Facial Skin-Mucosal Biodynamic Blast Injuries and Management

DNA Methylation Patterns of Chronic Explosive Breaching in U.S. Military Warfighters

Background: Injuries from exposure to explosions rose dramatically during the Iraq and Afghanistan wars, which motivated investigation of blast-related neurotrauma. We have undertaken human studies involving military "breachers" -exposed to controlled, low-level blast during a 3-days explosive breaching course. Methods: We screened epigenetic profiles in peripheral blood samples from 59 subjects (in two separate U.S. Military training sessions) using Infinium MethylationEPIC BeadChips. Participants had varying numbers of exposures to blast over their military careers (empirically defined as high ≥ 40, and conversely, low < 39 breaching exposures). Daily self-reported physiological symptoms were recorded. Tinnitus, memory problems, headaches, and sleep disturbances are most frequently reported. Results: We identified 14 significantly differentially methylated regions (DMRs) within genes associated with cumulative blast exposure in participants with high relative to low cumulative blast exposure. Notably, NTSR1 and SPON1 were significantly differentially methylated in high relative to low blast exposed groups, suggesting that sleep dysregulation may be altered in response to chronic cumulative blast exposure. In comparing lifetime blast exposure at baseline (prior to exposure in current training), and top associated symptoms, we identified significant DMRs associated with tinnitus, sleep difficulties, and headache. Notably, we identified KCNN3, SOD3, MUC4, GALR1, and WDR45B, which are implicated in auditory function, as differentially methylated associated with self-reported tinnitus. These findings suggest neurobiological mechanisms behind auditory injuries in our military warfighters and are particularly relevant given tinnitus is not only a primary disability among veterans, but has also been demonstrated in active duty medical records for populations exposed to blast in training. Additionally, we found that differentially methylated regions associated with the genes CCDC68 and COMT track with sleep difficulties, and those within FMOD and TNXB track with pain and headache. Conclusion: Sleep disturbances, as well as tinnitus and chronic pain, are widely reported in U.S. military service members and veterans. As we have previously demonstrated, DNA methylation encapsulates lifetime exposure to blast. The current data support previous findings and recapitulate transcriptional regulatory alterations in genes involved in sleep, auditory function, and pain. These data uncovered novel epigenetic and transcriptional regulatory mechanism underlying the etiological basis of these symptoms.

The Impact of Blast Implosions and Bullet Injury on Maxillary Air Sinus

BACKGROUND

Successive waves and generations of terrorists attacked the Iraqis in the years following the fall of the regime in Iraq in 2003, after the US invasion of the country under the pretext of weapons of mass destruction. Hence, the Iraqi people enrolled in ongoing war with these armed groups which led to massive casualties due to blasts and missile injuries.Mechanism of blasts injury can be classified into primary, secondary, tertiary, and quaternary. While bullet injuries can be classified into low and high-energy injuries, the type and severity of the injury will influence the type of management, together with facilities available in the authors' hospitals.In this study the authors aim to compare between the effects of blast implosions and penetrating missiles on the maxillofacial air containing cavities, specifically the maxillary sinuses.

PATIENTS AND METHODS

Twenty-eight patients (26 male patients [92.85%] and 2 [7.14%] female patients) with maxillary sinus wall fractures were admitted to the authors' maxillofacial surgery Department in the Hospital of specialized surgeries/Baghdad Medical city from July 2014 to November 2016.

RESULTS

Seventy-six percent of the total bullet injuries affect the left side of the face, while shell injuries tend to affect the right side of the face by 60% than the left side.Direct maxillary sinus injuries constitute 76.9% of the injuries caused by bullets, while it constitutes only 40% of shell injuries.

CONCLUSION

Bullet injuries are associated with more severe comminuted fractures in addition to involvement of multiple neighboring bones and this may lead to extensive bone loss, while postoperative complications and infection are more common with improvised explosive devices injuries.

Bones heal, teeth don't! The involvement of dentists in the acute and long-term management of patients injured in the Manchester Arena Bomb

This paper outlines the involvement of dentists in the treatment of patients following the terror attack at Manchester Arena on 22 May 2017. It predominantly describes the role of the authors - a paediatric dental consultant and maxillofacial surgery dental core trainee (DCT). As a result of the incident a number of patients suffered oro-facial injuries, with many treated at Central Manchester Foundation Trust Hospitals' Manchester Royal Infirmary and Royal Manchester Children's Hospital. The major incident response of the trust is discussed, as are the presentation of blast injuries and corresponding NHS guidance. Two paediatric cases present the role of the paediatric dental consultant in the acute, intermediate and long-term management of these patients. The presentation of unique dento-alveolar injuries in the context of other trauma and their subsequent treatment demanded true multidisciplinary management. The importance of teeth and oral health to physical and psycho-social wellbeing and recovery was clear and recognised by other teams involved in the patients' management. The experience reinforced the overall impact dental health has on physical and psycho-social health, and how a holistic approach is integral to treatment of major trauma.

Thermal shell fragment craniofacial injury: biophysics, pathophysiology, and management

This article aims to bring attention to unique risks and burns by thermal shell fragment craniofacial soft tissue injury. Hot shrapnel may inflict burns to major vessel walls and lead to life-threatening hemorrhaging or death, which adds a new challenge for craniofacial surgeons. Morbidity of thermal deep tissue may lead to deep tissue necrosis and infection.Thermal energy (TE) physics, biophysics, and pathophysiological effects relate directly to the amount of heat generated from shell casing detonation, which transfers to skin, deep tissue, as well as brain and leads to life-threatening burning of organs; this is different from shrapnel kinetic energy injury.The unprecedented increase in using a large range of explosives and high-heat thermobaric weapons contributes to the superfluous and unnecessary suffering caused by thermal injury wounds.Surgeons and medics should recognize that a surprising amount of TE can be found in an explosion or detonation of a steel-encased explosive, resulting in TEs ranging from 400 F up to 1000 F.

Effect of biomechanism mine explosion on children: craniofacial injuries and management

The significant bodily violence and harm to children from blast injuries continue to be substantially caused by unexploded ordnance and improved explosive devices. Children have many unique anatomic and pathophysiologic attributes that potentially affect their susceptibility to injury. Consequently, this provides a characteristic profile to mine blast effects and projectile injuries. As a result, children's injuries inflicted on craniofacial tissues, airway compromise, hemorrhage, and brain injuries vary significantly from those inflicted on adults. In children more than adults, it is relevant that the simplest, immediate repair of maxillofacial injury is preferable to a major complex surgical approach that is significantly delayed because of availability.Twenty-one cases of mine blast/shrapnel pediatric maxillofacial injuries were selected to represent categorical varieties of a significant but unknown number of casualties treated successfully. The high number of mortality and morbidity caused by mine blast/projectile necessitates a reappraisal of pediatric craniofacial management training. "Losing a single child's life" is especially unacceptable if that loss was found to be due to the medical preparedness being inadequate or the lack of pediatric knowledge.

Blast injuries to the human mandible: development of a finite element model and a preliminary finite element analysis

OBJECTIVE

In an attempt to explore new tools for constructing a model of blast injuries to the human mandible, a finite element method was used. This model allowed us to perform dynamic simulations and analyse the injury processes and severity of trauma to the human mandible from an explosion striking at the middle mandibular angle.

METHODS

A 3D finite element model of the human mandible was created using digitally visualised CT scanning data of the human mandible. It was used to dynamically simulate the complete injury process of a blast event to a human mandible (at the middle mandibular angle) under the injury conditions of a 600 mg TNT explosion. The model was also used to elucidate the subsequent mandibular damage and the dynamic distribution of several biomechanical indices (e.g., stress, and strain). The resulting data were subjected to a comparative analysis.

RESULTS

Simulation was successfully conducted for injury events in which 600 mg of TNT exploded at 3 cm, 5 cm and 10 cm from the middle mandibular angle of a human mandible; specifically, the simulation included the dynamic injury processes and the distribution of stress and strain in various parts of the damaged mandible. A comparison of the simulation data revealed that different blast distances resulted in considerable variation in the severity and biological indices of the mandibular injury.

CONCLUSION

The finite element model was able to dynamically simulate the blast-initiated trauma processes to a human mandible, which allowed for investigation of the severity of damage to the mandible under different injury conditions. This model and the simulation method are conducive for applications in basic studies and clinical investigations of blast-initiated injury mechanisms of bone tissues.