A dual-radioisotope hybrid whole-body micro-positron emission tomography/computed tomography system reveals functional heterogeneity and early local and systemic changes following targeted radiation to the murine caudal skeleton.

The purpose of this study was to develop a longitudinal non-invasive functional imaging method using a dual-radioisotope hybrid micro-positron emission tomography/computed tomography (PET/CT) scanner in order to assess both the skeletal metabolic heterogeneity and the effect of localized radiation that models therapeutic cancer treatment on marrow and bone metabolism. Skeletally mature BALB/c female mice were given clinically relevant local radiation (16 Gy) to the hind limbs on day 0. Micro-PET/CT acquisition was performed serially for the same mice on days -5 and +2 with FDG and days -4 and +3 with NaF. Serum levels of pro-inflammatory cytokines were measured. Significant differences (p < 0.0001) in marrow metabolism (measured by FDG) and bone metabolism (measured by NaF) were observed among bones before radiation, which demonstrates functional heterogeneity in the marrow and mineralized bone throughout the skeleton. Radiation significantly (p < 0.0001) decreased FDG uptake but increased NaF uptake (p = 0.0314) in both irradiated and non-irradiated bones at early time points. An increase in IL-6 was observed with a significant abscopal (distant) effect on marrow and bone metabolic function. Radiation significantly decreased circulating IGF-1 (p < 0.01). Non-invasive longitudinal imaging with dual-radioisotope micro-PET/CT is feasible to investigate simultaneous changes in marrow and bone metabolic function at local and distant skeletal sites in response to focused radiation injury. Distinct local and remote changes may be affected by several cytokines activated early after local radiation exposure. This approach has the potential for longer-term studies to clarify the effects of radiation on marrow and bone.

The influence of therapeutic radiation on the patterns of bone remodeling in ovary-intact and ovariectomized mice.

Our purpose was to characterize changes in bone remodeling associated with localized radiation that models therapeutic cancer treatment in ovary-intact (I) and ovariectomized (OVX) mice and to evaluate the influence of radiation on the pattern of bone mineral remodeling. Young adult, female BALB/c mice, I and OVX, were used (n = 71). All mice were intravenously injected with 15 µCi (45)Ca. Thirty days post-(45)Ca administration, the hind limbs of 17 mice were exposed to a single dose of 16 Gy radiation (R). The time course of (45)Ca excretion, serum CTx and osteocalcin markers, and cancellous bone volume fraction (BV/TV) and cortical thickness (Ct.Th) of the distal femur were assayed. Cellular activity and dynamic histomorphometry were performed. Irradiation resulted in rapid increases in fecal (45)Ca excretion compared to control groups, indicating increased bone remodeling. CTx increased rapidly after irradiation, followed by an increase in osteocalcin concentration. BV/TV decreased in the I mice following irradiation. Ct.Th increased in the OVX groups following irradiation. I+R mice exhibited diminished osteoblast surface, osteoclast number, and mineral apposition. Our murine model showed the systemic effects (via (45)Ca excretion) and local effects (via bone microarchitecture and surface activity) of clinically relevant, therapeutic radiation exposure. The I and OVX murine models have similar (45)Ca excretion but different bone microarchitectural responses. The (45)Ca assay effectively indicates the onset and rate of systemic bone mineral remodeling, providing real-time assessment of changes in bone histomorphometric parameters. Monitoring bone health via a bone mineral marker may help to identify the appropriate time for clinical intervention to preserve skeletal integrity.

Skeletal remodeling following clinically relevant radiation-induced bone damage treated with zoledronic acid.

Our aim was to determine if zoledronic acid (ZA) changes (45)Ca pharmacokinetics and bone microstructure in irradiated, ovary-intact (I) and irradiated, ovariectomized mice (OVX), two groups with different patterns of skeletal damage. The hind limbs of I and OVX BALB/c mice received a single 16-Gy radiation dose, simulating pre- and postmenopausal female cancer patients undergoing radiation treatment. All I and OVX mice were radiolabeled with 15 µCi (45)Ca. Mice were treated with or without a 0.5 mg/kg injection of ZA. The time course of bone mineral remodeling was evaluated using a fecal (45)Ca assay, measured by liquid scintillation. A group of nonirradiated, intact mice were used for the longitudinal evaluation of (45)Ca biodistribution. Distal femur bone histomorphometric parameters were measured using microCT at 50 days post-ZA intervention. Most (45)Ca was incorporated into the skeleton and eliminated from the soft tissues within 3-5 days postirradiation, attaining a steady state of excretion at 25-30 days. ZA intervention in both groups resulted in a rapid decrease in fecal (45)Ca excretion. There was a significant difference in (45)Ca excretion in the OVX ± ZA (P = 0.005) group but not in the I ± ZA (P = 0.655) group. The rate of excretion of fecal (45)Ca was slower in the OVX + ZA compared to the I + ZA group (P = 0.064). (45)Ca assay is useful to monitor the time course of bone mineral remodeling after an antiresorptive intervention in irradiated mice, providing a basis to investigate bone effects of cancer therapy protocols. For equivalent doses of ZA, recovery may depend on the nature and degree of skeletal damage.

Paramagnetic microparticles do not elicit islet cytotoxicity with co-culture or host immune reactivity after implantation.

BACKGROUND: Paramagnetic microparticles (MPs) may be useful in pancreatic islet purification, in particular purification of porcine islets as a potential xenotransplantation product. We assessed whether MPs affect islet function or induce an adverse effect following implantation. METHODS: Porcine islets were co-cultured with 0, 500, and 1500 MPs per islet equivalent (IE) for 1 day and with 0 and 1500 MPs/IE for 7 days. Fractional viability was assessed using oxygen consumption rate normalized to DNA content (OCR/DNA) and after 7-day co-culture by perifusion glucose-stimulated insulin secretion (GSIS) and by transplantation under the renal capsule of diabetic nude mice. To assess an inflammatory response or immune reaction, MPs (∼10(7)) were implanted under the renal capsule of C57BL/6 mice. RESULTS: No statistically significant differences were measured in OCR/DNA (mean ± SE) following 1-day co-culture with 0, 500, or 1500 MPs/IE (243.3 ± 4.5, 211.3 ± 8.1, or 230.6 ± 11.3 nmol/min·mgDNA, respectively) or following 7-day co-culture with 0 or 1500 MPs/IE (248.5 ± 1.4 or 252.9 ± 4.7 nmol/min·mgDNA, respectively). GSIS was not affected by the presence of MPs; first- and second-phase insulin area-under-the-curve (mean ± SE) reflected no statistically significant differences after 7-day co-culture between 0 and 1500 MPs/IE (8.36 ± 0.29 and 8.45 ± 0.70 pg/ml·min·ngDNA for first-phase; 69.73 ± 2.18 and 65.70 ± 4.34 pg/ml·min·ngDNA for second-phase, respectively). Islets co-cultured with MPs normalized hyperglycemia in diabetic nude mice, suggesting no adverse effects on in vivo islet function. Implantation of MPs did not elicit tissue injury, inflammatory change or immune reactivity. CONCLUSION: MPs do not adversely affect islet viability or function during co-culture, and MPs are not immune reactive following implantation.

Osteogenic protein-1 overcomes inhibition of fracture healing in the diabetic rat: a pilot study.

Type I diabetes mellitus inhibits fracture healing and leads to an increase in complications. As a pilot study, we used a closed fracture model in the diabetic rat to address the question of whether osteogenic protein-1 (OP-1) in a collagen carrier can overcome this inhibition by increasing the area of the newly mineralized callus and femoral torque to failure compared with diabetic animals with fractures treated without OP-1. Diabetes was created in 54 rats by injection of streptozotocin. After 2 weeks, a closed femur fracture was created using a drop-weight impaction device. Each fracture site was immediately opened and treated with or without 25 microg OP-1 in a collagen carrier. Animals were euthanized after 2 or 4 weeks. Fracture healing was assessed by callus area from high-resolution radiographs, callus strength from torsional failure testing, and undecalcified histologic analysis. The area of newly mineralized callus was greater in diabetic animals treated with 25 microg OP-1/carrier compared with diabetic animals with untreated fractures and with fractures treated with carrier alone. This increase in callus area did not translate into an equivalent increase in torque to failure. Osteogenic protein-1 showed some evidence of overcoming the inhibition of fracture healing in the diabetic rat.

rhBMP-2 modulation of gene expression in infected segmental bone defects.

The osteoinductive capability of BMPs appears diminished in the setting of acute infection. We applied rhBMP-2 to a segmental defect in a rat femur and measured the expression of key bone formation genes in the presence of acute infection. Types I and II collagen, osteocalcin, and BMP Type II receptor mRNA expression were characterized in 72 Sprague-Dawley rats, which received either bovine collagen carrier with 200 mug rhBMP-2 plus Staphylococcus aureus, carrier with bacteria only, carrier with rhBMP-2 only, or carrier alone. Six animals from each group were euthanized at 1, 2, and 4 weeks. Total RNA was isolated and extracted, and mRNA was determined by real-time comparative quantitative PCR. Infected defects had little expression of collagen I and II and osteocalcin mRNAs, while BMP receptor II expression with infection was greater than carrier-only controls at weeks 2 and 4. Notably, all four genes were upregulated in infected defects in the presence of rhBMP-2. Thus, in a clinical setting with a high risk of infection and nonunion, such as a compound fracture with bone loss, rhBMP-2 may increase the rate and extent of bone formation. Even if infection does occur, rhBMP-2 may allow a quicker overall recovery time.

OP-1 augments glucocorticoid-inhibited fracture healing in a rat fracture model.

Glucocorticoids inhibit bone remodeling and fracture healing. We sought to determine whether osteogenic protein 1 (OP-1) can overcome this inhibition in a closed fracture model in the rat. Time-released prednisolone or placebo pellets were implanted subcutaneously; closed femoral fractures were created 2 weeks later in rats. Fractures received sham, OP-1 and collagen, or collagen-only implants. Femurs were harvested at 3, 10, 21, 28, and 42 days postfracture. Fractures were examined radiographically for amount of hard callus; mechanically for torque and stiffness (also expressed as a percentage of the contralateral intact femur); and histomorphometrically for amount of cartilaginous and noncartilaginous soft callus, hard callus, and total callus. Glucocorticoid administration inhibited fracture healing. The application of a devitalized Type I collagen matrix mitigated the inhibitory effects of prednisolone on fracture healing However, further increases in indices of fracture healing were observed when OP-1 was added to the collagen matrix compared with collagen alone. OP-1 and collagen was more effective than collagen alone.

Magnetic Levitation of MC3T3 Osteoblast Cells as a Ground-Based Simulation of Microgravity.

Diamagnetic samples placed in a strong magnetic field and a magnetic field gradient experience a magnetic force. Stable magnetic levitation occurs when the magnetic force exactly counter balances the gravitational force. Under this condition, a diamagnetic sample is in a simulated microgravity environment. The purpose of this study is to explore if MC3T3-E1 osteoblastic cells can be grown in magnetically simulated hypo-g and hyper-g environments and determine if gene expression is differentially expressed under these conditions. The murine calvarial osteoblastic cell line, MC3T3-E1, grown on Cytodex-3 beads, were subjected to a net gravitational force of 0, 1 and 2 g in a 17 T superconducting magnet for 2 days. Microarray analysis of these cells indicated that gravitational stress leads to up and down regulation of hundreds of genes. The methodology of sustaining long-term magnetic levitation of biological systems are discussed.

Characterization of a chronic infection in an internally-stabilized segmental defect in the rat femur.

The aim of this study was to characterize a new model of chronic osteomyelitis with clinically relevant features. A segmental defect of critical size was surgically created in the rat femur, stabilized with a polyacetyl plate and Kirschner wires, and contaminated with bacteria. The animals were allowed to recover while the contamination progressed to a chronic infection. At a later point in time, the defect was surgically débrided without removing the implant. Further treatments of interest, such as antibiotic therapy or application of an osteogenic agent, could be introduced at this time. To implement this model, an initial experiment was performed to determine the bacterial inoculum and time from contamination that would reliably result in an infected defect without causing excessive bone damage by the time débridement surgery was performed. The number of recovered bacteria, degree of radiographic bony lysis, and torsional stiffness of the defect fixation were measured in 192 rats as a function of 4 inocula of Staphylococcus aureus (10(3), 10(4), 10(5) or 10(6) CFUs) and 4 times from contamination (1, 2, 3 or 4 weeks). A 10(4) CFU inoculum over 2 weeks was found to consistently create an infection without severe lysis and loss of fixation stability. Based on these values, a second experiment was performed in 96 rats to characterize the débrided defect over time (2, 4, 8 and 12 weeks after débridement), with and without 4 weeks of the antibiotic ceftriaxone, in terms of the same outcome variables. Infection was persistent in all animals in spite of débridement and antibiotic therapy. Antibiotic therapy did not reduce the degree of bony lysis. Compared with animals not given antibiotic, bacterial counts significantly decreased during the period of antibiotic therapy, but then rebounded to significantly higher levels at 12 weeks. This model allows us to perform further studies on differing regimens of antibiotic therapy and their relationship to surgical débridement, and on the efficacy of osteogenic agents in the presence of infection.

Osteogenic protein-1 induced bone formation in an infected segmental defect in the rat femur.

The goal of this study was to use a segmental defect model in the rat femur to determine if osteogenic protein-1 (OP-1) is capable of inducing bone formation in the presence of bacterial contamination. A 6 mm segmental defect was surgically created and stabilized with a polyacetyl plate and Kirschner wires in one femur in each of 126 Sprague-Dawley rats. The animals were divided into eight groups in which the defect was either left untreated, or subjected to various combinations of OP-1 (11 or 50 microg), lyophilized bovine type I collagen (carrier for the OP-1), and 10(5) colony-forming units of Staphylococcus aureus. The animals were euthanized at either 2, 4, or 9 weeks. Quantitative radiographic and histologic analyses were performed on the harvested tissue. The initial contamination progressed to infection in all animals receiving bacteria, as determined by qualitative bacteriology. There was very little, if any, bone formation in the untreated defects, and in the contaminated defects with or without collagen carrier. Bone formation was significantly greater in contaminated defects with either dose of OP-1, compared with contaminated defects without OP-1. The 50 microg dose of OP-1 induced significantly more bone formation than the 11 microg dose, both with and without bacteria. This investigation has demonstrated that OP-1 maintains its osteoinductive capability in a contaminated segmental defect. OP-1 may potentially be used in the clinical management of contaminated fractures.

Osteogenic protein-1 induces bone formation in the presence of bacterial infection in a rat intramuscular osteoinduction model.

OBJECTIVE: Evaluate the ability of osteogenic protein-1 to induce formation of de novo bone in the presence of bacterial infection and metal in an intramuscular osteoinduction model in the rat. DESIGN: Prospective experimental design with assessment time points of up to 4 weeks. SETTING: Intramuscular pocket surgically created along each side of the spine. ANIMALS: One-hundred-twenty adult male Sprague-Dawley rats. INTERVENTIONS: Each intramuscular pocket received 0, 10, or 25 microg of osteogenic protein-1 combined with a lyophilized collagen carrier, and 0 or 5 x 10 colony-forming units of Staphylococcus aureus. Pockets in 48 animals received a metal implant. Animals were killed at 1, 2, 3, or 4 weeks. MAIN OUTCOME MEASUREMENTS: High-resolution radiographs of resulting nodules of bone/soft tissue were digitized, and areas of newly formed bone were quantified using an image analysis workstation. The nodules were decalcified for histology, and calcium content of the decalcifying solution was quantified by flame atomic absorption spectrophotometry. RESULTS: There were minimal levels of calcium and area of new bone formation in nodules from pockets containing collagen carrier without osteogenic protein-1, for both infection and noninfection conditions. Calcium content and area of newly formed bone were significantly greater: 1) in infected pockets with osteogenic protein-1, compared to infected pockets without osteogenic protein-1; and 2) in noninfected pockets with osteogenic protein-1, compared to infected pockets with osteogenic protein-1. The presence of metal did not have a significant effect. CONCLUSION: Osteogenic protein-1 maintained its osteoinductive capability in a contaminated intramuscular pocket in the rat, albeit at a lower level than without infection. This finding supports further study using a more clinically realistic model.

The influence of therapeutic radiation on the patterns of bone marrow in ovary-intact and ovariectomized mice.

BACKGROUND: The functional components of bone marrow (i.e., the hematopoietic and stromal populations) and the adjacent bone have traditionally been evaluated incompletely as distinct entities rather than the integrated system. We perturbed this system in vivo using a medically relevant radiation model in the presence or absence of ovarian function to understand integrated tissue interaction. METHODOLOGY/PRINCIPAL FINDINGS: Ovary-intact and ovariectomized mice underwent either no radiation or single fractional 16 Gy radiation to the caudal skeleton (I ± R, OVX ± R). Marrow fat, hematopoietic cellularity, and cancellous bone volume fraction (BV/TV %) were assessed. Ovariectomy alone did not significantly reduce marrow cellularity in non-irradiated mice (OVX-R vs. I-R, p = 0.8445) after 30 days; however it impaired the hematopoietic recovery of marrow following radiation exposure (OVX+R vs. I+R, p = 0.0092). The combination of radiation and OVX dramatically increases marrow fat compared to either factor alone (p = 0.0062). The synergistic effect was also apparent in the reduction of hematopoietic marrow cellularity (p = 0.0661); however it was absent in BV/TV% changes (p = 0.2520). The expected inverse relationship between marrow adiposity vs. hematopoietic cellularity and bone volume was observed. Interestingly compared with OVX mice, intact mice demonstrated double the reduction in hematopoietic cellularity and a tenfold greater degree of bone loss for a given unit of expansion in marrow fat. CONCLUSIONS/SIGNIFICANCE: Ovariectomy prior to delivery of a clinically-relevant focal radiation exposure in mice, exacerbated post-radiation adipose accumulation in the marrow space but blunted bone loss and hematopoietic suppression. In the normally coupled homeostatic relationship between the bone and marrow domains, OVX appears to alter feedback mechanisms. Confirmation of this non-linear phenomenon (presumably due to differential radiosensitivity) and demonstration of the mechanism of action is needed to provide strategies to diminish the effect of radiation on exposed tissues.