Characterization of a Biochemical Mouse Model of Primary Aldosteronism for Thermal Therapies.

Introduction: Aldosterone-producing adenoma (APA) is the most common cause of endocrine-related hypertension but surgery is not always feasible. Current medical interventions are associated with significant side effects and poor patient compliance. New APA animal models that replicate basic characteristics of APA and give physical and biochemical feedback are needed to test new non-surgical treatment methods, such as image-guided thermal ablation. Methods: A model of APA was developed in nude mice using HAC15 cells, a human adrenal carcinoma cell line. Tumor growth, aldosterone production, and sensitivity to angiotensin II were characterized in the model. The utility of the model was validated via treatment with microwave ablation and characterization of the resulting physical and biochemical changes in the tumor. Results: The APA model showed rapid and relatively homogeneous growth. The tumors produced aldosterone and steroid precursors in response to angiotensin II challenge, and plasma aldosterone levels were significantly higher in tumor bearing mice two hours after challenge verses non-tumor bearing mice. The model was useful for testing microwave ablation therapy, reducing aldosterone production by 80% in treated mice. Conclusion: The HAC15 model is a useful tumor model to study and develop localized treatment methods for APA.

Histology-validated electromagnetic characterization of ex-vivo ovine lung tissue for microwave-based medical applications.

Microwave thermal ablation is an established therapeutic technique for treating malignant tissue in various organs. Its success greatly depends on the knowledge of dielectric properties of the targeted tissue and on how they change during the treatment. Innovation in lung navigation has recently increased the clinical interest in the transbronchial microwave ablation treatment of lung cancer. However, lung tissue is not largely characterized, thus its dielectric properties investigation prior and post ablation is key. In this work, dielectric properties of ex-vivo ovine lung parenchyma untreated and ablated at 2.45 GHz were recorded in the 0.5-8 GHz frequency range. The measured dielectric properties were fitted to 2-pole Cole-Cole relaxation model and the obtained model parameters were compared. Based on observed changes in the model parameters, the physical changes of the tissue post-ablation were discussed and validated through histology analysis. Additionally, to investigate the link of achieved results with the rate of heating, another two sets of samples, originating from both ovine and porcine tissues, were heated with a microwave oven for different times and at different powers. Dielectric properties were measured in the same frequency range. It was found that lung tissue experiences a different behavior according to heating rates: its dielectric properties increase post-ablation while a decrease is found for low rates of heating. It is hypothesized, and validated by histology, that during ablation, although the tissue is losing water, the air cavities deform, lowering air content and increasing the resulting tissue properties.

Evaluation of human adipose-derived stromal cell behaviour following exposure to Tamoxifen.

BACKGROUND AND AIM: Adipose-derived stromal cells (ASCs) are a promising cell source for novel tissue engineering approaches to breast reconstruction following cancer resection. However there is limited knowledge on the effect of adjuvant therapies such as hormonal therapy on ASCs, which may affect their efficacy in regenerative strategies. The present study aims to investigate the effects of Tamoxifen and its metabolites Afimoxifene (4-Hydroxy-Tamoxifen) and Endoxifen (N-desmethyl-4-hydroxytamoxifen) on patient-derived ASC viability, apoptosis, adipogenic differentiation and angiogenic potential. METHODS: ASCs were isolated from fat harvested from female breast cancer patients undergoing breast reconstruction surgery or cosmetic procedures. Oestrogen receptor (ER α, ß) expression was analysed using immunofluorescence. ASCs were then treated with various concentrations of Afimoxifene, Endoxifen and Tamoxifen (combination), and the impact on ASC viability and apoptosis determined. ASCs were cultured in adipogenic-differentiation media with or without tamoxifen and derivatives, and adipogenesis was measured using quantitative Real-time Polymerase chain reaction (qRT-PCR) and histological staining (Oil Red O). The effect on secreted VEGF levels was also quantified in ASC conditioned media RESULTS: ASCs were successfully isolated and characterised from human abdominal lipoaspirates or fat tissues (n = 8). ASCs subjected to varying doses of Tamoxifen and metabolites (up to 1000 nM) showed no decline in cell viability or increase in apoptosis, at physiological doses (upto 100 nM). Functional decline in adipogenic differentiation or gene expression was observed at supraphysiological concentrations of Tamoxifen (1000 nM). VEGF165 protein secretion in ASC-cell conditioned media was not significantly impacted irrespective of dosage. CONCLUSION: At physiologically relevant doses, Tamoxifen treatment did not result in any deleterious effect on ASC survival and functionality and is unlikely to negatively impact ASC based breast reconstruction strategies for breast cancer patients receiving this adjuvant hormonal therapy.

Effect of Breast Cancer and Adjuvant Therapy on Adipose-Derived Stromal Cells: Implications for the Role of ADSCs in Regenerative Strategies for Breast Reconstruction.

Tissue engineering using Adipose Derived Stromal Cells (ADSCs) has emerged as a novel regenerative medicine approach to replace and reconstruct soft tissue damaged or lost as a result of disease process or therapeutic surgical resection. ADSCs are an attractive cell source for soft tissue regeneration due to the fact that they are easily accessible, multipotent, non-immunogenic and pro-angiogenic. ADSC based regenerative strategies have been successfully translated to the clinical setting for the treatment of Crohn's fistulae, musculoskeletal pathologies, wound healing, and cosmetic breast augmentation (fat grafting). ADSCs are particularly attractive as a source for adipose tissue engineering as they exhibit preferential differentiation to adipocytes and support maintenance of mature adipose graft volume. The potential for reconstruction with an autologous tissue sources and a natural appearance and texture is particularly appealing in the setting of breast cancer; up to 40% of patients require mastectomy for locoregional control and current approaches to post-mastectomy breast reconstruction (PMBR) are limited by the potential for complications at the donor and reconstruction sites. Despite their potential, the use of ADSCs in breast cancer patients is controversial due to concerns regarding oncological safety. These concerns relate to the regeneration of tissue at a site where a malignancy has been treated and the impact this may have on stimulating local disease recurrence or dissemination. Pre-clinical data suggest that ADSCs exhibit pro-oncogenic characteristics and are involved in stimulating progression, and growth of tumour cells. However, there have been conflicting reports on the oncologic outcome, in terms of locoregional recurrence, for breast cancer patients in whom ADSC enhanced fat grafting was utilised as an alternative to reconstruction for small volume defects. A further consideration which may impact the successful translation of ADSC based regenerative strategies for post cancer reconstruction is the potential effects of cancer therapy. This review aims to address the effect of malignant cells, adjuvant therapies and patient-specific factors that may influence the success of regenerative strategies using ADSCs for post cancer tissue regeneration.