Biomimetic micelles to accurately regulate the inflammatory microenvironment for glomerulonephritis treatment.

Glomerulonephritis is a key factor in leading to end-stage renal disease. Mesangial cell proliferation and macrophage infiltration are two prominent features linked in a vicious circle mechanism for glomerulonephritis progression. Herein, a novel biomimetic pH-sensitive nanomicelle (MM/HA-DXM) was constructed to synergize hyaluronic acid (HA)-activated macrophage phenotypic remodeling and dexamethasone (DXM)-mediated mesangial cell killing for precise treatment of glomerulonephritis. Owing to the camouflaged coating with endogenous macrophage membrane (MM), MM/HA-DXM could escape from RES phagocytosis and then be recruited to inflammatory glomerulus by active homing effect. Afterwards, HA-DXM nanomicelles ruptured in response to the weakly acidic glomerulonephritis microenvironment, to locally release HA and DXM. On the one hand, DXM can inhibit the abnormal proliferation of mesangial cells. On the other hand, HA transformed pro-inflammatory M1 macrophages into anti-inflammatory M2 phenotype to improve the glomerular inflammatory microenvironment. In doxorubicin-induced glomerulonephritis models, results revealed that MM/HA-DXM could specifically "homing" to inflammatory renal tissue with 4.33-fold improvement in targeting performance. In addition, in vivo pharmacodynamic results proved that after treatment with MM/HA-DXM, the proteinuria level decreased to 2.33 times, as compared with that of control group, demonstrating a superior therapeutic effect on glomerulonephritis via this collaborative two-pronged anti-inflammatory therapy strategy.

Nanoreactor activated in situ for starvation-chemodynamic therapy of breast cancer.

The nano-drug delivery system activated by the tumour microenvironment (TME) can effectively treat tumours with low toxicity. Based on a high level of reductive GSH in TME and the different coordination properties of Fe ions, this project intended to prepare a GSH-activated cascade catalytic nanoreactor for breast cancer treatment using Fe3+/Fe2+ as the molecular switch. In this study, the glucose oxidase (GOx) loaded iron alginate nano hydrogel (FeAlg/GOx) was prepared by the simple one-step titration method. Results showed that FeAlg/GOx could remain stable during in vivo circulation to avoid hypoglycaemia. When it reached the targeted tumour site, reductive GSH can reduce Fe3+ to Fe2+. Thereafter, FeAlg/GOx nanogel was broken and GOx was released to consume the essential nutrient glucose (Glu) to achieve tumour starvation therapy. Next, the substrate H2O2 generated by the reaction between GOx and Glu can be catalysed by Fe2+ to produce highly cytotoxic •OH in situ, which could further kill tumour cells. The in vivo pharmacodynamics results demonstrated that compared with the control group (V/V0 = 8.36 ± 1.73), FeAlg/GOx group showed the most significant anti-tumour effect with V/V0 of 3.08 ± 1.06. In conclusion, this "inactivated" FeAlg/GOx nanogel can be converted into "activated" therapeutic substances in situ to achieve starvation-chemodynamic combined treatment for breast cancer.