Xi Lin Jing scite author profile

Background Deferoxamine (DFO) is an iron-chelating agent that has also been shown to increase angiogenesis. We hypothesize that the angiogenic properties of DFO will improve bone regeneration in distraction osteogenesis (DO) after x-ray radiation therapy (XRT) by restoring the vascularity around the distraction site. Material & Methods Three groups of Sprague-Dawley rats underwent distraction of the left mandible. Two groups received pre-operative fractionated XRT, and one of these groups was treated with DFO during distraction. After consolidation, the animals were perfused and imaged with microCT to calculate vascular radiomorphometrics. Results Radiation inflicted a severe diminution in the vascular metrics of the distracted regenerate and consequently led to poor clinical outcome. The DFO treated group revealed improved DO bone regeneration with a substantial restoration and proliferation of vascularity. Conclusions This set of experiments quantitatively demonstrates the ability of DFO to temper the anti-angiogenic effect of XRT in mandibular DO. These exciting results suggest that DFO may be a viable treatment option aimed at mitigating the damaging effects of XRT on new bone formation.

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The Surgical Management of Nerve Gaps

Habre¹,

Bond²,

Jing³

et al. 2018

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Peripheral nerve injuries can result in significant morbidity, including motor and/or sensory loss, which can affect significantly the life of the patient. Nowadays, the gold standard for the treatment of nerve section is end-to-end neurorrhaphy. Unfortunately, in some cases, there is segmental loss of the nerve trunk. Nerve mobilization allows primary repair of the sectioned nerve by end-to-end neurorrhaphy if the gap is less than 1 cm. When the nerve gap exceeds 1 cm, autologous nerve grafting is the gold standard of treatment. To overcome the limited availability and the donor site morbidity, other techniques have been used: vascularized nerve grafts, cellular and acellular allografts, nerve conduits, nerve transfers, and end-to-side neurorrhaphy. The purpose of this review is to present an overview of the literature on the applications of these techniques in peripheral nerve repair. Furthermore, preoperative evaluation, timing of repair, and future perspectives are also discussed.

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Chitosan as a Bone Scaffold Biomaterial

Kozusko

Riccio

Goulart

et al. 2018

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The current standard of care for bone reconstruction, whether secondary to injury, nonunion, cancer resection, or idiopathic bone loss, is autologous bone grafting. Alternatives to autograft and allograft bone substitutes currently being researched are synthetic and natural graft materials that are able to guide bone regeneration. One promising material currently being researched is chitosan, a highly versatile, naturally occurring polysaccharide, derived from the exoskeleton of arthropods that is comprised of glucosamine and N-acetylglucosamine. Research on chitosan as a bone scaffold has been promising. Chitosan is efficacious in bone regeneration due to its lack of immunogenicity, its biodegradability, and its physiologic features. Chitosan combined with growth factors and/or other scaffold materials has proven to be an effective alternative to autologous bone grafts. Additionally, current studies have shown that it can provide the additional benefit of a local drug delivery system. As research in the area of bone scaffolding continues to grow, further clinical research on chitosan in conjunction with growth factors, proteins, and alloplastic materials will likely be at the forefront.

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Frontal Sinus Fractures: Management and Complications

Jing

Luce

2019

Craniomaxillofacial Trauma & Reconstruction

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Frontal sinus fractures are relatively rare maxillofacial injuries (only 5–15% of all facial fractures). The appropriate management of frontal sinus fracture and associated pathology is controversial. Diagnosis and treatment of frontal sinus fractures has improved with the advances of high-resolution computed tomography technology. Treatment of frontal sinus fractures depends on several factors, including contour deformity of anterior table; the presence of CSF leak or air–fluid level in the sinus, likelihood of nasofrontal duct obstruction, and degree of displacement of posterior table. Nasofrontal duct patency should be checked if fracture pattern is highly suspicious of ductal injury. Cranialization is performed in cases of severely comminuted posterior wall fracture. Long-term complication of frontal sinus fracture can occur up to 10 years after initial injury or intervention; so, judicious long-term follow-up is warranted. This article presents the management and complications of frontal sinus fractures.

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Xi Lin Jing

Deferoxamine reverses radiation induced hypovascularity during bone regeneration and repair in the murine mandible

The Surgical Management of Nerve Gaps

Chitosan as a Bone Scaffold Biomaterial

Frontal Sinus Fractures: Management and Complications

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