Quality of Life and Pain Experienced by Children and Adolescents With Cancer at Home Following Discharge From the Hospital.

An exploratory study was conducted to examine the quality of life and pain experienced by patients with pediatric cancer at home after discharge. Physical, cognitive, social, and emotional aspects of quality of life were measured and how these may be affected by age, sex, diagnosis, and pain status. The authors also characterized intensity, location, and quality of pain experienced. A sample of 33 patients participating in a larger study was selected on the basis of having pain on the day of discharge and having completed the Pediatric Quality of Life Inventory Generic, Cancer Module, Multidimensional Fatigue Scale, and the Adolescent Pediatric Pain Tool at home. Cancer diagnoses were leukemias/lymphomas (42.4%), brain/central nervous system tumors (27.3%), sarcomas (24.2%), or other (6.1%). More than half of patients reported pain (n=17; 51.5%). Patients with pain had more fatigue affecting the quality of life (P=0.01), and lower physical and emotional functioning, leading to lower overall health-related quality of life scores (P=0.011). Female individuals and adolescents reported worse emotional functioning (P=0.02 and P=0.05, respectively). Physical, cognitive, and social functioning were lowest among patients diagnosed with sarcomas (P=0.00, P=0.01, and P=0.04, respectively). It is important to understand the symptom experience of patients at home as a first step in moving towards optimal discharge teaching and treatment.

Nanostructure-Enabled and Macromolecule-Grafted Surfaces for Biomedical Applications.

Advances in nanotechnology and nanomaterials have enabled the development of functional biomaterials with surface properties that reduce the rate of the device rejection in injectable and implantable biomaterials. In addition, the surface of biomaterials can be functionalized with macromolecules for stimuli-responsive purposes to improve the efficacy and effectiveness in drug release applications. Furthermore, macromolecule-grafted surfaces exhibit a hierarchical nanostructure that mimics nanotextured surfaces for the promotion of cellular responses in tissue engineering. Owing to these unique properties, this review focuses on the grafting of macromolecules on the surfaces of various biomaterials (e.g., films, fibers, hydrogels, and etc.) to create nanostructure-enabled and macromolecule-grafted surfaces for biomedical applications, such as thrombosis prevention and wound healing. The macromolecule-modified surfaces can be treated as a functional device that either passively inhibits adverse effects from injectable and implantable devices or actively delivers biological agents that are locally based on proper stimulation. In this review, several methods are discussed to enable the surface of biomaterials to be used for further grafting of macromolecules. In addition, we review surface-modified films (coatings) and fibers with respect to several biomedical applications. Our review provides a scientific update on the current achievements and future trends of nanostructure-enabled and macromolecule-grafted surfaces in biomedical applications.