Damage Control Laparotomy Wound Incisions Can Be Closed With Low Rates of Superficial Surgical Site Infections.

Due to high rates of surgical site infections (SSIs) in damage control laparotomies (DCLs), many surgeons leave wounds to heal by secondary intention. We hypothesize that patients after DCL can have their wounds primarily closed with wicks/Penrose drains with low rates of superficial surgical site infections. A retrospective review of a prospectively maintained DCL database was performed for all patients who underwent DCL from January 2016 to June 2018. From January 2016 to June 2018, a total of 171 patients underwent DCL. After exclusions, 107 patients were reviewed to assess for SSI. 57 patients were closed with wicks/Penrose drains, 3 were closed with delayed primary closure, and 47 patients were closed completely at time of fascial closure. There were 4 (3.7%) superficial SSIs, 13 (12.1%) organ space infections, and 14 surgical site occurrences (3 of which required opening the skin). Primary closure of incisions after DCL has low superficial SSI rates.

Neuropeptide-Induced Mast Cell Degranulation and Characterization of Signaling Modulation in Response to IgE Conditioning.

As tissue-resident immune cells, mast cells are frequently found in close proximity to afferent neurons and are subjected to immunoactive mediators secreted by these neurons, including substance P (SP) and calcitonin gene-related peptide (CGRP). Neurogenic inflammation is thought to play an important role in the pathophysiology of many diseases. Unraveling the cellular mechanisms at the interface between the immune response and the peripheral nervous system is important for understanding how these diseases arise and progress. In this work, mast cell degranulation following direct exposure to CGRP and SP was studied both at the bulk and single-cell levels to characterize the mouse peritoneal mast cell response to neuropeptides and compare this response to well-studied mast cell activation pathways. Results show that mast cells secrete fewer chemical messenger-filled granules with increased IgE preincubation concentrations. The biophysical characteristics of mast cell degranulation in response to SP and CGRP is in many ways similar to calcium ionophore-induced mast cell degranulation; however, neuropeptide-stimulated mast cells secrete reduced chemical messenger content per secretion event, resulting in an overall relative decrease in secreted chemical messengers.

Outcomes of Endoscopic Stenting for Traumatic Biliary and Pancreatic Fistulae.

The role of endoscopic retrograde cholangiopancreatography (ERCP) in the trauma patient is limited. Therefore, reporting of outcomes is sparse in the literature. The purpose of this study was to review outcomes of patients who underwent ERCP for traumatic biliopancreatic injury. We retrospectively reviewed 1550 ERCPs, from a prospectively maintained database, performed by a single surgical endoscopist consulted by the trauma surgical service for the management of traumatic fistulae. Referral was made for patients with high output (greater than 200 mL/d) and/or persistent (failure to resolve within 30 days) fistulae and traumatic biliary stricture. Primary end point was postprocedural complications. Secondary end points included patient characteristics, stents placed, and duration of stenting. Seventeen patients underwent a total of 31 ERCPs for biliary and/or pancreatic injury resulting from abdominal trauma (eight penetrating, nine blunt). Fourteen patients had ERCP after laparotomy, with a mean interval to ERCP of 74 days. In three patients, ERCP was the only intervention required. Fourteen biliary stents were placed, seven of which were metallic. Ten pancreatic stents were placed; one proximally migrated but was successfully retrieved. Four patients had both ducts simultaneously stented. The mean duration of stenting was 158 days. All fistulae resolved after stenting. There were no serious complications.

Single-cell analysis of mast cell degranulation induced by airway smooth muscle-secreted chemokines.

BACKGROUND: Asthma is a chronic inflammatory disease characterized by narrowed airways, bronchial hyper-responsiveness, mucus hyper-secretion, and airway remodeling. Mast cell (MC) infiltration into airway smooth muscle (ASM) is a defining feature of asthma, and ASM regulates the inflammatory response by secreting chemokines, including CXCL10 and CCL5. Single cell analysis offers a unique approach to study specific cellular signaling interactions within large and complex signaling networks such as the inflammatory microenvironment in asthma. METHODS: Carbon-fiber microelectrode amperometry was used to study the effects of ASM-secreted chemokines on mouse peritoneal MC degranulation. RESULTS: MC degranulation in response to CXCL10 and CCL5 was monitored at the single cell level. Relative to IgE-mediated degranulation, CXCL10- and CCL5-stimulated MCs released a decreased amount of serotonin per granule with fewer release events per cell. Decreased serotonin release per granule was correlated with increased spike half-width and rise-time values. CONCLUSIONS: MCs are directly activated by ASM-associated chemokines. CXCL10 and CCL5 induce less robust MC degranulation compared to IgE- and A23187-stimulation. The kinetics of MC degranulation are signaling pathway-dependent, suggesting a biophysical mechanism of regulated degranulation that incorporates control over granule trafficking, transport, and docking machinery. GENERAL SIGNIFICANCE: The biophysical mechanisms, including variations in number of exocytotic release events, serotonin released per granule, and the membrane kinetics of exocytosis that underlie MC degranulation in response to CXCL10 and CCL5 were characterized at the single cell level. These findings clarify the function of ASM-derived chemokines as instigators of MC degranulation relative to classical mechanisms of MC stimulation.

Time- and concentration-dependent effects of exogenous serotonin and inflammatory cytokines on mast cell function.

Mast cells play a significant role in both the innate and adaptive immune response; however, the tissue-bound nature of mast cells presents an experimental roadblock to performing physiologically relevant mast cell experiments. In this work, a heterogeneous cell culture containing primary culture murine peritoneal mast cells (MPMCs) was studied to characterize the time-dependence of mast cell response to allergen stimulation and the time- and concentration-dependence of the ability of the heterogeneous MPMC culture to uptake and degranulate exogenous serotonin using high performance liquid chromatography (HPLC) coupled to an electrochemical detector. Additionally, because mast cells play a central role in asthma, MPMCs were exposed to CXCL10 and CCL5, two important asthma-related inflammatory cytokines that have recently been shown to induce mast cell degranulation. MPMC response to both allergen exposure and cytokine exposure was evaluated for 5-HT secretion and bioactive lipid formation using ultraperformance liquid chromatography coupled to an electrospray ionization triple quadrupole mass spectrometer (UPLC-MS/MS). In this work, MPMC response was shown to be highly regulated and responsive to subtle alterations in a complex environment through time- and concentration-dependent degranulation and bioactive lipid formation. These results highlight the importance of selecting an appropriate mast cell model when studying mast cell involvement in allergic response and inflammation.

Carbon-fiber microelectrode amperometry reveals sickle-cell-induced inflammation and chronic morphine effects on single mast cells.

Sickle cell disease, caused by a mutation of hemoglobin, is characterized by a complex pathophysiology including an important inflammatory component. Mast cells are tissue-resident leukocytes known to influence a range of immune functions in a variety of different ways, largely through the secretion of biologically active mediators from preformed granules. However, it is not understood how mast cells influence the inflammatory environment in sickle cell disease. A notable consequence of sickle cell disease is severe pain. Therefore, morphine is often used to treat this disease. Because mast cells express opioid receptors, it is pertinent to understand how chronic morphine exposure influences mast cell function and inflammation in sickle cell disease. Herein, carbon-fiber microelectrode amperometry (CFMA) was used to monitor the secretion of immunoactive mediators from single mast cells. CFMA enabled the detection and quantification of discrete exocytotic events from single mast cells. Mast cells from two transgenic mouse models expressing human sickle hemoglobin (hBERK1 and BERK) and a control mouse expressing normal human hemoglobin (HbA-BERK) were monitored using CFMA to explore the impact of sickle-cell-induced inflammation and chronic morphine exposure on mast cell function. This work, utilizing the unique mechanistic perspective provided by CFMA, describes how mast cell function is significantly altered in hBERK1 and BERK mice, including decreased serotonin released compared to HbA-BERK controls. Furthermore, morphine was shown to significantly increase the serotonin released from HbA-BERK mast cells and demonstrated the capacity to reverse the observed sickle-cell-induced changes in mast cell function.

Electroanalytical eavesdropping on single cell communication.

This article reviews measurement of single cell exocytosis with microelectrodes, covering history, basic instrumentation, cell types investigated, and fundamental insight gained.