Evaluation of Adult Patients Readmitted for Severe Sepsis/Septic Shock Under the BPCI Advanced Program.

Bundled Payments for Care Improvement-Advanced Program (BPCI-A) is designed to pay a single payment covering services provided during an episode of care. Sepsis is associated with increased readmissions, mortality, and health care costs. The purpose of the study was to evaluate the BPCI program patients with sepsis who were readmitted within 90 days versus not readmitted. This was a retrospective cohort study including 271 (110 readmitted) patients enrolled in the BPCI program with Diagnostic-Related Grouping codes of septicemia or severe sepsis. Skin/soft tissue infection was the most common infection. There was a significant difference between the groups for resource needs at discharge including wound care (25.45% versus 11.18%; P = 0.002) and physical therapy (74.55% versus 57.14%; P = 0.004). Mortality was higher among readmissions, 43.64% versus 26.71% no readmission ( P = 0.004). Identifying risk factors for readmission, providing appropriate resources, and follow-up may contribute to improved patient outcomes for patients with sepsis enrolled in the BPCI program.

Acellular polycaprolactone scaffolds laden with fibroblast/endothelial cell-derived extracellular matrix for bone regeneration.

Inconsistencies in graft osteoconduction and osteoinduction present a clinical challenge in regeneration of large bone defects. Deposition of decellularized extracellular matrix (dECM) on tissue engineered scaffolds offers an alternative approach that can enhance these properties by mimicking bone's molecular complexity and direct infiltrating cells to repair damaged bone. However, dECMs derived from homogenous cell populations do not adequately simulate the heterogeneous and vascularized microenvironment of the bone. In this study, successive culture and decellularization of fibroblasts and endothelial cells (ECs) grown on polycaprolactone microfibers was used to develop a bioactive scaffold with heterogeneous dECM mimicking endothelial basement membrane. These scaffolds had greater amount of protein and minimally increased nucleic acid content than scaffolds with homogenous culture dECM. Coomassie Blue and antibody staining revealed extensive tube formation by ECs on fibroblast dECM. Fibroblast/endothelial dECM significantly enhanced osteoblast attachment, alkaline phosphatase activity, and osteocalcin- and osteopontin-positive extracellular mineral deposits. We demonstrated that the osteoconduction of dECMs can be tailored with the appropriate combination of cells to accelerate osteoblast mineral secretion. The overall concept can be expanded to generate increasingly more complex tissue constructs for regeneration of bone defects and other vascularized tissues.