Comprehensive characterizations of nanoparticle biodistribution following systemic injection in mice.

Various nanoparticle (NP) properties such as shape and surface charge have been studied in an attempt to enhance the efficacy of NPs in biomedical applications. When trying to undermine the precise biodistribution of NPs within the target organs, the analytical method becomes the determining factor in measuring the precise quantity of distributed NPs. High performance liquid chromatography (HPLC) represents a more powerful tool in quantifying NP biodistribution compared to conventional analytical methods such as an in vivo imaging system (IVIS). This, in part, is due to better curve linearity offered by HPLC than IVIS. Furthermore, HPLC enables us to fully analyze each gram of NPs present in the organs without compromising the signals and the depth-related sensitivity as is the case in IVIS measurements. In addition, we found that changing physiological conditions improved large NP (200-500 nm) distribution in brain tissue. These results reveal the importance of selecting analytic tools and physiological environment when characterizing NP biodistribution for future nanoscale toxicology, therapeutics and diagnostics.

Functionalized nanoparticles provide early cardioprotection after acute myocardial infarction.

Recent developments in nanotechnology have created considerable potential toward diagnosis and cancer therapy. In contrast, the use of nanotechnology in tissue repair or regeneration remains largely unexplored. We hypothesized that intramyocardial injection of insulin-like growth factor (IGF)-1-complexed poly(D,L-lactide-co-glycolide) (PLGA) nanoparticles (PLGA-IGF-1 NPs) increases IGF-1 retention, induces Akt phosphorylation, and provides early cardioprotection after acute myocardial infarction (MI). We synthesized 3 different sizes of PLGA particles (60 nm, 200 nm, and 1 µm) which were complexed with IGF-1 using electrostatic force to preserve the biological function of IGF-1. Afterward, we injected PLGA-IGF-1 NPs in the heart after MI directly. Compared with the other two larger particles, the 60 nm-sized PLGA-IGF-1 NPs carried more IGF-1 and induced more Akt phosphorylation in cultured cardiomyocytes. PLGA-IGF-1 NPs also prolonged Akt activation in cardiomyocytes up to 24h and prevented cardiomyocyte apoptosis induced by doxorubicin in a dose-dependent manner. In vivo, PLGA-IGF-1 NP treatment significantly retained more IGF-1 in the myocardium than the IGF-1 alone treatment at 2, 6, 8, and 24 h. Akt phosphorylation was detected in cardiomyocytes 24h post-MI only in hearts receiving PLGA-IGF-1 NP treatment, but not in hearts receiving injection of PBS, IGF-1 or PLGA NPs. Importantly, a single intramyocardial injection of PLGA-IGF-1 NPs was sufficient to prevent cardiomyocyte apoptosis (P<0.001), reduce infarct size (P<0.05), and improve left ventricle ejection fraction (P<0.01) 21 days after experimental MI in mice. Our results not only demonstrate the potential of nanoparticle-based technology as a new approach to treating MI, but also have significant implications for translation of this technology into clinical therapy for ischemic cardiovascular diseases.

Treatment of acute thromboembolism in mice using heparin-conjugated carbon nanocapsules.

The unsurpassed properties in electrical conductivity, thermal conductivity, strength, and surface area-to-volume ratio allow for many potential applications of carbon nanomaterials in various fields. Recently, studies have characterized the potential of using carbon nanotubes (CNTs) as a biomaterial for biomedical applications and as a drug carrier via intravenous injection. However, most studies show that unmodified CNTs possess a high degree of toxicity and cause inflammation, mechanical obstruction from high organ retention, and other biocompatibility issues following in vivo delivery. In contrast, carbon nanocapsules (CNCs) have a lower aspect ratio compared with CNTs and have a higher dispersion rate. To investigate the possibility of using CNCs as an alternative to CNTs for drug delivery, heparin-conjugated CNCs (CNC-H) were studied in a mouse model of acute hindlimb thromboembolism. Our results showed that CNC-H not only displayed superior antithrombotic activity in vitro and in vivo but they also had the ability to extend the thrombus formation time far longer than an injection of heparin or CNCs alone. Therefore, the present study showed for the first time that functionalized CNCs can act as nanocarriers to deliver thrombolytic therapeutics.

Biosafety of non-surface modified carbon nanocapsules as a potential alternative to carbon nanotubes for drug delivery purposes.

BACKGROUND: Carbon nanotubes (CNTs) have found wide success in circuitry, photovoltaics, and other applications. In contrast, several hurdles exist in using CNTs towards applications in drug delivery. Raw, non-modified CNTs are widely known for their toxicity. As such, many have attempted to reduce CNT toxicity for intravenous drug delivery purposes by post-process surface modification. Alternatively, a novel sphere-like carbon nanocapsule (CNC) developed by the arc-discharge method holds similar electric and thermal conductivities, as well as high strength. This study investigated the systemic toxicity and biocompatibility of different non-surface modified carbon nanomaterials in mice, including multi-walled carbon nanotubes (MWCNTs), single-walled carbon nanotubes (SWCNTs), carbon nanocapsules (CNCs), and C 60 fullerene (C 60). The retention of the nanomaterials and systemic effects after intravenous injections were studied. METHODOLOGY AND PRINCIPAL FINDINGS: MWCNTs, SWCNTs, CNCs, and C 60 were injected intravenously into FVB mice and then sacrificed for tissue section examination. Inflammatory cytokine levels were evaluated with ELISA. Mice receiving injection of MWCNTs or SWCNTs at 50 µg/g b.w. died while C 60 injected group survived at a 50% rate. Surprisingly, mortality rate of mice injected with CNCs was only at 10%. Tissue sections revealed that most carbon nanomaterials retained in the lung. Furthermore, serum and lung-tissue cytokine levels did not reveal any inflammatory response compared to those in mice receiving normal saline injection. CONCLUSION: Carbon nanocapsules are more biocompatible than other carbon nanomaterials and are more suitable for intravenous drug delivery. These results indicate potential biomedical use of non-surface modified carbon allotrope. Additionally, functionalization of the carbon nanocapsules could further enhance dispersion and biocompatibility for intravenous injection.

The enhancement of endothelial cell therapy for angiogenesis in hindlimb ischemia using hyaluronan.

Growing evidence shows that injection of hyaluronan (HA) benefits ischemic injury in animals. On the other hand, cell therapy is an emerging approach to treat occlusive arterial diseases, although the low retention rate of cells after direct injection remains a major concern. Here, we tested whether injection of HA along with endothelial cells promotes the retention and growth of transplanted cells, thus improving therapeutic angiogenesis in a mouse model of hindlimb ischemia (HI). In culture, HA improved human umbilical vein endothelial cell (HUVEC) proliferation proportional to HA concentration and protected HUVECs from apoptosis. Subsequently, in immunocompromised mice HI was induced by femoral artery ligation and treatments were given 24h later. At 4 weeks, injection of HA along with HUVECs had a greater effect for restoring blood perfusion and salvaging the ischemic limb compared to injection of HA or HUVECs alone. In addition, angiogenesis and arteriogenesis were significantly increased by HA+HUVECs injection. Lastly, HA+HUVECs injection resulted in the retention of more cells than HUVECs alone, and allowed their engraftment into the vasculature of the ischemic limb. These results suggest that this combined approach can be translated into a clinical therapy for peripheral artery occlusive disease.

Intramyocardial peptide nanofiber injection improves postinfarction ventricular remodeling and efficacy of bone marrow cell therapy in pigs.

BACKGROUND: Growing evidence suggests that intramyocardial biomaterial injection improves cardiac functions after myocardial infarction (MI) in rodents. Cell therapy is another promising approach to treat MI, although poor retention of transplanted cells is a major challenge. In this study, we hypothesized that intramyocardial injection of self-assembling peptide nanofibers (NFs) thickens the infarcted myocardium and increases transplanted autologous bone marrow mononuclear cell (MNC) retention to attenuate cardiac remodeling and dysfunction in a pig MI model. METHODS AND RESULTS: A total of 40 mature minipigs were divided into 5 groups: sham, MI+normal saline, MI+NFs, MI+MNCs, and MI+MNCs/NFs. MI was induced by coronary occlusion followed by intramyocardial injection of 2 mL normal saline or 1% NFs with or without 1×10(8) isolated autologous MNCs. NF injection significantly improved diastolic function and reduced ventricular remodeling 28 days after treatment. Injection of MNCs alone ameliorated systolic function only, whereas injection of MNCs with NFs significantly improved both systolic and diastolic functions as indicated by +dP/dt and -dP/dt (1214.5±91.9 and -1109.7±91.2 mm Hg/s in MI+NS, 1693.7±84.7 and -1809.6±264.3 mm Hg/s in MI+MNCs/NFs, respectively), increased transplanted cell retention (29.3±4.5 cells/mm(2) in MI+MNCs and 229.4±41.4 cells/mm(2) in MI+MNCs/NFs) and promoted capillary density in the peri-infarct area. CONCLUSIONS: We demonstrated that NF injection alone prevents ventricular remodeling, whereas cell implantation with NFs improves cell retention and cardiac functions after MI in pigs. This unprecedented combined treatment in a large animal model has therapeutic effects, which can be translated to clinical applications in the foreseeable future.