Development of Annexin A1-surface-functionalized metal-complex multi-wall lipid core nanocapsules and effectiveness on experimental colitis.

Annexin A1 (AnxA1), a 37KDa protein, is secreted by inflammatory and epithelial cells and displays anti-inflammatory and wound healing activities in intestinal bowel diseases. Herein, we aimed to functionalize recombinant AnxA1 (AnxA1) on multi-wall lipid core nanocapsules (MLNC) and investigate its effectiveness on experimental colitis. MLNC were prepared by covering lipid core nanocapsules (LNC) with chitosan, which coordinates metals to specific protein chemisorption sites. Therefore, MLNC were linked to Zn2+ and AnxA1 was added to form MLNC-AnxA1. LNC, MLNC and MLNC-AnxA1 presented average size of 129, 152 and 163 nm, respectively, and similar polydispersity indexes (0.xx); incorporation of chitosan inverted the negative potential zeta; the coordination efficiency of AnxA1 was 92.22 %, and transmission electron microscope photomicrograph showed MLNC-AnxA1 had a spherical shape. The effectiveness of MLNC-AnxA1 was measured in Dextran Sulfate Sodium (DSS)-induced colitis in male C57BL/6 mice. DSS (2 % solution) was administered from days 1-6; saline, LNC, MLNC, MLNC-AnxA1 or AnxA1 were administered, once a day, by oral or intraperitoneal (i.p.) routes, from days 6-9. Clinical parameters of the disease were measured from day 0-10 and gut tissues were collected for histopathology, immunohistochemistry and flow cytometry analyses. Only i.p. treatment with MLNC-AnxA1 reduced weight loss, diarrhea and disease activity index, and prevented loss of colonic structure integrity; induced the switch of macrophages into M2 phenotype in the lamina propria; recovered the colonic histoarchitecture by decreasing dysplasia of crypts, inflammation and ulcerations; restored the expression of claudin-1 Zonna-occludens-1 tight junctions in the inflamed gut; and induced stem cell proliferation in intestinal crypts. Associated, data highlight the functionalization of MLNC with AnxA1 as a tool to improve the local actions of such protein in the inflamed gut by inducing resolution of inflammation and tissue repair.

Docosahexaenoic fatty acid nanoencapsulated with Anti-PECAM-1 as strategy to increase atherosclerotic plaque stability / Ácido graxo docosahexaenoico nanoencapsulado com anti-PECAM-1 como uma estratégia para aumentar a estabilidade de placas ateroscleróticas

Cardiovascular diseases (CVDs) are the main cause of mortality worldwide, being the ischemic heart disease responsible for 85% of deaths. Atherosclerosis is a chronic inflammation of the arteries that underlies ischemic forms of CVD and involves the innate and adaptive immune systems, from initial fatty streak formation to atherosclerotic plaque ruptures, which defines the beginning and end stages of disease, respectively. Recent research on the reduction of systemic inflammation in order to treat CVD is controversial, since results show that this reduced inflammation can also increase patient susceptibility to general infection. Therefore, new tissue-targeting strategies are necessary. Docosahexaenoic fatty acid (DHA) is a natural bioactive precursor of pro-resolving oxylipins that can reduce inflammation. Based on these factors, the objective of this study was to develop a nanocapsule containing algae oil as a DHA source and apply anti-PECAM-1 on its surface to drive it to the inflamed endothelium. Initially, a surface-functionalized metal-complex multi-wall nanocapsule containing algae oil in its nucleus (MLNC-DHA-a1) was developed. This nanocapsules presented a mean diameter of 163 ± 5 nm, was spherical in shape, showed 94.80% conjugation efficiency using 200 µg/mL of anti-PECAM-1 on the surface, and did not show significant toxicity toward HUVECs at concentrations from 0.14 to 2.90x1011 nanocapsules/mL. The nanocapsules were also stable for 2 h, sufficient time to allow for clinical applications. In cell viability assays, concentrations of 0.14 to 1.40x1011 nanocapsules/mL did not significantly affect the viability of immortalized murine macrophages (RAW 264.7) and U-937 cells after 24, 48, and 72 h of treatment. Finally, macrophages were incubated with 0.75x1011 MLNC-DHA-a1 nanocapsules/mL for 4 h and showed a significant uptake, observed using dark-field hyperspectral microscopy (CytoViva®). Once inside murine macrophages (RAW 264.7), MLNC-DHA-a1 nanocapsules promoted a strong increase in M2 phenotype polarization compared to non-treated control cells. Our results suggest that DHA-enriched algae oil, as part of a lipid core nanocapsules, does not reduce cell viability and improves macrophage phenotype, making it a promising potential therapy for controlling chronic inflammation and healing or stabilizing atherosclerotic plaques

As doenças cardiovasculares (DCVs) são a principal causa de mortalidade no mundo, sendo os eventos isquêmicos responsáveis por 85% das mortes. A aterosclerose é uma inflamação crônica das artérias associada aos eventos isquêmicos das DCVs, na qual o sistema imunológico inato e adaptativo estão envolvidos desde a formação inicial das estrias gordurosas até a ruptura das placas ateroscleróticas. Pesquisas recentes direcionadas à redução da inflamação sistêmica têm mostrado resultados controversos, pois essa abordagem pode aumentar a susceptibilidade do paciente a infecções. Nesse sentido, novas estratégias direcionadas ao tecido lesionado são necessárias. No que se refere a medicamentos anti-inflamatórios ou suplementos alimentares, o ácido docosaexaenóico (DHA) tem sido relatado como um precursor natural de oxilipinas pró- resolutivas. Baseado nesse contexto, o objetivo deste estudo foi desenvolver nanocápsulas contendo óleo de alga como fonte de DHA e vetorizar essas nanopartículas com o anticorpo antiPECAM-1 em sua superfície, visando direcioná-las ao endotélio inflamado. Inicialmente, a nanocápsula multiparede metal-complexa funcionalizada contendo óleo de alga em seu núcleo (MLNC-DHA-a1) foi desenvolvida, apresentando um diâmetro médio de 163 ± 5 nm, formato esférico, onde a eficiência de conjugação do anti-PECAM-1 (200 µg/mL) foi de 94,80% sem toxicidade significativa em HUVECs nas concentrações de 1.14 a 2.9 x 1011 nanocápsulas/mL. As nanocápsulas apresentaram uma estabilidade de 2h, o que representa tempo suficiente para a sua aplicação clínica. A seguir, ensaios de viabilidade celular foram realizados em outras linhagens de células para avaliar a toxicidade das nanocápsulas. As concentrações de 0.14 a 1.40 x 1011 de nanocápsulas/mL não afetaram significativamente a viabilidade celular de macrófagos murinos imortalizados (RAW 264.7) e U-937 após 24, 48 e 72 h de tratamento. Por fim, os macrófagos (RAW 264.7) foram incubados com 0.75 x 1011 MLNC-DHA-a1/mL durante 4 h e apresentam uma captação significativa das nanocápsulas, observada por microscopia hiperespectral de campo escuro (CytoViva®). Uma vez captadas pelos macrófagos murinos imortalizados (RAW 264.7), as nanoformulações MLNC-DHA-a1 promoveram um forte aumento da polarização do fenótipo M2 em comparação com as células controle não tratadas. Nossos resultados sugerem que o óleo de alga rico em DHA presente no núcleo lipídico das nanocápsulas, não reduziu a viabilidade celular e estimulou uma maior polarização de macrófagos para o tipo M2, sendo assim uma terapia potencial para controlar a inflamação crônica e cicatrizar ou estabilizar placas ateroscleróticas