Consent and parental responsibility - the past, the present and the future

Introduction: Informed consent is the 'permission or agreement' given by the patient for a proposed action. This paper explores the clinician's role in obtaining informed consent, provides an overview of consent and parental responsibility in the UK, and presents practical adjuncts to aid dental professionals in ascertaining who has parental responsibility to delineate persons capable of providing assent on behalf of an underage patient. / Consent and parental responsibility: While the principles of consent have largely stayed constant with time, subtleties in parental responsibility legislation exist in different regions of the UK. An audit exploring consent and parental responsibility knowledge among clinicians within the orthodontic department at the UCLH Eastman Dental Hospital demonstrated that none of the respondents met the gold standard (100%). The results ranged from 59-89% with a mean score of 74%. The majority of questions answered incorrectly related to knowledge of parental responsibility. / Conclusion: It is the responsibility of clinicians providing any care within the UK to stay up to date with legislation and regulations regarding consent and parental responsibility. Knowledge-based questionnaires can highlight areas of knowledge deficit which can be addressed through continuous professional development. This paper provides a flowchart summarising parental responsibility and a prefilled parental responsibility questionnaire as adjuncts to simplify the process of dental professionals ascertaining parental responsibility

Mechanical and surface chemical analysis of retrieved breast implants from a single centre

INTRODUCTION: Breast implants are associated with complications such as capsular contracture, implant rupture and leakage often necessitating further corrective surgery. Re-operation rates have been reported to occur in up to 15.4% of primary augmentation patients and up to 27% in primary reconstructions patients within the first three years (Cunningham, 2007). The aim of this study was to examine the mechanical and surface chemical properties as well as the fibroblast response of retrieved breast implants in our unit to determine the in vivo changes which occur over time. METHODS: Ethical approval was obtained. 47 implants were retrieved. Implantation time ranged from 1 month to 388 months (Mean 106.1 months). Tensile strength, elongation, Young's modulus and tear strength properties were measured using Instron 5565 tensiometer on anterior and posterior aspects of the implant. Attenuated total reflectance-fourier transform infra-red spectroscopy (ATR-FTIR), wettability and scanning electron microscopy (SEM) analysis was performed on the shell surfaces. Bicinchoninic acid assay was performed to determine shell protein content. The fibroblast response was determined by seeding HDFa cells on the retrieved implants and cell metabolism measured using Alamar Blue™ assay. RESULTS: Mechanical properties fall with increasing duration of implantation. There were no significant changes in ATR-FTIR spectra between ruptured and intact implants nor significant changes in wettability in implants grouped into 5 year categories. SEM imaging reveals surface degradation changes with increasing duration of implantation. CONCLUSIONS: With increasing duration of implantation, mechanical properties of the breast implants fall. However this was not associated with surface chemical changes as determined by ATR-FTIR and wettability nor protein content of the shells. Thus the reduction in mechanical properties is associated with breast implant failure but further research is required to elucidate the mechanisms

Determining the outcomes of post-mastectomy radiation therapy delivered to the definitive implant in patients undergoing one- and two-stage implant-based breast reconstruction: A systematic review and meta-analysis

BACKGROUND: Post-mastectomy radiation therapy (PMRT) is known to increase the complication rate and implant loss in implant-based breast reconstruction. The purpose of this study was to systematically review the literature regarding the outcome of PMRT delivered to the permanent/definitive implant. METHODS: Systematic review and meta-analysis of studies involving immediate implant-based reconstruction and PMRT when delivered to the permanent implant. RESULTS: Seven studies included 2921 patients (520 PMRT, 2401 control). PMRT was associated with significant increase in capsular contracture (7 studies, 2529 patients, 494 PMRT, 2035 control, OR 10.21, 95% CI 3.74 to 27.89, p < 0.00001). In addition, PMRT was associated with a significant increase in revisional surgery (7 studies, 2921 patients, 520 PMRT, 2401 control, OR 2.18, 95% CI 1.33 to 3.57, p = 0.002) and reconstructive failure (6 studies, 2814 patients, 496 PMRT, 2318 control, OR 2.52, 95% CI 1.48 to 4.29, p+0.0007). Moreover, it was associated with a significant reduction in patient satisfaction (4 studies, 468 patients, 138 PMRT, 294 control, OR 0.29, 95% CI 0.15 to 0.57, p = 0.0003) and cosmetic outcome (4 studies, 1317 patients, 238 PMRT, 1009 control, OR 28, 95% CI. 0.11 to 0.67, p = 0.005). CONCLUSIONS: This meta-analysis demonstrates that within the first 5 years, post implant-based reconstruction for those patients who receive PMRT, the rates of adverse events are increased, and there is a significant reduction in patient satisfaction and cosmetic outcome

Multiscale Mechano-Biological Finite Element Modelling of Oncoplastic Breast Surgery-Numerical Study towards Surgical Planning and Cosmetic Outcome Prediction

Surgical treatment for early-stage breast carcinoma primarily necessitates breast conserving therapy (BCT), where the tumour is removed while preserving the breast shape. To date, there have been very few attempts to develop accurate and efficient computational tools that could be used in the clinical environment for pre-operative planning and oncoplastic breast surgery assessment. Moreover, from the breast cancer research perspective, there has been very little effort to model complex mechano-biological processes involved in wound healing. We address this by providing an integrated numerical framework that can simulate the therapeutic effects of BCT over the extended period of treatment and recovery. A validated, three-dimensional, multiscale finite element procedure that simulates breast tissue deformations and physiological wound healing is presented. In the proposed methodology, a partitioned, continuum-based mathematical model for tissue recovery and angiogenesis, and breast tissue deformation is considered. The effectiveness and accuracy of the proposed numerical scheme is illustrated through patient-specific representative examples. Wound repair and contraction numerical analyses of real MRI-derived breast geometries are investigated, and the final predictions of the breast shape are validated against post-operative follow-up optical surface scans from four patients. Mean (standard deviation) breast surface distance errors in millimetres of 3.1 (±3.1), 3.2 (±2.4), 2.8 (±2.7) and 4.1 (±3.3) were obtained, demonstrating the ability of the surgical simulation tool to predict, pre-operatively, the outcome of BCT to clinically useful accuracy

Tribological behaviour of AZ31 magnesium alloy reinforced by bimodal size B4C after precipitation hardening

This study investigated dry sliding wear properties of AZ31 magnesium alloy and B4C-reinforced AZ31 composites containing 5, 10, and 20 wt.% B4C with bimodal sizes under different loadings (10–80 N) at various sliding speeds (0.1–1 m/s) via the pin-on-disc configuration. Microhardness evaluations showed that when the distribution of B4C particles was uniform the hardness of the composites increased by enhancing the reinforcement content. The unreinforced alloy and the composite samples were examined to determine the wear mechanism maps and identify the dominant wear mechanisms in each wear condition and reinforcement content. For this purpose, wear rates and friction coefficients were recorded during the wear tests and worn surfaces were characterized by scanning electron microscopy and energy dispersive X-ray spectrometry analyses. The determined wear mechanisms were abrasion, oxidation, delamination, adhesion, and plastic deformation as a result of thermal softening and melting. The wear evaluations revealed that the composites containing 5 and 10 wt.% B4C had a significantly higher wear resistance in all the conditions. However, 20 wt.% B4C/AZ31 composite had a lower resistance at high sliding speeds (0.5–1 m/s) and high loadings (40–80 N) in comparison with the unreinforced alloy. The highest wear resistance was obtained at high sliding speeds and low loadings with the domination of oxidative wear