Laboratory of Neuroimmunology and Developmental Origins of Disease, Utrecht, the Netherlands.
Br J Pharmacol. 2011 Jul;163(5):1048-58. doi: 10.1111/j.1476-5381.2011.01314.x.
Systemic glucocorticoid therapy may effectively attenuate lung inflammation but also induce severe side-effects. Delivery of glucocorticoids by liposomes could therefore be beneficial. We investigated if liposome-encapsulated dexamethasone inhibited ventilator-induced lung inflammation. Furthermore, we evaluated whether targeting of cellular Fcγ-receptors (FcγRs) by conjugating immunoglobulin G (IgG) to liposomes, would improve the efficacy of dexamethasone-liposomes in attenuating granulocyte infiltration, one of the hallmarks of lung inflammation.
Mice were anaesthetized, tracheotomized and mechanically ventilated for 5 h with either 'low' tidal volumes ∼7.5 mL·kg(-1) (LV(T) ) or 'high' tidal volumes ∼15 mL·kg(-1) (HV(T) ). At initiation of ventilation, we intravenously administered dexamethasone encapsulated in liposomes (Dex-liposomes), dexamethasone encapsulated in IgG-modified liposomes (IgG-Dex-liposomes) or free dexamethasone. Non-ventilated mice served as controls.
Dex-liposomes attenuated granulocyte infiltration and IL-6 mRNA expression after LV(T) -ventilation, but not after HV(T) -ventilation. Dex-liposomes also down-regulated mRNA expression of IL-1β and KC, but not of CCL2 (MCP-1) in lungs of LV(T) and HV(T) -ventilated mice. Importantly, IgG-Dex-liposomes inhibited granulocyte influx caused by either LV(T) or HV(T) -ventilation. IgG-Dex-liposomes diminished IL-1β and KC mRNA expression in both ventilation groups, and IL-6 and CCL2 mRNA expression in the LV(T) -ventilated group. Free dexamethasone prevented granulocyte influx and inflammatory mediator expression induced by LV(T) or HV(T) -ventilation.
FcγR-targeted IgG-Dex-liposomes are pharmacologically more effective than Dex-liposomes particularly in inhibiting pulmonary granulocyte infiltration. IgG-Dex-liposomes inhibited most parameters of ventilator-induced lung inflammation as effectively as free dexamethasone, with the advantage that liposome-encapsulated dexamethasone will be released locally in the lung thereby preventing systemic side-effects.
全身糖皮质激素治疗可以有效减轻肺部炎症,但也会引起严重的副作用。因此,脂质体包裹的糖皮质激素可能会带来益处。我们研究了包被有地塞米松的脂质体是否可以抑制呼吸机引起的肺部炎症。此外,我们还评估了通过将免疫球蛋白 G (IgG) 偶联到脂质体上来靶向细胞 Fcγ 受体 (FcγR) 是否会提高地塞米松脂质体减轻粒细胞浸润的疗效,粒细胞浸润是肺部炎症的标志之一。
将小鼠麻醉、气管切开并进行机械通气 5 小时,潮气量分别为 7.5 mL·kg(-1) (LV(T)) 或 15 mL·kg(-1) (HV(T))。在开始通气时,我们静脉内给予包被有地塞米松的脂质体(Dex-liposomes)、包被有 IgG 的地塞米松脂质体(IgG-Dex-liposomes)或游离地塞米松。未通气的小鼠作为对照。
Dex-liposomes 减轻了 LV(T) 通气后的粒细胞浸润和 IL-6 mRNA 表达,但对 HV(T) 通气后没有作用。Dex-liposomes 还下调了 IL-1β 和 KC,但没有下调 LV(T) 和 HV(T) 通气后肺部的 CCL2 (MCP-1) mRNA 表达。重要的是,IgG-Dex-liposomes 抑制了 LV(T) 或 HV(T) 通气引起的粒细胞流入。IgG-Dex-liposomes 减少了两组通气小鼠的 IL-1β 和 KC mRNA 表达,以及 LV(T) 通气组的 IL-6 和 CCL2 mRNA 表达。游离地塞米松预防了 LV(T) 或 HV(T) 通气引起的粒细胞流入和炎症介质表达。
FcγR 靶向的 IgG-Dex-liposomes 在药理学上比 Dex-liposomes 更有效,特别是在抑制肺部粒细胞浸润方面。IgG-Dex-liposomes 抑制了大多数呼吸机引起的肺部炎症参数,与游离地塞米松同样有效,而脂质体包裹的地塞米松将在肺部局部释放,从而预防全身副作用。
