RESUMEN
After liver transplantation (LTx), the most common cause of death in the long-term is de-novo malignancy (DNM). The aim is to review the gender differences in the standardized incidence ratio (SIR) of DNM within the same geographical locations. METHODS: Four studies were identified comparing post-LTx SIR between males and females. RESULTS: From 6663 males and 2780 females LTx recipients, the mean SIR from each of the four studies for males is 2.8, 2.0, 1.94, and 3.4, and 3.5, 1.3, 1.95, and 2.3 for females. On meta-analysis using a random effect model for each gender group. No significant difference was revealed after logarithmic transformation and subgroup meta-analysis. Overall mean SIR with 95% Confidence Interval (CI) for males is 2.53 (95% CI 1.65-3.88) and 2.3 (1.25-4.24) for females. lung malignancy, 1.97 (1.14-3.41) for males and 2.65 (0.67-10.47) for females. For colorectal malignancy, the combined SIR for males is 1.98 (0.58-6.78) and 1.85 (1.02-3.37) for females. The SIR for female gender-specific malignancies; SIR for breast is 1.1 ± 4.4, cervix 2.9 ± 1.9, uterus 2.8, and ovarian 0.7, and for males, testis 1.6 ± 1.3, prostate 1.2 ± 0.4. However, rare malignancies, male breast cancers (n = 1, SIR, 22.6), and Kaposi's sarcoma, in males (n = 6) and in females (n = 1), had SIR 120. and 212.7, respectively. CONCLUSION: Overall, there are no statistical differences between male and female DNM. Female-specific cervix, uterus, ovarian, and male-specific testis and prostate have similar SIR. Rare malignancies have very high SIR.
RESUMEN
Granular hydrogel scaffolds (GHS) are fabricated via placing hydrogel microparticles (HMP) in close contact (packing), followed by physical and/or chemical interparticle bond formation. Gelatin methacryloyl (GelMA) GHS have recently emerged as a promising platform for biomedical applications; however, little is known about how the packing of building blocks, physically crosslinked soft GelMA HMP, affects the physical (pore microarchitecture and mechanical/rheological properties) and biological (in vitro and in vivo) attributes of GHS. Here, the GHS pore microarchitecture is engineered via the external (centrifugal) force-induced packing and deformation of GelMA HMP to regulate GHS mechanical and rheological properties, as well as biological responses in vitro and in vivo. Increasing the magnitude and duration of centrifugal force increases the HMP deformation/packing, decreases GHS void fraction and median pore diameter, and increases GHS compressive and storage moduli. MDA-MB-231 human triple negative breast adenocarcinoma cells spread and flatten on the GelMA HMP surface in loosely packed GHS, whereas they adopt an elongated morphology in highly packed GHS as a result of spatial confinement. Via culturing untreated or blebbistatin-treated cells in GHS, the effect of non-muscle myosin II-driven contractility on cell morphology is shown. In vivo subcutaneous implantation in mice confirms a significantly higher endothelial, fibroblast, and macrophage cell infiltration within the GHS with a lower packing density, which is in accordance with the in vitro cell migration outcome. These results indicate that the packing state of GelMA GHS may enable the engineering of cell response in vitro and tissue response in vivo. This research is a fundamental step forward in standardizing and engineering GelMA GHS microarchitecture for tissue engineering and regeneration.