Topical oxygen treatment relieves pain from hard-to-heal leg ulcers and improves healing: a case series.

Managing painful hard-to-heal leg ulcers is challenging with current therapeutic options. Wounds are prone to being hypoxic, and the subsequent pain is often related to hypoxia. Hyperbaric oxygen therapy (HBOT) is used to treat hard-to-heal leg wounds by delivering 100% oxygen at a pressure 2-3 times higher than atmospheric pressure. Unfortunately, most patients cannot be offered HBOT because it is costly and needs to be applied at specialised centres. Therefore, topical continuous oxygen therapy (TCOT) is a novel alternative for continuous local oxygen delivery to wounds and is associated with improved wound healing; however, its effect on painful wounds is unknown. This retrospective study was conducted on 20 patients, of whom 17 had painful hard-to-heal leg ulcers. In 13 patients (76%) with painful ulcers, TCOT was associated with rapid and substantial pain alleviation. Also, eight (40%) of the patients' wounds healed entirely with TCOT. This study suggests that TCOT may represent a novel pain management device for hard-to-heal wounds.

Mapping O-glycosylation Sites Using OpeRATOR and LC-MS.

O-glycosylation is a difficult posttranslational modification to analyze. O-glycans are labile and often cluster making their analysis by LC-MS very challenging. OpeRATOR is an O-glycan specific protease that cleaves the protein backbone N-terminally of glycosylated serine and threonine residues. This enables the generation of glycopeptides of suitable size for mapping O-glycosylation sites in detail by bottom-up LC-MS analysis. In this chapter we demonstrate a simple workflow for in-depth analysis of O-glycosylation sites on heavily glycosylated proteins using OpeRATOR digestion and HILIC-MS/MS analysis.

Topical oxygen treatment relieves pain from hard-to-heal leg ulcers and improves healing: a case report.

Pain from hard-to-heal wounds is common and challenging to manage with current therapies. Most hard-to-heal wounds show some degree of hypoxia that impairs healing and contributes to pain. Regular oxygen therapy is given in hyperbaric oxygen chambers and is costly, time-consuming and cannot be offered to most patients. Moreover, hyperbaric oxygen therapy (HBOT) only increases tissue oxygen for a short time and is given only for a few hours per week. Topical oxygen therapy (TOT) was introduced as an alternative and in this report we focus on topical continuous oxygen therapy (TCOT), which has been shown to be associated with healing of hard-to-heal ulcers. We report on a patient with type 1 diabetes with a painful hard-to-heal lower leg ulcer that failed to heal with standard wound dressings and that had insufficient response to pharmacological analgesia. The patient was on three different analgesics before treating the wound with TCOT. As the wound was considered hypoxic, due to longstanding diabetes and probable microangiopathy, TCOT was commenced. Within one week of treatment starting, the patient spontaneously ceased all his analgesics as he was free of pain; and after 2.5 months, the ulcer healed. The patient reported no adverse effects. In addition to promoting healing, TCOT may also be considered for its potential analgesic effects in hard-to-heal wound management.

EndoS and EndoS2 hydrolyze Fc-glycans on therapeutic antibodies with different glycoform selectivity and can be used for rapid quantification of high-mannose glycans.

Enzymes that affect glycoproteins of the human immune system, and thereby modulate defense responses, are abundant among bacterial pathogens. Two endoglycosidases from the human pathogen Streptococcus pyogenes, EndoS and EndoS2, have recently been shown to hydrolyze N-linked glycans of human immunoglobulin G. However, detailed characterization and comparison of the hydrolyzing activities have not been performed. In the present study, we set out to characterize the enzymes by comparing the activities of EndoS and EndoS2 on a selection of therapeutic monoclonal antibodies (mAbs), cetuximab, adalimumab, panitumumab and denosumab. By analyzing the glycans hydrolyzed by EndoS and EndoS2 from the antibodies using matrix-assisted laser desorption ionization time of flight, we found that both the enzymes cleaved complex glycans and that EndoS2 hydrolyzed hybrid and oligomannose structures to a greater extent compared with EndoS. A comparison of ultra-high-performance liquid chromatography (LC) profiles of the glycan pool of cetuximab hydrolyzed with EndoS and EndoS2 showed that EndoS2 hydrolyzed hybrid and oligomannose glycans, whereas these peaks were missing in the EndoS chromatogram. We utilized this difference in glycoform selectivity, in combination with the IdeS protease, and developed a LC separation method to quantify high mannose content in the Fc fragments of the selected mAbs. We conclude that EndoS and EndoS2 hydrolyze different glycoforms from the Fc-glycosylation site on therapeutic mAbs and that this can be used for rapid quantification of high mannose content.