Neutrophil Accumulation in the Small Intestine Contributes to Local Tissue Destruction Following Combined Radiation and Burn Injury

Extended Reality Use in Paediatric Intensive Care: A Scoping Review

Background: Extended reality (XR) technology such as virtual and augmented reality is increasingly being utilised in paediatric medicine due to its role in medical education and reported positive impacts on outcomes including pain, anxiety, and sleep. To the author's knowledge, no previous reviews investigating the use of XR in paediatric intensive care have been undertaken. Objectives: To scope the use of XR in paediatric intensive care, and assess its barriers to adoption, including safety considerations, cleaning and infection control. Eligibility criteria: All articles of any methodological design discussing the use of XR within paediatric intensive and critical care were included. Sources of evidence: Four databases (EMBASE, CINAHL, PsychInfo, PubMed) and Google Scholar were searched without any limitations on publication year. Charting methods: Data was extracted into Microsoft Excel by two authors independently (AG & SF) and cross-checked for completeness. Results: One hundred and eighty-eight articles were originally identified. Following the application of eligibility criteria 16 articles utilising XR in clinical interventions (n = 7) and medical education (n = 9) were included. Articles utilised VR and AR for highly variable purposes within both medical education (eg disaster preparedness, intubation) and clinical interventions (eg decrease pain, nausea, anxiety and improve Glasgow Coma Scale). Conclusions: While research into the use of XR in paediatric intensive care is still in its infancy it has increased dramatically over the past 5 years within two key areas. Firstly, in healthcare education, to assist in the acquisition of PICU-specific knowledge and practice of skills such as intubation of difficult airways. Secondly, studies have evaluated and demonstrated that with appropriate use, VR appears to be a safe and feasible intervention to decrease pain and anxiety in PICU patients.

Wound Trauma Exacerbates Acute, but not Delayed, Effects of Radiation in Rats: Mitigation by Lisinopril

The goal of this study is to understand and mitigate the effects of wounds on acute radiation syndrome (ARS) and delayed effects of acute radiation exposure (DEARE), for preparedness against a radiological attack or accident. Combined injuries from concomitant trauma and radiation are likely in these scenarios. Either exacerbation or mitigation of radiation damage by wound trauma has been previously reported in preclinical studies. Female WAG/RijCmcr rats received 13 Gy X-rays, with partial-body shielding of one leg. Within 2 h, irradiated rats and non-irradiated controls were given full-thickness skin wounds with or without lisinopril, started orally 7 days after irradiation. Morbidity, skin wound area, breathing interval and blood urea nitrogen were measured up to 160 days post-irradiation to independently evaluate wound trauma and DEARE. Wounding exacerbated morbidity in irradiated rats between 5 and 14 days post-irradiation (during the ARS phase), and irradiation delayed wound healing. Wounding did not alter delayed morbidities from radiation pneumonitis or nephropathy after 30 days post-irradiation. Lisinopril did not mitigate wound healing, but markedly decreased morbidity during DEARE from 31 through 160 days. The results derived from this unique model of combined injuries suggest different molecular mechanisms of injury and healing of ARS and DEARE after radiation exposure.

Neutralization of interleukin-17A alleviates burn-induced intestinal barrier disruption via reducing pro-inflammatory cytokines in a mouse model

Background

The intestinal barrier integrity can be disrupted due to burn injury, which is responsible for local and systemic inflammatory responses. Anti-inflammation strategy is one of the proposed therapeutic approaches to control inflammatory cascade at an early stage. Interleukin-17A (IL-17A) plays a critical role in inflammatory diseases. However, the role of IL-17A in the progression of burn-induced intestinal inflammation is poorly understood. In this study, we aimed to investigate the effect of IL-17A and associated pro-inflammatory cytokines that were deeply involved in the pathogenesis of burn-induced intestinal inflammatory injury, and furthermore, we sought to determine the early source of IL-17A in the intestine.

Methods

Mouse burn model was successfully established with infliction of 30% total body surface area scald burn. The histopathological manifestation, intestinal permeability, zonula occludens-1 expression, pro-inflammatory cytokines were determined with or without IL-17A-neutralization. Flow cytometry was used to detect the major source of IL-17A⁺ cells in the intestine.

Results

Burn caused intestinal barrier damage, increase of intestinal permeability, alteration of zonula occludens-1 expressions, elevation of IL-17A, IL-6, IL-1β and tumor necrosis factor-α (TNF-α), whereas IL-17A neutralization dramatically alleviated burn-induced intestinal barrier disruption, maintained zonula occludens-1 expression, and noticeably, inhibited pro-inflammatory cytokines elevation. In addition, we observed that the proportion of intestinal IL-17A⁺Vγ4⁺ T subtype cells (but not IL-17A⁺Vγ1⁺ T subtype cells) were increased in burn group, and neutralization of IL-17A suppressed this increase.

Conclusions

The main original findings of this study are intestinal mucosa barrier is disrupted after burn through affecting the expression of pro-inflammatory cytokines, and a protective role of IL-17A neutralization for intestinal mucosa barrier is determined. Furthermore, Vγ4⁺ T cells are identified as the major early producers of IL-17A that orchestrate an inflammatory response in the burn model. These data suggest that IL-17A blockage may provide a unique target for therapeutic intervention to treat intestinal insult after burn.

Glutamine protects intestinal mucosa and promotes its transport after burn injury in rats

Glutamine is an important energy source for intestinal epithelial cells (IEC); however, it is still controversial whether glutaminecan be fully utilized under pathological conditions. In this study, we investigated the changes in glutamine transport after burns and assessed the effects of exogenous glutamine administration. Finally, the potential underlying mechanisms were explored. Experimental rats were randomly divided into three groups: control group (C); burn group (B); burn+glutamine group (B+G). Rats in groups B+G and B received intragastric administration of isodose glutamine or alanine, respectively. At days 1, 3 and 5 after burns, the structure of intestinal mucosa and brush-border membrane vesicles (BBMV) were observed. The glutamine transport capacity of IEC and BBMV was detected. The synthesis of glutamine transporter ASCT2 and B0AT1 was determined. Moreover, the intestinal mucosal blood flow (IMBF), diamine oxidase activity, and the glutamine and ATP content were measured. The results showed that burn injury caused structural damage to IECs and BBMV, and significantly impaired the ability for glutamine transportation. Moreover, the mRNA and protein expressions of ASCT2 and B0AT1 as well as the glutamine and ATP content were markedly decreased. Compared with group B, most of these indicators in group B+G showed significant improvement, and approached normal levels. We conclude that glutamine administration can relieve intestinal damage, improve IMBF, promote energy synthesis and alleviate endoplasmic reticulum stress after burn injury. Finally, the synthesis and modification of ASCT2 and B0AT1 are promoted, which ultimately enhances intestinal glutamine transport.

Development of A Novel Murine Model of Combined Radiation and Peripheral Tissue Trauma Injuries

Detonation of a 10-kiloton nuclear bomb in an urban setting would result in >1 million casualties, the majority of which would present with combined injuries. Combined injuries, such as peripheral tissue trauma and radiation exposure, trigger inflammatory events that lead to multiple organ dysfunction (MOD) and death, with gastrointestinal (GI) and pulmonary involvement playing crucial roles. The objective of this study was to develop an animal model of combined injuries, peripheral tissue trauma (TBX animal model) combined with total body irradiation with 5% bone marrow shielding (TBI/BM5) to investigate if peripheral tissue trauma contributes to reduced survival. Male C57BL/6J mice were exposed to TBX10%, irradiation (TBI/BM5), or combined injuries (TBX10% + TBI/BM5). Experiments were conducted to evaluate mortality at day 7 after TBI/BM5. Serial euthanasia was performed at day 1, 3 and 6 or 7 after TBI/BM5 to evaluate the time course of pathophysiologic processes in combined injuries. Functional tests were performed to assess pulmonary function and GI motility. Postmortem samples of lungs and jejunum were collected to assess tissue damage. Results indicated higher lethality and shorter survival in the TBX10% +T BI/BM5 group than in the TBX10% or TBI/BM5 groups (day 1 vs. day 7 and 6, respectively). TBI/BM5 alone had no effects on the lungs but significantly impaired GI function at day 6. As expected, in the animals that received severe trauma (TBX10%), we observed impairment in lung function and delay in GI transit in the first 3 days, effects that decreased at later time points. Trauma combined with radiation (TBX10% + TBI/BM5) significantly augmented impairment of the lung and GI function in comparison to TBX10% and TBI/BM5 groups at 24 h. Histologic evaluation indicated that combined injuries caused greater tissue damage in the intestines in TBX10% + TBI/BM5 group when compared to other groups. We describe here the first combined tissue trauma/radiation injury model that will allow conduction of mechanistic studies to identify new therapeutic targets and serve as a platform for testing novel therapeutic interventions.