Age and Injury Size Influence the Magnitude of Fecal Dysbiosis in Adult Burn Patients

Nonselective beta blockade enhances gut microbiome diversity in a rodent model of trauma, hemorrhage, and chronic stress

BACKGROUND

Traumatic injury leads to gut dysbiosis with changes in microbiome diversity and conversion toward a "pathobiome" signature characterized by a selective overabundance of pathogenic bacteria. The use of non-selective beta antagonism in trauma patients has been established as a useful adjunct to reduce systemic inflammation. We sought to investigate whether beta-adrenergic blockade following trauma would prevent the conversion of microbiome to a "pathobiome" phenotype.

METHODS

Sprague-Dawley rats (n = 6-8/group) were subjected to routine daily handling (naïve), lung contusion with hemorrhagic shock (LCHS), or LCHS with daily chronic stress (LCHS/CS), each with or without administration of intraperitoneal propranolol (BB) (10 mg/kg/day). Fecal microbiome was measured on Days 0, 7, and 14 using high-throughput 16S rRNA sequencing and QIIME2 bioinformatics analyses. Alpha- and beta-diversity and microbiome composition were assessed with significance defined as * p < 0.05.

RESULTS

Use of propranolol following LCHS or LCHS/CS demonstrated a significant increase in the number of bacterial species (Chao1 index), as well as overall richness and evenness (Shannon index) compared with their untreated counterparts at Day 7. By Day 14, these differences were no longer apparent between BB and untreated groups subjected to LCHS/CS. There was an abundance of commensal bacteria such as Oscillospiraceae and Clostridia in LCHS and LCHS/CS treated with BB after 7 days which persisted at 14 days.

CONCLUSION

These findings suggest a role for beta-antagonism in altering the diversity of the gut microbiome and the need for further studies to elucidate the cellular and molecular mechanisms underlying this intriguing connection of microbiome with trauma and beta-blockade.

Advanced Age Worsens Respiratory Function and Pulmonary Inflammation After Burn Injury and This Correlates With Changes in the Fecal Microbiome in Mice

Cutaneous burn injury in the elderly is associated with poor clinical outcomes and increased pulmonary-related complications. We and others have shown that burn injury triggers a cascade of inflammatory mediators which increase gut permeability and dysbiosis of the fecal microbiota and this is more dramatic in the aged. Since crosstalk between intestinal microbes and the lung, termed the "gut-lung axis," impacts immunity and homeostasis in the airway, we hypothesized that the increased intestinal dysbiosis in age and burn injury may contribute to excessive pulmonary inflammation and poor prognosis after injury. To explore this hypothesis, we used a clinically relevant murine model of burn injury in which young and aged mice are subjected to a 12% TBSA dorsal scald burn or sham injury. About 24 h after injury, lung function was assessed and lungs and feces were collected for analysis of inflammatory mediators and fecal microbial species. The results show that, when compared to younger mice, burn injury in aged mice triggers a decline in respiratory function and exacerbates pulmonary inflammation. In addition to heightened levels of the neutrophil recruiting chemokine CXCL1, aged mice displayed a profound increase in the pro-inflammatory protein, calprotectin, in the lung after burn injury. Comparison of the fecal microbiome and inflammatory markers in the lung revealed unique, age-dependent, correlation patterns between individual taxa and pulmonary inflammation. Taken together, these findings suggest that the postburn dysbiosis of the gut flora in aged mice may contribute to the changes in pulmonary inflammatory profiles.

Bacterial dysbiosis and decrease in SCFA correlate with intestinal inflammation following alcohol intoxication and burn injury

Background

Patients intoxicated at the time of burn experience increased rates of sepsis and death compared with that observed in similarly sized burns alone. We sought to characterise changes in the intestinal microbiome and short-chain fatty acids (SCFAs) following alcohol intoxication and burn injury and to determine whether these changes are associated with intestinal inflammation.

Methods

10-12-week-old C57BL/6 male and female mice were subjected to ethanol intoxication and a 12.5% total body surface area scald burn injury. The following day, mice were euthanised and faecal contents from the caecum and small intestine (SI) were harvested for 16S sequencing for microbial analysis and caecum contents underwent high-performance liquid chromatography mass spectroscopy to assess SCFAs.

Results

The intestinal microbiome of ethanol burn (EB) mice exhibited decreased alpha diversity and distinct beta diversity compared with sham vehicle (SV). EB faeces were marked by increased Proteobacteria and many pathobionts. EB caecum faeces exhibited a significant decrease in butyrate and a downward trend in acetate and total SCFAs. SCFA changes correlated with microbial changes particularly in the SI. Treatment of murine duodenal cell clone-K (MODE-K) cells with faecal slurries led to upregulation of interleukin-6 (IL-6) from EB faeces compared with SV faeces which correlated with levels of Enterobacteriaceae. However, supplementation of butyrate reduced faecal slurry-induced MODE-K cells IL-6 release.

Conclusion

Together, these findings suggest that alcohol and burn injury induce bacterial dysbiosis and a decrease in SCFAs, which together can promote intestinal inflammation and barrier disruption, predisposing to postinjury pathology.

A 10-year mono-center study on patients with burns ≥70% TBSA: prediction model construction and multicenter validation - retrospective cohort

BACKGROUND

Burn injuries with ≥70% total body surface area (TBSA) are especially acute and life-threatening, leading to severe complications and terrible prognosis, while a powerful model for the prediction of overall survival (OS) is lacking. The objective of this study is to identify prognostic factors for the OS of patients with burn injury ≥70% TBSA and construct and validate a feasible predictive model.

MATERIALS AND METHODS

Patients diagnosed with burns ≥70% TBSA admitted and treated between 2010 and 2020 in our hospital were included. A cohort of the patients from the Kunshan explosion were assigned as the validation set. The χ2 test and K-M survival analysis were conducted to identify potential predictors for OS. Then, multivariate Cox regression analysis was performed to identify the independent factors. Afterward, we constructed a nomogram to predict OS probability. Finally, the Kunshan cohort was applied as an external validation set.

RESULTS

Sex, the percentage of third-degree and fourth-degree burns as well as organ dysfunction were identified as significant independent factors. A nomogram only based on the factors of the individuals was built and evidenced to have promising predictive accuracy, accordance, and discrimination by both internal and external validation.

CONCLUSIONS

This study recognized significant influencing factors for the OS of patients with burns ≥70% TBSA. Furthermore, our nomogram proved to be an effective tool for doctors to quickly evaluate patients' outcomes and make appropriate clinical decisions at an early stage of treatment.

Reducing the excessive inflammation after burn injury in aged mice by maintaining a healthier intestinal microbiome

One in six people are projected to be 65 years or older by 2050. As the population ages, better treatments for injuries that disproportionately impact the aged population will be needed. Clinical studies show that people aged 65 and older experience higher rates of morbidity and mortality after burn injury, including a greater incidence of pulmonary complications when compared to younger burn injured adults, which we and others believe is mediated, in part, by inflammation originating in the intestines. Herein, we use our clinically relevant model of scald burn injury in young and aged mice to determine whether cohousing aged mice with young mice or giving aged mice oral gavage of fecal material from young mice is sufficient to alter the microbiome of the aged mice and protect them from inflammation in the ileum and the lungs. Aged burn injured mice have less DNA expression of Bacteroidetes in the feces and an unhealthy Firmicutes/Bacteroidetes ratio. Both Bacteroidetes and the ratio of these two phyla are restored in aged burn injured by prior cohousing for a month with younger mice but not fecal transfer from young mice. This shift in the microbiome coincides with heightened expression of danger-associated molecular patterns (DAMP), and pro-inflammatory cytokine interleukin-6 (il6) in the ileum and lung of aged, burn injured mice, and heightened antimicrobial peptide camp in the lung. Cohousing reverses DAMP expression in the ileum and lung, and cathelicidin-related antimicrobial peptide protein (camp) in the lung, while fecal transfer heightened DAMPs while reducing camp in the lung, and also increased IL-6 protein in the lungs. These results highlight the importance of the intestinal microbiome in mediating inflammation within the gut-lung axis, giving insights into potential future treatments in the clinic.

Recent alcohol intake impacts microbiota in adult burn patients

Alcohol use is associated with an increased incidence of negative health outcomes in burn patients due to biological mechanisms that include a dysregulated inflammatory response and increased intestinal permeability. This study used phosphatidylethanol (PEth) in blood, a direct biomarker of recent alcohol use, to investigate associations between a recent history of alcohol use and the fecal microbiota, short chain fatty acids, and inflammatory markers in the first week after a burn injury for nineteen participants. Burn patients were grouped according to PEth levels of low or high and differences in the overall fecal microbial community were observed between these cohorts. Two genera that contributed to the differences and had higher relative abundance in the low PEth burn patient group were Akkermansia, a mucin degrading bacteria that improves intestinal barrier function, and Bacteroides, a potentially anti-inflammatory bacteria. There was no statistically significant difference between levels of short chain fatty acids or intestinal permeability across the two groups. To our knowledge, this study represents the first report to evaluate the effects of burn injury and recent alcohol use on early post burn microbiota dysbiosis, inflammatory response, and levels of short chain fatty acids. Future studies in this field are warranted to better understand the factors associated with negative health outcomes and develop interventional trials.

Effects of Factors Influencing Scar Formation on the Scar Microbiome in Patients with Burns

Skin microbiome dysbiosis has deleterious effects, and the factors influencing burn scar formation, which affects the scar microbiome composition, are unknown. Therefore, we investigated the effects of various factors influencing scar formation on the scar microbiome composition in patients with burns. We collected samples from the burn scar center and margin of 40 patients with burns, subgrouped by factors influencing scar formation. Scar microbiome composition-influencing factors were analyzed using univariate and multivariate analyses. Skin graft, hospitalization period, intensive care unit (ICU) admission, burn degree, sex, age, total body surface area burned (TBSA), time post-injury, transepidermal water loss, the erythrocyte sedimentation rate, and C-reactive protein levels were identified as factors influencing burn scar microbiome composition. Only TBSA and ICU admission were associated with significant differences in alpha diversity. Alpha diversity significantly decreased with an increase in TBSA and was significantly lower in patients admitted to the ICU than in those not admitted to the ICU. Furthermore, we identified microorganisms associated with various explanatory variables. Our cross-sectional systems biology study confirmed that various variables influence the scar microbiome composition in patients with burns, each of which is associated with various microorganisms. Therefore, these factors should be considered during the application of skin microbiota for burn scar management.

Meta-Analysis of Publicly Available Clinical and Preclinical Microbiome Data From Studies of Burn Injury

Following burn injury, alterations in host commensal microbiota across body spaces may leave patients susceptible to opportunistic pathogens and serious sequelae such as sepsis. Generally, studies examining the microbiome postburn have had a limited sample size and lack of longitudinal data, which coupled with experimental and analytic variation, impacts overall interpretation. We performed a meta-analysis of publicly available sequencing data from preclinical and clinical burn studies to determine if there were consistent alterations in the microbiome across various anatomical sites and hosts. Ten human and animal 16S rRNA sequencing studies spanning respiratory, urinary, cutaneous, and gastrointestinal microbiomes were included. Taxonomic classification and alpha and beta diversity metrics were analyzed using QIIME2 v2021.8. Alpha diversity was consistently higher in control samples compared to burn-injured samples which were also different based on host and anatomical location; however, phylogenetic evaluation (ie, Faith PD) elucidated more significant differences compared to taxonomic metrics (ie, Shannon entropy). Beta diversity analysis based on weighted UniFrac showed that rodent specimens clustered less closely to humans than pig samples for both rectal and skin sources. Host species and performing institute were found to have a significant impact on community structure. In rectal samples, bacterial composition in pig and human burn samples included Bacteroidetes, Firmicutes, and Proteobacteria, while rodent samples were dominated by Firmicutes. Proteobacteria and Firmicutes increased on burned skin in each host species. Our results suggest that host species and the performing institute strongly influence microbiome structure. Burn-induced alterations in microbiome diversity and taxa exist across hosts, with phylogenetic metrics more valuable than others. Coordinated, multicenter studies, both clinical and preclinical, within the burn community are needed to more completely realize the diagnostic and therapeutic potential of the microbiome for improving outcomes postburn.

Multicompartmental traumatic injury and the microbiome: Shift to a pathobiome

BACKGROUND

Previous animal models have demonstrated altered gut microbiome after mild traumatic injury; however, the impact of injury severity and critical illness is unknown. We hypothesized that a rodent model of severe multicompartmental injuries and chronic stress would demonstrate microbiome alterations toward a "pathobiome" characterized by an overabundance of pathogenic organisms, which would persist 1 week after injury.

METHODS

Male Sprague-Dawley rats (n = 8 per group) were subjected to either multiple injuries (PT) (lung contusion, hemorrhagic shock, cecectomy, and bifemoral pseudofractures), PT plus daily chronic restraint stress for 2 hours (PT/CS), or naive controls. Fecal microbiome was measured on days 0, 3, and 7 using high-throughput 16S rRNA sequencing and Quantitative Insights Into Microbial Ecology 2 bioinformatics analysis. Microbial α diversity was assessed using Chao1 and Shannon indices, and β diversity with principle coordinate analysis. Intestinal permeability was evaluated by plasma occludin; ileum and descending colon tissues were reviewed for injury. Analyses were performed in GraphPad (GraphPad Software, La Jolla, CA) and R (R Foundation for Statistical Computing, Vienna, Austria), with significance defined as p < 0.05.

RESULTS

There were significant alterations in β diversity at day 3 and between all groups. By day 3, both PT and PT/CS demonstrated significantly depleted bacterial diversity (Chao1) ( p = 0.01 and p = 0.001, respectively) versus naive, which persisted up to day 7 in PT/CS only ( p = 0.001). Anaerostipes and Rothia dominated PT and Lactobacillus bloomed in PT/CS cohorts by day 7. Plasma occludin was significantly elevated in PT/CS compared with naive ( p = 0.04), and descending colon of both PT and PT/CS showed significantly higher injury compared with naive ( p = 0.005, p = 0.006).

CONCLUSIONS

Multiple injuries with and without chronic stress induces significant alterations in microbiome diversity and composition within 3 days; these changes are more prominent and persist for 1 week postinjury with stress. This rapid and persistent transition to a "pathobiome" phenotype represents a critical phenomenon that may influence outcomes after severe trauma and critical illness.

The role and therapeutic potential of gut microbiome in severe burn

Severe burn is a serious acute trauma that can lead to significant complications such as sepsis, multiple organ failure, and high mortality worldwide. The gut microbiome, the largest microbial reservoir in the human body, plays a significant role in this pathogenic process. Intestinal dysbiosis and disruption of the intestinal mucosal barrier are common after severe burn, leading to bacterial translocation to the bloodstream and other organs of the body, which is associated with many subsequent severe complications. The progression of some intestinal diseases can be improved by modulating the composition of gut microbiota and the levels of its metabolites, which also provides a promising direction for post-burn treatment. In this article, we summarised the studies describing changes in the gut microbiome after severe burn, as well as changes in the function of the intestinal mucosal barrier. Additionally, we presented the potential and challenges of microbial therapy, which may provide microbial therapy strategies for severe burn.