In contrast, for particle-based embolic agents such as poly-dl-lactide microparticles and CalliSpheres® beads, their embolization endpoints were mainly determined by the particle size, whereas the particle densities close to the endpoints dramatically dropped down, which with the penetration depth represented two critical factors determining the embolic distribution. Such a decellularized organ model may open a new route to visually and quantitatively characterize embolization effects of various embolotherapies. This study aimed to evaluate in vivo the effect of laser photobiomodulation associated with a repair cement (MTA Repair HP™) on the process of bone repair in the femur of rats, through histological and histomorphometric assays. Forty Wistar albino rats were randomly divided into four groups, with two periods of euthanasia - 15 and 21 days (n = 5 per period). Under general anesthesia, a bone defect was made in the left femur of each animal. In the LS (Laser) group, the defect was irradiated following the parameters λ = 808 nm, P = 100 mW, ED = 80 J/cm2 per point, 22 s per point, E = 2.2 J per point. In the LM (MTA Repair HP™ + Laser) group, the defect was filled with MTA Repair HP™ and irradiated with laser in the same protocol of the LS group. In the MH (MTA Repair HP™) group, the defect was filled with MTA Repair HP™ without irradiation. In the CTR (Control) group, the bone defect received no treatment. At 15 days, the mean index of bone neoformation in the defect area was significantly lower in the CTR group as compared to the MH, LS, and LM groups. At 21 days, the LM group presented significantly greater bone neoformation than the MH group, without significant difference between LS and LM. Laser photobiomodulation therapy is promising as an adjuvant in the bone repair process, especially when associated with the use of biomaterials. A melanin producer bacteria Halomonas venusta was isolated from a marine sponge Callyspongia sp. and optimized for melanin production. The optimized fermented media supplemented with 1% tyrosine yielded 4.92 mg/ml of melanin. The melanin incorporated cream was formulated and fortified with concentrates of seaweed Gelidium spinosum. Melanin and seaweed concentrate were found to be rich in antioxidant activity and were effectively inhibited the growth of S. aureus (MTCC 96) and S. selleck pyogenes (MTCC 442). Various combinations of the cream were optimized and selected a formula containing 0.25% of melanin and 0.75% of seaweed concentrate which showed improved texture quality of cream. The formulated cream showed a pH of 5.52, spreadability 23 mm, and smooth and homogeneous texture. On application over skin provides a cooling effect and immediate disappearance without formation of white or oily film. Texture analysis of newly formulated cream showed similar results with that of control cream in terms of firmness, cohesiveness, index of viscosity and consistency. The formulated cream showed significant reduction of reactive oxygen species generated on exposure to direct sunlight. The cream showed protective effect on photohemolysis thus protecting the skin from lysis of red blood cells. The sun protection factor of the formulated cream F3 was found to be 18.373 ± 1.45. The combined antimicrobial and antioxidant effect of melanin and seaweed concentrate increased the shelf life of cream over the control. This study was the first report on photoprotective cream formulation using melanin and seaweed concentrate, which improved antioxidant and wound healing properties. The antimicrobial effect of the formulated natural cream could reduce the emergence of drug resistant bacteria and side effects of synthetic creams. In the second half of the 20th century, asbestos extraction was up to 4 Mt/year. Due to its high strength and insulation properties, this mineral was used as an additive in building materials. Over time these materials were destroyed by the process of weathering and leaching. Asbestos fibers in dust form penetrate the respiratory system causing diseases. This article proposes the binding of hazardous asbestos fibers in a polymer matrix formed from waste cooking oil. Compact materials were produced by heating catalyzed waste cooking oil and asbestos waste, and the process of obtaining these materials was optimized and their physicochemical and strength properties were determined. Oil-asbestos blocks contained sulfuric acid in a mass ratio of 0.05-0.30, being the mass of waste cooking oil, invariable mass of filling and 20% of waste cooking oil to the mass of the whole mixture. The materials were characterized by a compact structure and high hardness. The best mechanical strength above 140 N/mm was obtained for blocks with low acid to oil mass ratio ranging from 0.05 to 0.1125. Porous carbons from digestate-derived hydrochar were produced, characterized and their performance to reclaim phosphate from water was evaluated as a preliminary approach to demonstrate their practical application. In a first step, the digestate was converted into hydrochars through hydrothermal carbonization by using two different pH conditions 8.3 (native conditions) and 3.0 (addition of H2SO4). The resulting hydrochars did not present significant differences. Consecutively, the hydrochars were activated with KOH to produce activated carbons with enhanced textural properties. The resulting porous carbons presented marked differences the AC native presented a lower ash content (20.3 wt%) and a higher surface area (SBET = 1106 m2/g) when compared with the AC-H2SO4 (ash content = 43.7 wt% SBET = 503 m2/g). Phosphorus, as phosphate, is a resource present in significative amount in wastewater, causing serious problems of eutrophication. Therefore, the performance of the porous carbons samples to recover phosphate - P(PO43-) - from water was evaluated through exploitation assays that included kinetic studies. The lumped model presented a good fitting to the kinetic data and the obtained uptake capacities were the same for both carbons, 12 mg P(PO43-)/g carbon. Despite the poorer textural properties of AC-H2SO4, this carbon was richer in Ca, Al, Fe, K, and Mg cations which promoted the formation of mineral complexes with phosphate anions. The results obtained in this work are promising for the future development of P(PO43-) enriched carbons that can be used thereafter as biofertilizers in soil amendment applications.