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

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.

[1]  M. Morris,et al.  Raman spectroscopy demonstrates prolonged alteration of bone chemical composition following extremity localized irradiation. , 2013, Bone.

[2]  R. Ord,et al.  Treatment rationale for pathological fractures of the mandible: a series of 44 fractures. , 2008, International journal of oral and maxillofacial surgery.

[3]  S. Buchman,et al.  Dose-Response Effect of Human Equivalent Radiation in the Mandible , 2013, The Journal of craniofacial surgery.

[4]  D. H. Kohn,et al.  Ultrastructural Changes Accompanying the Mechanical Deformation of Bone Tissue: A Raman Imaging Study , 2003, Calcified Tissue International.

[5]  A. Boskey,et al.  Infrared Assessment of Bone Quality: A Review , 2011, Clinical orthopaedics and related research.

[6]  R. Weber,et al.  Local recurrence in head and neck cancer: relationship to radiation resistance and signal transduction. , 2002, Clinical cancer research : an official journal of the American Association for Cancer Research.

[7]  K. K. Mahato,et al.  Osteoradionecrosis (ORN) of the Mandible: A Laser Raman Spectroscopic Study , 2003, Applied spectroscopy.

[8]  Paul I. Okagbare,et al.  Noninvasive Raman spectroscopy of rat tibiae: approach to in vivo assessment of bone quality , 2012, Journal of biomedical optics.

[9]  R. Marx Osteoradionecrosis: a new concept of its pathophysiology. , 1983, Journal of oral and maxillofacial surgery : official journal of the American Association of Oral and Maxillofacial Surgeons.

[10]  S. Goldstein,et al.  Raman spectroscopy demonstrates Amifostine induced preservation of bone mineralization patterns in the irradiated murine mandible. , 2013, Bone.

[11]  D. Brizel,et al.  Influence of intravenous amifostine on xerostomia, tumor control, and survival after radiotherapy for head-and- neck cancer: 2-year follow-up of a prospective, randomized, phase III trial. , 2005, International journal of radiation oncology, biology, physics.

[12]  S. Buchman,et al.  The effect of Amifostine prophylaxis on bone densitometry, biomechanical strength and union in mandibular pathologic fracture repair. , 2013, Bone.

[13]  M. Panjabi,et al.  Postfracture irradiation effects on the biomechanical and histologic parameters of fracture healing , 1991, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[14]  Paul I. Okagbare,et al.  Early detection of burn induced heterotopic ossification using transcutaneous Raman spectroscopy. , 2013, Bone.

[15]  C. Grau,et al.  Chemical radioprotection: a critical review of amifostine as a cytoprotector in radiotherapy. , 2003, Seminars in radiation oncology.

[16]  Michael D Morris,et al.  Raman Assessment of Bone Quality , 2011, Clinical orthopaedics and related research.

[17]  Mary-Ann Mycek,et al.  Quantitative polarized Raman spectroscopy in highly turbid bone tissue. , 2010, Journal of biomedical optics.

[18]  S. Buchman,et al.  Amifostine preserves osteocyte number and osteoid formation in fracture healing following radiotherapy. , 2014, Journal of oral and maxillofacial surgery : official journal of the American Association of Oral and Maxillofacial Surgeons.

[19]  B. Vikram,et al.  Phase III randomized trial of amifostine as a radioprotector in head and neck cancer. , 2001, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[20]  S. Goldstein,et al.  Dose-Response Effect of Human Equivalent Radiation in the Murine Mandible: Part II. A Biomechanical Assessment , 2011, Plastic and reconstructive surgery.

[21]  Michael D. Morris,et al.  Transcutaneous Raman Spectroscopy of Murine Bone In Vivo , 2009, Applied spectroscopy.

[22]  S. Weiner,et al.  Electron imaging and diffraction study of individual crystals of bone, mineralized tendon and synthetic carbonate apatite. , 1991, Connective tissue research.