Assessment of PULP score in predicting 30-day perforated duodenal ulcer morbidity, and comparison of its performance with Boey and ASA, a retrospective study

Background: /aim: Scores commonly employed to risk stratify perforated peptic ulcer patients include ASA (American Society of Anesthesiologists), Boey and peptic ulcer perforation score (PULP). However, few studies assessed and compared the accuracy indices of these three scores in predicting post PPU repair 30-day morbidity. We assessed accuracy indices of PULP, and compared them to Boey and ASA in predicting post perforated duodenal (PDU) ulcer repair 30-day morbidity. Methods: Retrospective chart review of all PDU patients (perforated duodenal ulcers only) at the largest two hospitals in Qatar (N = 152). Data included demographic, clinical, laboratory, operative, and post repair 30-day morbidity. Area under the Curve (AUC), sensitivity and specificity were computed for each of the 3 scores. Multivariate logistic regression assessed the accuracy indices of each score. Results: All patients were males (M age 37.41 years). Post PDU repair 30-day morbidity was 10.5% (16 morbidities). Older age, higher ASA (?3), Boey (?1) or PULP (?8) scores, shock on admission and preoperative comorbidities; and conversely, lower hemoglobin and albumin were all positively significantly associated with higher post PDU 30-day morbidity. PULP displayed the largest AUC (72%), and was the only score to significantly predict 30-day morbidity. The current study is the first to report the sensitivity and specificity of these three scores for post PDU repair 30-day morbidity; and first to assess accuracy indices for PULP in predicting post PDU repair 30-day morbidity. Conclusion: PULP score had the largest AUC and was the only score to significantly predict post PDU repair 30-day morbidity.Scopu

Development of nitric oxide releasing visible light crosslinked gelatin methacrylate hydrogel for rapid closure of diabetic wounds

Management of non-healing and slow to heal diabetic wounds is a major concern in healthcare across the world. Numerous techniques have been investigated to solve the issue of delayed wound healing, though, mostly unable to promote complete healing of diabetic wounds due to the lack of proper cell proliferation, poor cell-cell communication, and higher chances of wound infections. These challenges can be minimized by using hydrogel based wound healing patches loaded with bioactive agents. Gelatin methacrylate (GelMA) has been proven to be a highly cell friendly, cell adhesive, and inexpensive biopolymer for various tissue engineering and wound healing applications. In this study, S-Nitroso-N-acetylpenicillamine (SNAP), a nitric oxide (NO) donor, was incorporated in a highly porous GelMA hydrogel patch to improve cell proliferation, facilitate rapid cell migration, and enhance diabetic wound healing. We adopted a visible light crosslinking method to fabricate this highly porous biodegradable but relatively stable patch. Developed patches were characterized for morphology, NO release, cell proliferation and migration, and diabetic wound healing in a rat model. The obtained results indicate that SNAP loaded visible light crosslinked GelMA hydrogel patches can be highly effective in promoting diabetic wound healing.Scopu

Growth factor loaded in situ photocrosslinkable poly(3-hydroxybutyrate-co-3-hydroxyvalerate)/gelatin methacryloyl hybrid patch for diabetic wound healing

Management of chronic diabetic ulcers remains as a major challenge in healthcare which requires extensive multidisciplinary approaches to ensure wound protection, management of excess wound exudates and promoting healing. Developing wound healing patches that can act as a protective barrier and support healing is highly needed to manage chronic diabetic ulcers. In order to boost the wound healing potential of patch material, bioactive agents such as growth factors can be used. Porous membranes made of nanofibers generated using electrospinning have potential for application as wound coverage matrices. However, electrospun membranes produced from several biodegradable polymers are hydrophobic and cannot manage the excess exudates produced by chronic wounds. Gelatin-methacryloyl (GelMA) hydrogels absorb excess exudates and provide an optimal biological environment for the healing wound. Epidermal growth factor (EGF) promotes cell migration, angiogenesis and overall wound healing. Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) membranes provide microbial, thermal and mechanical barrier properties to the wound healing patch. Herein, we developed a biodegradable polymeric patch based on the combination of mechanically stable electrospun PHBV, GelMA hydrogel and EGF for promoting diabetic wound healing. In vitro and in vivo studies were carried out to evaluate the effect of developed patches on cell proliferation, cell migration, angiogenesis and wound healing. Our results showed that EGF loaded patches can promote the migration and proliferation of multiple types of cells (keratinocytes, fibroblasts and endothelial cells) and enhance angiogenesis. In situ development of the patch and subsequent in vivo wound healing study in diabetic rats showed that EGF loaded patches provide rapid healing compared to control wounds. Interestingly, 100 ng EGF per cm2 of the patches was enough to provide favourable cellular response, angiogenesis and rapid diabetic wound healing. Overall results indicate that EGF loaded PHBV-GelMA hybrid patch could be a promising approach to promote diabetic wound healing.Scopu