Health professionals and students encounter multi-level barriers to implementing high-value osteoarthritis care: a multi-national study.

OBJECTIVE: Consistent evidence-practice gaps in osteoarthritis (OA) care are observed in primary care settings globally. Building workforce capacity to deliver high-value care requires a contemporary understanding of barriers to care delivery. We aimed to explore barriers to OA care delivery among clinicians and students. DESIGN: A cross-sectional, multinational study sampling clinicians (physiotherapists, primary care nurses, general practitioners (GPs), GP registrars; total possible denominator: n = 119,735) and final-year physiotherapy and medical students (denominator: n = 2,215) across Australia, New Zealand and Canada. Respondents answered a survey, aligned to contemporary implementation science domains, which measured barriers to OA care using categorical and free-text responses. RESULTS: 1886 clinicians and 1611 students responded. Items within the domains 'health system' and 'patient-related factors' represented the most applicable barriers experienced by clinicians (25-42% and 20-36%, respectively), whereas for students, 'knowledge and skills' and 'patient-related factors' (16-24% and 19-28%, respectively) were the most applicable domains. Meta-synthesis of qualitative data highlighted skills gaps in specific components of OA care (tailoring exercise, nutritional/overweight management and supporting positive behaviour change); assessment, measurement and monitoring; tailoring care; managing case complexity; and translating knowledge to practice (especially among students). Other barriers included general infrastructure limitations (particularly related to community facilities); patient-related factors (e.g., beliefs and compliance); workforce-related factors such as inconsistent care and a general knowledge gap in high-value care; and system and service-level factors relating to financing and time pressures, respectively. CONCLUSIONS: Clinicians and students encounter barriers to delivery of high-value OA care in clinical practice/training (micro-level); within service environments (meso-level); and within the health system (macro-level).

Loss of chromosome 14 increases the radiosensitivity of CGL1 human hybrid cells but lowers their susceptibility to radiation-induced neoplastic transformation.

Loss of active tumor suppressor alleles on fibroblast chromosomes 11 and 14 are involved in radiation-induced neoplastic transformation of human hybrid CGL1 cells. Loss of either chromosome 11 or 14 alone is not sufficient for neoplastic transformation. To gain insight into the potential functions of these tumor suppressor loci, we have investigated the effects of chromosome 11 or 14 loss on radiation-induced neoplastic transformation. We recently demonstrated that loss of chromosome 11 increases the susceptibility to X-ray induced cell killing, neoplastic transformation and the expression of delayed death. The data suggested that one possible function of the chromosome 11 tumor suppressor gene may be to help maintain genome stability after radiation damage. We postulated that if the chromosome 14 allele is functioning in a similar manner, then the loss of chromosome 14 may also make the hybrid cells more susceptible to radiation-induced cell killing and neoplastic transformation. A hybrid cell line which has lost one copy of chromosome 14 was isolated and designated CON3(-14). CON3(-14) cells were more sensitive to X-ray-induced cell killing when compared with parental CGL1 cells. However, the susceptibility to radiation-induced neoplastic transformation was significantly reduced (by a factor of two) compared with the parental CGL1 cells. The expression of delayed death in the progeny of the irradiated CON3(-14) cells, growing in transformation flasks, was similar to CGL1 cells during the 21 day assay period. Taken together, the data indicate that loss of chromosome 14 alone increased the X-ray sensitivity of the hybrid cells but reduced their susceptibility to radiation-induced neoplastic transformation. These data suggest that the tumor suppressor alleles on chromosomes 11 and 14 may be functionally distinct in terms of their regulation of genomic instability and neoplastic transformation after radiation exposure.

Previous loss of chromosome 11 containing a suppressor locus increases radiosensitivity, neoplastic transformation frequency and delayed death in HeLa x fibroblast human hybrid cells.

CGL1 (HeLa x fibroblast) hybrid cells have been utilized to study mechanisms of radiation-induced neoplastic transformation of human cells in vitro. Previous analysis has shown that loss of active tumor suppressor alleles on fibroblast chromosomes 11 and 14 may be required for radiation-induced neoplastic transformation of CGL1 cells. Loss of chromosome 11 alone was, therefore, found to be necessary but not sufficient for neoplastic transformation. We postulated that the loss of chromosome 11 may make the hybrid cells more susceptible to radiation-induced neoplastic transformation, since these cells have already undergone one of the required tumor suppressor loss events. Hybrid cells which have lost one copy of chromosome 11 were designated CON104(-11). CON104(-11) hybrid cells were found to have increased X-ray sensitivity and susceptibility to radiation-induced neoplastic transformation when compared with the parental CGL1 cells. In addition, the neoplastically transformed foci appear to arise earlier after radiation exposure in CON104(-11) versus CGL1 cells. Furthermore, the plating efficiency (PE) of the progeny of the irradiated CON104(-11) cells, growing in transformation flasks, is persistently lower than parental CGL1 cells during the 21 day assay period. The lower PE of the progeny of irradiated cells was attributed to the expression of delayed death/lethal mutations post-irradiation, a reflection of genomic instability. Taken together, the data indicate that previous loss of chromosome 11 may increase the radiation-induced genomic instability of the hybrid cells, leading to increased radiation sensitivity and neoplastic transformation potential. The data suggest that one possible function of the chromosome 11 tumor suppressor gene may be to help maintain genome stability after radiation damage.

Delayed apoptotic responses associated with radiation-induced neoplastic transformation of human hybrid cells.

HeLa X human skin fibroblast hybrid cells have been developed into a model for radiation-induced neoplastic transformation of human cells. Previous studies indicate that the appearance of neoplastically transformed foci in this system is delayed for several population doublings after irradiation and appears to involve the loss of putative tumor suppressor loci on fibroblast chromosomes 11 and 14. We now show that after treatment with 7 Gy of X-rays, transformed foci initiation correlates with delayed apoptosis initiated in the progeny of the irradiated cells after 10-12 cell divisions and with reduced plating efficiency (delayed death). The cells develop classic apoptotic morphology, positive terminal deoxynucleotidyl transferase-mediated nick end labeling and phosphatidylserine (annexin V) staining, and cleavage of poly(ADP-ribose) polymerase. In addition, a delayed induction of the p53 protein and the proapoptotic Bax protein is evident over a week after radiation exposure. We propose that a delayed build-up of mitosis-dependent genomic DNA damage or a loss of genetic material over time (10-12 cell divisions postirradiation) has two relevant outcomes: (a) cell death due to the delayed induction of a p53-dependent apoptosis; and (b) neoplastic transformation of a minor subset of survivors that has lost fibroblast chromosomes 11 and 14 (tumor suppressor loci for this system) and has either evaded apoptosis or not acquired enough genetic damage to induce apoptosis. It is postulated that both phenomena result from X-ray-induced, translesion-mediated genomic instability.

Loss of suppressor loci on chromosomes 11 and 14 may be required for radiation-induced neoplastic transformation of HeLa x skin fibroblast human cell hybrids.

We have previously reported a linkage between radiation-induced damage to a putative tumor suppressor locus on fibroblast chromosome 11 and the re-expression of tumorigenicity in a hybrid cell line (HeLa x human skin fibroblast) used to study neoplastic transformation. Further investigation into the molecular basis of radiation-induced neoplastic transformation of the hybrid cell, CGL1, indicates that loss of fibroblast chromosome 11 appears to be necessary but not sufficient for neoplastic transformation. Previous analysis had suggested, though not clearly demonstrated, a possible role for loss of alleles on fibroblast chromosome 14 in the neoplastic transformation of the hybrid cells. Therefore, the status of chromosome 14 in the gamma-ray-induced, neoplastically transformed (GIM) hybrid cell lines and in nontumorigenic control (CON) hybrid cell lines isolated from irradiated populations has been investigated. Chromosome painting and molecular studies using restriction fragment length polymorphisms and tetranucleotide repeat polymorphism analysis were performed. As an additional control, the status of chromosome 12 was also examined. We report that five of the eight GIM cell lines have lost one complete copy of a fibroblast chromosome 14 while only one of the five CON cell lines has lost a complete copy of a fibroblast chromosome 14. No evidence of large-scale loss of chromosome 12 was detected in the GIM or CON cells. The data further suggest that both copies of fibroblast chromosome 14 contain an active tumor suppressor locus and that radiation-induced loss of either fibroblast chromosome 14 is associated with neoplastic transformation in this system. We now conclude that loss of alleles on both fibroblast chromosome 11 and 14 may be required for the radiation-induced neoplastic transformation of these human hybrid cells.

In vitro cytotoxicity of silver-impregnated collagen cuffs designed to decrease infection in tunneled catheters.

PURPOSE: To examine in vitro the effects of silver-impregnated collagen cuff material from central venous catheters on human fibroblast growth. MATERIALS AND METHODS: In culture flasks, hybrid cells were exposed to silver-impregnated collagen cuff material, and human fibroblasts were exposed to silver-impregnated or silver-free collagen cuff material. After 72 hours of growth, cells were stained and digitally imaged, and the relative areas of cytotoxicity were determined. RESULTS: Flasks containing the silver-impregnated collagen cuff material and hybrid cells or human fibroblasts showed a marked local cytotoxic effect of the cuff material; cell-free zones surrounding the cuff material were demonstrated. No cytotoxic effect was seen in the flasks that contained silver-free cuff material (control group). Mean area of cleared cells was 312 mm2 +/- 130 (range, 156-624 mm2) in the flasks containing human fibroblasts and silver-impregnated cuff material and 0 mm2 in the corresponding control flasks (P < .0001). Mean radius of the area of cleared cells around the silver-impregnated cuff material in the flasks containing human fibroblasts was 9.8 mm +/- 2.0 (range, 7.0-14.1 mm). CONCLUSION: Silver-impregnated collagen cuff material demonstrates a local cytotoxicity on hybrid cells and human fibroblasts in vitro. This finding may explain the phenomena seen clinically of decreased anchorage and inadvertent removal of catheters with silver-impregnated collagen cuffs.