Acta Chir Orthop Traumatol Cech. 2006; 73(3):176-182 | DOI: 10.55095/achot2006/025

Scintigraphic Detection of Osteoblast Activity after Implantation of BAS-0 Bioactive Glass-Ceramic Material into Long Bone DefectsOriginal papers

P. ©PONER1, K. URBAN1, E. URBANOVÁ2
1 Ortopedická klinika LF UK a FN, Hradec Králové
2 Oddělení nukleární medicíny FN, Hradec Králové

PURPOSE OF THE STUDY:
The aim of the study was to demonstrate, by three-phase bone scintigraphy, radionuclide uptake at the site of defects in long bones filled with the non-resorbable bioactive glass-ceramic material BAS-0 at a long follow-up.

MATERIAL:
Twenty patients, 14 men and 6 women, operated on between 1990 and 2000 for benign bone tumors or tumor-like lesions localized in the femur, tibia or humerus were comprised in the study. Their average age at the time of operation was 14 years (range, 8 to 24). The diagnoses based on histological examination included juvenile bone cysts in 11, aneurysmal bone cyst in five, non-ossifying fibroma in two, and fibrous dysplasia in two patients. The lesions were localized in the femur, humerus and tibia in 11, five and four patients, respectively. The metaphysis was affected in eight and the diaphysis in 12 patients.

METHODS:
Clinical, radiological and scintigraphic examinations were carried out at 2 to 12 years (7 years on average) after surgery. The clinical evaluation included subjective complaints and objective findings. Radiographs were made in standard projections and the osteointegration of glass-ceramic material was investigated.
Three-phase bone scans were made and the healthy and the affected limbs in each patient were compared by means of an index. Radionuclide uptake was considered normal when the index value was equal to 1.0, mildly increased at an index value of 1.2, moderately increased at 1.2-1.5 and markedly increased at an index value higher than 1.5.

RESULTS:
The clinical evaluation showed that, in the patients with glass-ceramic filling of metaphyses, six had no subjective complaints and two reported transient pain. In the patients with implants in diaphyses, subjective complaints were recorded in nine and no complaints in three patients. No inflammatory changes in soft tissues were found. No restriction in weightbearing of the limb treated was reported by any of the patients.
On radiography, 18 patients were free from any disease residue or recurrence. Two patients had a residual defect. The bioactive glass-ceramic material BAS-0 was completely incorporated in all patients.
On three-phase bone scans, radionuclide distribution on the flow phase and soft tissue phase was symmetrical in both limbs of all patients. For the metaphyseal location of implants, the delayed images demonstrated physiological radionuclide distribution in one patient, mildly increased distribution (index up to 1.2) in four, increased uptake (index up to 1.5) in two patients, and highly increased uptake (index above 1.5) in one patient. For the diaphyseal location of implants, the delayed scans demonstrated slightly increased radionuclide distribution in two, markedly increased in two and highly increased uptake in eight patients.

DISCUSSION:
The tissue during incorporation of a non-resorbable synthetic material is influenced by stress-shielding. This changes local mechanical signals, which has a negative effect on the adjacent bone tissue. Stress accumulating at the interface of a rigid implant and bone tissue may result in pain, and is detected by scintigraphy as an increased nucleotide uptake, particularly in diaphyseal grafts.

CONCLUSIONS:
This paper presents problems associated with implantation of the non-resorbable bioactive glass-ceramic material BAS-0 in the treatment of diaphyseal defects of long bones. The results show that, for filling of the defects described herein, non-resorbable glass-ceramic materials are not suitable.

Keywords: bioactive glass-ceramic material, bone scan

Accepted: March 2, 2006; Published: June 1, 2006  Show citation

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©PONER P, URBAN K, URBANOVÁ E. Scintigraphic Detection of Osteoblast Activity after Implantation of BAS-0 Bioactive Glass-Ceramic Material into Long Bone Defects. Acta Chir Orthop Traumatol Cech. 2006;73(3):176-182. doi: 10.55095/achot2006/025. PubMed PMID: 16846563.
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