Thoracic interstitial injection of drug-liposomes in mice for treating atherosclerosis

Intervaginal space injection(ISI)is a novel mode of administration investigated over the last decade.After injecting nanoparticles into the intervaginal space,they can be transported along low flow resistance channels into the interstitial space.This transport has a certain delivery direction,and site-specific injection can work on specific organs or tissues.In this study,the thorax,a new ISI site in the interstitial surrounding the internal thoracic artery named the thoracic interstitial injection(tISI)was investigated.To prove the targeting ability of the tISI,two sizes of gold nanoparticles(AuNPs)(47 and 87 nm)were administered to mice.After 1 h,the biodistribution of AuNPs in the tissues was measured via single particle inductively coupled plasma mass spectrometry(spICP-MS).The results showed that the concentration of AuNPs in the aorta after tISI injection was significantly higher than that after intravenous injection.Moreover,fewer nanoparticles with larger particle sizes were observed to have entered the blood and were better targeted to the aorta.Thereafter,tanshinone IIa sodium sulfonate liposomes were administered for the treatment of aortic atherosclerosis.The proportion of aortic plaques in atherosclerotic Apoe-/-mice administered via tISI was significantly lower than that in other model animals(P<0.001).Furthermore,the proteoglycan content and CD68-positive cell count in the plaques were significantly reduced.The vascular elastic fibers at the plaque site were thickened,and fractures were reduced.tISI was,therefore,determined to be an effective strategy for the treatment of atherosclerotic aortic plaques.

Prognosis related genes in HER2+ breast cancer based on weighted gene co-expression network analysis

To the Editor:Breast cancer is one of the malignant diseases that cause death in women and is a severe threat to women’s health.With the progress of medical treatment,there are many methods to treat breast cancer,such as drug therapy and hormone therapy.Among them,molecular targeted therapy has dramatically improved the treatment effect of breast cancer.Therefore,it is vital to find important molecular markers.[1]Breast cancer can be divided into four subtypes:triple-negative(TN),lumA,lumB,and HER2+.[2]HER2+breast cancer accounts for 15–20%of breast cancers,with a higher grade,a more aggressive phenotype,and a worse prognosis.

Dual-responsive fiber-reinforced hydrogel actuators by direct ion patterning

Nature inspired deformable heterogeneous smart hydrogels have attracted much attention in many fields such as biomedicine devices and soft actuators.However,normal spatial heterogeneous hydrogel structures can only respond to single factor and take one action as set in fabrication.Herein,we report a pre-stretched metal-liganded shape memory hydrogel with fiber reinforced,P(AAc-co-AAm)/CCNFs-Fe3+(CCNFs:carboxylated cellulose nanofibers,AAc:acrylic acid,AAm:acrylamide),which can conduct shape deformation by solvent induction and ultraviolet(UV)light.The deformation pattern could be programmed by the deposing of ferroin ions.Also,the pre-stretched shape memory hydrogels could effectively produce cyclic actuation or complex shape actuation by UV light.More importantly,combining the solvent response with the light response enabled complex reversible actuations,such as simulating the bending and unfolding of fingers.The addition of CCNFs significantly enhanced the mechanical properties of the hydrogels.The hydrogels with 3 wt.%CCNFs showed an elongation at break of about 500%and a significant increase in tensile strength of 8.7-fold to 1.55 MPa after coordination with metal ions,which was able to meet the mechanical requirements of the bionic actuated hydrogels.This work demonstrated that combining light-programmed and light-responsive shape-memory hydrogels,complemented by another independent response property,could achieve complex and reversible programmed actuations.