadrupedal models, the goat model of ONFH, which is induced by a single injection of absolute alcohol, may be suitable and valuable for the evaluation of various therapeutics and side effects in the treatment of ONFH.

A two-degree-of-freedom hip exoskeleton device for an immature animal model of exercise-induced Legg—Calvé—Perthes disease

Legg—Calvé—Perthes disease (LCPD) is a significant problem in healthcare because it so commonly affects young adults and immature athletes, primarily gymnasts. In this paper, a two-degree-of-freedom (2-DOF) hip exoskeleton device was developed for study on an immature animal model of exercise-induced LCPD. The exoskeleton device can reproduce the repetitive actions and forceful centrality impingements on the coxafemoral head that occur in sports such as gymnastics and acrobatics. It initiated a new method rather than the traditional medical or physiological operation method to establish an animal model of LCPD and allowed for the development and testing of new treatments. Ten immature New Zealand white rabbits were selected for the experiment. Their right legs were driven to achieve repetitive extension/flexion and abduction/adduction beyond the normal range of motion, with centrality impingements at the maximum flexion position, while their left legs were kept in the initial healthy status and acted as the comparing reference. Four weeks later, the basic symptoms of early LCPD of the femoral head appeared. The results of X-ray, magnetic resonance imaging (MRI), gross anatomy observation, and H-E section also revealed it.

Treatment of osteonecrosis of the femoral head with hBMP-2-gene-modified tissue-engineered bone in goats

The efficacy of β-tricalcium phosphate (β-TCP) loaded with bone morphogenetic protein-2 (BMP-2)-gene-modified bone-marrow mesenchymal stem cells (BMSCs) was evaluated for the repair of experimentally-induced osteonecrosis of the femoral head in goats.

Bilateral early-stage osteonecrosis was induced in adult goats three weeks after ligation of the lateral and medial circumflex arteries and delivery of liquid nitrogen into the femoral head. After core decompression, porous β-TCP loaded with BMP-2 gene- or β-galactosidase (gal)-gene-transduced BMSCs was implanted into the left and right femoral heads, respectively. At 16 weeks after implantation, there was collapse of the femoral head in the untreated group but not in the BMP-2 or β-gal groups. The femoral heads in the BMP-2 group had a normal density and surface, while those in the β-gal group presented with a low density and an irregular surface. Histologically, new bone and fibrous tissue were formed in the macropores of the β-TCP. Sixteen weeks after implantation, lamellar bone had formed in the BMP-2 group, but there were some empty cavities and residual fibrous tissue in the β-gal group. The new bone volume in the BMP-2 group was significantly higher than that in the β-gal group. The maximum compressive strength and Young’s modulus of the repaired tissue in the BMP-2 group were similar to those of normal bone and significantly higher than those in the β-gal group.

Our findings indicate that porous β-TCP loaded with BMP-2-gene-transduced BMSCs are capable of repairing early-stage, experimentally-induced osteonecrosis of the femoral head and of restoring its mechanical function.

Relative versus absolute modulation of growth in the fusionless treatment of experimental scoliosis

STUDY DESIGN

Absolute and relative growth modulation of apical spinal segments were measured during creation and correction of an experimental scoliosis in a goat model.

OBJECTIVE

To differentiate relative and absolute changes in growth on the concavity and convexity of an experimental scoliosis treated with anterior vertebral stapling.

SUMMARY OF BACKGROUND DATA

The creation and correction of vertebral wedge deformities have been previously described in a rat tail model using external fixation as well as in a goat model using anterior vertebral body stapling.

METHODS

Progressive, structural, scoliotic curves convex to the right in the thoracic spine were created in 14 Spanish Cross-X female goats using a posterior asymmetric tether. After 7-13 weeks, all tethers were removed, and goats were randomized into stapled (n = 8) and untreated (n = 6) groups. Stapled goats underwent anterior vertebral stapling with 4 shape memory alloy staples (Medtronic Sofamor Danek, Memphis, TN) along the convexity of the maximal curvature. All goats were observed for an additional 7-13 weeks. There were 12 additional goats matched for age, sex, and weight used as growth controls throughout the study. Serial radiographs were used to document progression or correction of the maximal scoliotic deformity, and changes in relative and absolute growth at the apical spinal segment T9-10 (2 adjacent vertebrae and the intervening disc).

RESULTS

All tethered goats had progressive, structural, scoliotic curves of significant magnitude during the tethering period (average 61.4 degrees, range 49 degrees to 73 degrees) (P = 0.001). There was 1 goat from each group eliminated from the study because its apical spinal segment did not match the T9-10 level used to establish normal growth in controls. During the treatment period, stapled goats had a correction of -6.9 degrees (P = 0.03), whereas untreated goats had little change (-1.4 degrees). Apical spinal segment wedging progressed in all tethered goats, from 11.1 degrees to 22.4 degrees, during the tethering period (P = 0.001). During the treatment period, wedging corrected -2.2 degrees (range 22.5 degrees to 20.3 degrees) in the stapled goats but progressed +3.5 degrees (range 22.3 degrees to 25.8 degrees) in the untreated goats (P < 0.05). Apical spinal segment growth in all tethered goats was decreased on the concavity by 78% and increased on the convexity by 33% when compared to growth controls (P < 0.001). During the treatment period, growth on the concavity of the apical spinal segment of the stapled goats was decreased by 10% but increased in the untreated goats by 37% when compared to growth controls. On the convexity, apical spinal segment growth at T9-10 was decreased in the stapled goats by 18% and increased in the untreated goats by 29% when compared to growth controls (P < 0.04).

CONCLUSIONS

Data in this study show the ability to modulate relative and absolute growth, according to the Hueter-Volkmann law, at the apical spinal segment of a progressive experimental scoliosis. However, anterior vertebral stapling, although able to control progressive wedging and scoliosis at the apical spinal segment, was not able to reverse fully the Hueter-Volkmann effect.

Mechanical modulation of vertebral growth in the fusionless treatment of progressive scoliosis in an experimental model

STUDY DESIGN

Wedging of apical spinal segments was measured during creation and correction of an experimental scoliosis in a goat model.

OBJECTIVES

To create and correct apical vertebral wedge deformities in a progressive experimental scoliosis model by purely mechanical means.

SUMMARY OF BACKGROUND DATA

The creation and correction of vertebral wedge deformities has been previously described in a rat tail model using external fixation.

METHODS

Experimental scoliosis was created in 14 goats using a posterior asymmetric tether with convex rib resection and concave rib tethering. After a period of up to 13 weeks, all tethers were removed and goats were randomized into treated (n = 8) and untreated (n = 6) groups. Treated goats underwent anterior thoracic stapling with four shape memory alloy staples along the convexity of the maximal curvature. Goats were followed for an additional 7 to 13 weeks during treatment. Serial radiographs were used to document progression or correction of the maximal scoliotic deformity as well as to measure the wedging of the apical spinal segment (two adjacent vertebrae and the intervening disc).

RESULTS

During the tethering period, all goats achieved a progressive, structural, lordoscoliotic curve of significant magnitude (mean: 61 degrees, range: 49 to 73 degrees). Wedging of the apical spinal segment measured 11.1 degrees at the beginning and 22.4 degrees at the end of the tethering period. The increase in apical spinal segment wedging of +11.3 degrees (10.7 degrees vertebral/0.6-degree disc) was significant (P = 0.001). During the treatment period, the scoliosis in the stapled goats measured 56.8 degrees at the beginning and 43.4 degrees at the end for an average correction of -13.4 degrees (range: 0 to-22 degrees) (P = 0.001), whereas the untreated goats measured 67.0 degrees at the beginning and 59.8 degrees at the end for an average correction of -7.2 degrees (range: +7 to -21 degrees) (P = 0.19). Additionally, wedging of the apical spinal segment in the stapled goats measured 22.5 degrees at the beginning and 20.3 degrees at the end for an average correction of -2.2 degrees (-0.6 degrees vertebral/-1.6-degree disc); wedging of the apical vertebral segment in the untreated goats measured 22.3 degrees at the beginning and 25.8 degrees at the end of the treatment period for an average progression of +3.5 degrees (3.5 degrees vertebral/0.0-degree disc). The difference in apical spinal segment correction versus progression in the stapled (-2.2 degrees) versus control (+3.5 degrees) goats was significant (P < 0.05).

CONCLUSIONS

This study demonstrates the ability to create wedge deformities at the apex of an experimental scoliosis in a large animal model and to control the progression of these deformities using anterior thoracic staples.

The use of animal models in fusionless scoliosis investigations

STUDY DESIGN

Review article of current knowledge of animal models used in the investigations of fusionless scoliosis surgery.

OBJECTIVE

To provide a summary of available data on animal studies in the area of fusionless scoliosis surgery.

SUMMARY OF BACKGROUND DATA

Fusionless scoliosis surgery is an emerging treatment for patients with idiopathic scoliosis as it offers theoretical advantages over current forms of treatment. These advantages include correction of spinal deformity while preserving growth, motion, and function of the spine.

METHODS

Literature review of animal models used in the investigation of fusionless scoliosis surgery.

RESULTS

At present, the theoretical advantages of fusionless scoliosis surgery in the treatment of idiopathic scoliosis are unproven clinically. However, investigations using animal models have demonstrated promise for this new form of treatment. These studies have demonstrated the safety and efficacy of a variety of fusionless scoliosis implants in treating experimental scoliosis and in modulating spinal growth.

CONCLUSION

Fusionless scoliosis surgery offers theoretical advantages over brace treatment and surgery. Like bracing, fusionless treatments preserve growth, motion, and function of the spine. Like surgery, these treatments offer substantial correction of deformity. However, minimally invasive fusionless scoliosis surgery is less extensive than fusion surgery and may avoid adjacent segment degeneration and other complications related to fusion. Additional investigations are required to identify optimal implant strategies, to evaluate the effects of these implants of the spine and surrounding structures, and to define the appropriate patient population for these interventions.

Enhanced tissue factor pathway inhibitor response as a defense mechanism against ongoing local microvascular events of Legg-Calve-Perthes disease

The precise pathogenetic basis of Legg-Calve-Perthes disease (LCPD) is currently unknown. Hemostatic abnormalities, i.e., hypercoagulability and/or hypofibrinolysis, were proposed in the genesis of the LCPD. Deficiency of tissue factor pathway inhibitor (TFPI), a critical natural anticoagulant molecule, may lead to a prothrombotic state in a wide variety of conditions. The aim of this study is to assess the circulating TFPI pool in the LCPD. Group I consisted of 44 patients with LCPD and group II comprised 38 healthy children. Median (IQR) TPFI concentration was significantly higher in the group I (p < .0001). Enhanced TFPI response could be regarded as a compensatory defense mechanism against ongoing local microvascular events of occlusion and revascularization of LCPD. TFPI molecule may be an important link between the crossroads of the LCPD genesis and pathogenetic microvascular changes in the disease course. Further investigations are needed to shed light on the endothelial anticoagulant kinetics, the unique microvascular compromise, and the self-limiting nature of the disease.

A new animal model of femoral head osteonecrosis: one that progresses to human-like mechanical failure

Existing animal models of femoral head osteonecrosis, while displaying varying levels of concordance with early histopathologic features of the human disorder, generally fail to progress to end-stage mechanical collapse. A new animal model of osteonecrosis is here introduced, utilizing the emu (Dromaius novaehollandie). These animals' bipedality and their high activity level represent a much more challenging biomechanical environment to the hip than seen in quadrupedal models of this disorder. Femoral head osteonecrosis was induced surgically, using a combination of ischemic (vessel ligation) and cryogenic (liquid nitrogen) insults. Of nineteen emus allowed free-roaming pen activity to study the natural history of such lesions, eighteen progressed to an osseous structural failure, sixteen of them developing incapacitating lameness at an average time point 11.75 weeks after the surgical insult. Histologically, the animals showed close concordance with both the early- and late-stage human pathology, in six cases even to the point of developing a crescent sign. Because of its large physical size and its consistent progression to mechanical collapse, the emu appears to offer a unique opportunity for the near-human-scale study of surgical interventions to forestall femoral head collapse. Toward this end, various directions for model refinement are outlined.

Growth profiles and articular cartilage characterization in a goat model of Legg-Calve-Perthes disease

Numerous animal species, including the goat, have been evaluated as potential models for human Legg-Calve-Perthes disease (LCPD). These models disrupt the vasculature of the femoral head, causing it to collapse, and therefore do not mimic all the clinical patterns of the human disease. Baseline data regarding the weight and femoral length in the growing goat are not available. This study characterized the goat's normal growth for comparison with that of humans. The growth aberrations in the proximal femur created by surgically ablating the capital physis were described and compared with the aberrations observed in human LCPD cases. Age, weight, and femoral length (test and control) data were obtained for goats approximately 1 to 14 months of age. At 4 months of age, a craniolateral surgical approach was used to expose the cranial lateral capital physis so that it could be cauterized. Postoperative radiographs were evaluated by graphic analysis to assess the resultant changes in the morphology of the proximal femur. The articular cartilage of the femoral head and acetabulum was evaluated mechanically, using indentation testing, to determine the apparent modulus of elasticity, and histopathologically regarding its thickness and proteoglycan content. The proximal femurs of goats and humans exhibit similar morphology and growth patterns. There was a positive correlation between age, weight, and femoral lengths in the goat. The surgical procedure was effective in ablating the capital femoral physis as indicated by shorter femoral lengths and fragmented, flattened, and mushroomed femoral heads. The histopathological data revealed that the articular cartilage was significantly thicker in the operated hip joints at the ventrocaudal and cranial acetabula and the dorsal and ventral femoral heads. The test cartilage exhibited significantly less positive staining for proteoglycans in the dorsocaudal and the cranial acetabula as well as the ventral femoral head. The apparent modulus of elasticity, of the test cartilage was significantly lower than the control value at the dorsocaudal acetabulum. These data show that the surgical procedure produced morphological changes that mimic those in human LCPD. The increased thickness of the articular cartilage of the LCPD femoral head may account for the articular degeneration observed in older patients with LCPD, as increased cartilage thickness is associated with decreased tissue quality.