Dose-Response Effect of Human Equivalent Radiation in the Murine Mandible

Tchanque-Fossuo, Catherine N.; Monson, Laura A.; Farberg, Aaron S.; Donneys, Alexis; Deshpande, Sagar S.; Razdolsky, Elizabeth R.; Halonen, Neil R.; Goldstein, Steven A.; Buchman, Steven R.

doi:10.1097/prs.0b013e31822b67ae

Cited by 33 publications

(16 citation statements)

References 21 publications

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“…According to Nyaruba et al (21) and Wernle et al (22), alterations in bone strength seem to be more related to changes in the trabecular morphology than in the cortical morphology of irradiated bone. Nevertheless, the influence of ionizing radiation on the mechanical properties of bone was not yet fully clarified, as there are conflicting reports in previous studies (11,(21)(22)(23). In addition, the micro-CT images (Fig.…”

Section: Discussionmentioning

confidence: 99%

Meloxicam as a Radiation-Protective Agent on Mandibles of Irradiated Rats

et al. 2017

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This study evaluated the action of ionizing radiation and the possible radioprotective effect of the non-steroidal anti-inflammatory drug meloxicam on the bone physiology of rat mandibles by assessing the alveolar socket healing and bone strength. Forty male Wistar rats were divided in 4 groups (n=10): control (CG), irradiated (IG), meloxicam (MG), meloxicam irradiated (MIG). A dose of 0.2 mg/kg meloxicam was administered to MG and MIG. After this, IG and MIG were irradiated with 15 Gy radiation dose in the mandible. Forty days after the above procedures, the mandibular first molars were extracted and the animals were killed after 15 or 30 days (n=5). Micro-computed tomography and bending test were used to evaluate alveolar socket healing and bone strength, respectively. At 15 days, bone volume, bone volume fraction and trabecular thickness were higher in the CG and MG than in the IG and MIG; and trabecular separation was higher in the IG compared with the others. At 30 days, there was a difference only in trabecular separation, which was higher in IG than in CG and MG, and MIG did not differ from the others. Bone strength was lower in IG compared with CG and MG, and MIG did not differ from the others. In conclusion, the ionizing radiation affected the bone physiology of rat mandibles, delaying the alveolar socket healing and reducing the bone strength. Moreover, the meloxicam had a positive effect on the trabecular separation in alveolar socket healing and on the bone strength.

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Section: Discussionmentioning

confidence: 99%

Meloxicam as a Radiation-Protective Agent on Mandibles of Irradiated Rats

et al. 2017

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“…Both radiation groups received a previously established fractionated dose of 7 Gy/day for 5 days (35 Gy total), equivalent to a human dose of 70 Gy (20, 21). Following a 56-day recovery period, mandibles were perfused with Microfil, dissected, and imaged with µCT.…”

Section: Methodsmentioning

confidence: 99%

“…Rat hemimandibles were irradiated using a Philips RT250 orthovoltage unit (250 kV, 15 mA) (Kimtron Medical), fractionating the dose at 7 gray per day over 5 days, for a 35 Gray total, in the Irradiation Core at the University of Michigan Cancer Center (20, 21). Rats were anesthetized using an Isofluorane/Oxygen mixture (2% and 1 L/min), and placed right side down, exposing only the left hemimandible to radiation therapy.…”

Section: Methodsmentioning

confidence: 99%

Prophylactic administration of Amifostine protects vessel thickness in the setting of irradiated bone

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Deshpande

Nelson

et al. 2015

Journal of Plastic, Reconstructive & Aesthetic Surgery

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Although often beneficial in the treatment of head and neck cancer (HNC), radiation therapy (XRT) leads to the depletion of vascular supply and eventually decreased perfusion of the tissue. Specifically, previous studies have demonstrated the depletion of vessel volume fraction (VVF) and vessel thickness (VT) associated with XRT. Amifostine (AMF) provides protection from the detrimental effects of radiation damage, allowing for reliable post-irradiation fracture healing in the murine mandible. The purpose of this study is to investigate the prophylactic ability of AMF to protect the vascular network in an irradiated field. Sprague-Dawley rats (n=17) were divided into 3 groups: control (C, n=5), radiated (XRT, n=7), and radiated mandibles treated with Amifostine (AMF XRT, n=5). Both groups receiving radiation underwent a previously established, human equivalent dose of XRT totaling 35 Gray, equally fractionated over 5 days. The AMF XRT group received a weight dependent (0.5mg AMF/5g body weight) subcutaneous injection of AMF 45 minutes prior to XRT. Following a 56-day recovery period, mandibles were perfused, dissected, and imaged with µCT. ANOVA was used for comparisons between groups and p < 0.05 was considered statistically significant. Stereologic analysis demonstrated a significant and quantifiable restoration of VT in AMF treated mandibles as compared to those treated with radiation alone (0.061±.011mm versus 0.042±0.004mm, p=0.027). Interestingly, further analysis demonstrated no significant difference in VT between control mandibles and those treated with AMF (0.067±0.016mm versus 0.061±0.011mm, p=0.633). AMF treatment also showed an increase in VVF, however those results were not statistically significant from VVF values demonstrated by the XRT group. Our data support the contention that AMF therapy acts prophylactically to protect vessel thickness, as AMF-treated mandibles demonstrate VT levels that are not statistically different from controls in the setting of irradiation. Based on these findings, we support the continued investigation of this treatment paradigm in its potential translation for the prevention of vascular depletion after radiotherapy.

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“…We collaborated with the Experimental Irradiation Core of the University of Michigan Comprehensive Cancer Center to calculate a head and neck cancer human-equivalent dose radiation regimen of 70 Gy total [17]. Fractions were administered once daily over five consecutive days using a Philips RT250 orthovoltage unit (250 kV X-rays, 15 mA; Kimtron Medical, Oxford, CT, USA).…”

Section: Methodsmentioning

confidence: 99%

Raman spectroscopy delineates radiation-induced injury and partial rescue by amifostine in bone: a murine mandibular model

et al. 2014

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Despite its therapeutic role in head and neck cancer, radiation administration degrades the biomechanical properties of bone and can lead to pathologic fracture and osteoradionecrosis. Our laboratories have previously demonstrated that prophylactic amifostine administration preserves the biomechanical properties of irradiated bone and that Raman spectroscopy accurately evaluates bone composition ex vivo. As such, we hypothesize that Raman spectroscopy can offer insight into the temporal and mechanical effects of both irradiation and amifostine administration on bone to potentially predict and even prevent radiation-induced injury. Male Sprague–Dawley rats (350–400 g) were randomized into control, radiation exposure (XRT), and amifostine pre-treatment/radiation exposure groups (AMF-XRT). Irradiated animals received fractionated 70 Gy radiation to the left hemi-mandible, while AMF-XRT animals received amifostine just prior to radiation. Hemi-mandibles were harvested at 18 weeks after radiation, analyzed via Raman spectroscopy, and compared with specimens previously harvested at 8 weeks after radiation. Mineral (ρ958) and collagen (ρ1665) depolarization ratios were significantly lower in XRT specimens than in AMF-XRT and control specimens at both 8 and 18 weeks. amifostine administration resulted in a full return of mineral and collagen depolarization ratios to normal levels at 18 weeks. Raman spectroscopy demonstrates radiation-induced damage to the chemical composition and ultrastructure of bone while amifostine prophylaxis results in a recovery towards normal, native mineral and collagen composition and orientation. These findings have the potential to impact on clinical evaluations and interventions by preventing or detecting radiation-induced injury in patients requiring radiotherapy as part of a treatment regimen.

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Dose-Response Effect of Human Equivalent Radiation in the Murine Mandible

Cited by 33 publications

References 21 publications

Meloxicam as a Radiation-Protective Agent on Mandibles of Irradiated Rats

Meloxicam as a Radiation-Protective Agent on Mandibles of Irradiated Rats

Prophylactic administration of Amifostine protects vessel thickness in the setting of irradiated bone

Raman spectroscopy delineates radiation-induced injury and partial rescue by amifostine in bone: a murine mandibular model

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