Failure rates of nonoperative management of low-grade splenic injuries with active extravasation: an Eastern Association for the Surgery of Trauma multicenter study.

Objectives: There is little evidence guiding the management of grade I-II traumatic splenic injuries with contrast blush (CB). We aimed to analyze the failure rate of nonoperative management (NOM) of grade I-II splenic injuries with CB in hemodynamically stable patients. Methods: A multicenter, retrospective cohort study examining all grade I-II splenic injuries with CB was performed at 21 institutions from January 1, 2014, to October 31, 2019. Patients >18 years old with grade I or II splenic injury due to blunt trauma with CB on CT were included. The primary outcome was the failure of NOM requiring angioembolization/operation. We determined the failure rate of NOM for grade I versus grade II splenic injuries. We then performed bivariate comparisons of patients who failed NOM with those who did not. Results: A total of 145 patients were included. Median Injury Severity Score was 17. The combined rate of failure for grade I-II injuries was 20.0%. There was no statistical difference in failure of NOM between grade I and II injuries with CB (18.2% vs 21.1%, p>0.05). Patients who failed NOM had an increased median hospital length of stay (p=0.024) and increased need for blood transfusion (p=0.004) and massive transfusion (p=0.030). Five patients (3.4%) died and 96 (66.2%) were discharged home, with no differences between those who failed and those who did not fail NOM (both p>0.05). Conclusion: NOM of grade I-II splenic injuries with CB fails in 20% of patients. Level of evidence: IV.

Treatment of Abdominal Aortic Aneurysm Utilizing Adipose-Derived Mesenchymal Stem Cells in a Porcine Model.

INTRODUCTION: The current treatment paradigm of abdominal aortic aneurysms (AAA) focuses on observing patients until their disease reaches certain thresholds for intervention, with no preceding treatment available. There is an opportunity to develop novel therapies to prevent further aneurysmal growth and decrease the risk of a highly morbid rupture. We used a porcine model of aortic dilation to assess the ability of human adipose-derived mesenchymal stem cells (MSCs) to attenuate aortic dilation. MATERIALS AND METHODS: Twelve Yorkshire pigs received periadventitial injections (collagenase and elastase) into a 4-cm segment of infrarenal aorta. Animals were treated with either 1 × 106 MSCs placed onto Gelfoam or treated with media as a control. Aortic diameters were measured at the time of surgery and monitored at postoperative day (POD) 7 and 14 with ultrasound. Animals were sacrificed on POD 21. Aortic tissue was harvested for histopathological analyses and immunohistochemistry. Groups were compared with paired t-tests or Mann-Whitney U-tests. RESULTS: All animals survived until POD 21. The mean aortic diameter was reduced in the aortic dilation + MSC treatment group compared to aortic dilation control animals (1.10 ± 0.126 versus 1.48 cm ± 0.151, P < 0.001). Aortic media thickness was reduced in the aortic dilation group compared to the aortic dilation + MSC group (609.14 IQR 445.21-692.93 µm versus 643.55 IQR 560.91-733.88 µm, P = 0.0048). There was a significant decrease in the content of collagen and alpha-smooth muscle actin and elastin perturbation in the aortic dilation group as compared to the aortic dilation + MSC group. Immunohistochemistry demonstrated an increased level of vascular endothelial growth factor, tissue inhibitor of matrix metalloproteinase 1, and tissue inhibitor of matrix metalloproteinase 3 expression in the aorta of aortic dilation + MSC animals. CONCLUSIONS: Stem cell therapy suppressed the aortic dilation in a porcine model. Animals from the aortic dilation group showed more diseased gross features, histologic changes, and biochemical properties of the aorta compared to that of the aortic dilation + MSC treated animals. This novel finding should prompt further investigation into translatable drug and cell therapies for aneurysmal disease.

What to do When Decompressive Gastrostomies and Jejunostomies are not Options? A Scoping Review of Transesophageal Gastrostomy Tubes for Advanced Malignancies.

BACKGROUND: In advanced malignant bowel obstruction, decompressive gastrostomy tubes (GTs) may not be feasible due to ascites, peritoneal carcinomatosis, and altered gastric anatomy. Whereas nasogastric tubes (NGTs) allow temporary decompression, percutaneous transesophageal gastrostomy tubes (PTEGs) are an alternative method for long-term palliative decompression. This study performed a scoping review to determine outcomes with PTEG in advanced malignancies. METHODS: A systematic literature search was performed to include all studies that reported the clinical results of PTEGs for malignancy. No language, national, or publication status restrictions were used. RESULTS: The analysis included 14 relevant studies with a total of 340 patients. In 11 studies, standard PTEGs were inserted with a rupture-free balloon's placement into the mouth or nose and esophageal puncture under fluoroscopy or ultrasound, followed by a guidewire into the stomach with placement of a single-lumen tube. Of 340 patients, 65 (19.1%) had minor complications, and 5 (2.1%) had significant complications, including bleeding and severe aspiration pneumonia. Of 171 patients, 169 with PTEGs (98.8%) reported relief of nasal discomfort from NGT and alleviation of obstructive symptoms. The one randomized controlled trial reported a significantly higher quality of life with PTEGs than with NGTs. CONCLUSIONS: When decompression for advanced malignancy is technically not feasible with a gastrostomy tube, the PTEG is a viable, safe option for palliation. The PTEG is associated with lower significant complication rates than the gastrostomy tube and significantly higher patient-derived outcomes than the NGT.

Development of a Model for Abdominal Aortic Aneurysms in Swine.

INTRODUCTION: Producing a reliable large-animal model of AAA has proven challenging. We sought to create a reproducible swine model of AAA using enzymatic degradation of the aortic wall. METHODS: Twelve male Yorkshire swine received periadventitial injections of type 1 collagenase and porcine pancreatic elastase into a 4 cm segment of infrarenal aorta. Nine survived until postoperative day (POD) 21. Aortic growth was monitored at 7 and 14 days using ultrasound. The animals were euthanized on POD 21, and the suprarenal (control) and infrarenal aorta were harvested for analysis, after gross measurement of aortic diameter (AD). Tensile strength was measured and additional segments were collected for histopathological analysis. PCR of matrix metalloproteinases (MMP9) was conducted. Groups were compared with paired t-tests, or ANOVA, where appropriate. RESULTS: Average percent growth of AD at POD 21 for treated segments was 27% versus 4.5% for control tissue. The average difference in AD by subject, was 26.7% (P<0.001). Aortic medial thickness was decreased in treated tissue; 235 µm versus 645 µm (P<0.0001). Quantities of both medial elastin fibers, and smooth muscles cells were decreased in treated tissue; 1.8% compared to 9.9% (P<0.0001), and 24% versus 37.4%, respectively. Tensile strength was also decreased in treated tissue; 16.7 MPa versus 29.5 MPa (P=0.0002). A 12-fold increase in expression of MMP9 mRNA was also demonstrated in aneurysmal tissue (P=0.002) CONCLUSION: A reproducible, large-animal model of AAA, with anatomical, histopathological, and biomechanical properties that are clinically translatable, can be achieved with extraluminal enzymatic degradation.

Herpes wound infection after femoral endarterectomy.

Wound infection after common femoral endarterectomy is a well-documented phenomenon leading to significant morbidity, especially in the setting of a prosthetic graft. A push has recently been made in the literature for salvage of the prosthetic graft using debridement, antibiotics, and vacuum-assisted closure therapy. Herein we present the case of wound infection after common femoral endarterectomy with bovine patch angioplasty initially presumed to be of bacterial origin that failed to respond to vacuum-assisted closure therapy until the viral nature of the pathogen was discovered. The patient will continue lifelong valacyclovir for suppressive therapy.

The Structure and Biological Function of CREG.

The cellular repressor of E1A-stimulated genes (CREG) is a 220 amino acid glycoprotein structurally similar to oxidoreductases. However, CREG does not have enzymatic activities because it cannot bind to the cofactor flavin mononucleotide. Although CREG can be secreted, it is mainly an intracellular protein localized in the endocytic-lysosomal compartment. It undergoes proteolytic maturation mediated by lysosomal cysteine proteases. Biochemical studies have demonstrated that CREG interacts with mannose-6-phosphate/insulin-like growth factor-2 receptor (M6P/IGF2R) and exocyst Sec8. CREG inhibits proliferation and induces differentiation and senescence when overexpressed in cultured cells. In Drosophila, RNAi-mediated knockdown of CREG causes developmental lethality at the pupal stage. In mice, global deletion of the CREG1 gene leads to early embryonic death. These findings establish an essential role for CREG in development. CREG1 haploinsufficient and liver-specific knockout mice are susceptible to high fat diet-induced obesity, hepatic steatosis and insulin resistance. The purpose of this review is to provide an overview of what we know about the biochemistry and biology of CREG and to discuss the important questions that remain to be addressed in the future.