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Τετάρτη 11 Σεπτεμβρίου 2019

Design and evaluation of anti-fibrosis drug engineered resealed erythrocytes for targeted delivery

Abstract

Resealed erythrocytes (RSE) are potential, site-specific carrier system for drug delivery with prolonged drug release activity. In this study, erythrocytes obtained from Wistar albino rats were loaded with ambroxol hydrochloride (AH) with the focus to convenience the lung targeting possibility of the carrier erythrocytes. AH loading in erythrocytes using preswell dilution technique with glutaraldehyde (GA) as a cross-linking agent was evaluated and validated. Drug-loaded erythrocyte was characterized in terms of in vitro drug release followed by osmotic fragility study which showed amplified drug entrapment efficiency (DEE) and hemoglobin content values as well. In vivo lung fibrosis study, rats were sensitized to egg albumin by intraperitoneal (i.p.) injection and then inhalation in a whole body inhalation chamber. A sign of inflammation, airway sub-mucosal fibrosis, hypertrophy, and hyperplasia was observed. A series of in vivo studies were carried out to describe the effect of AH-loaded RSE including measurement of cytokines in Bronchoalveolar Lavage (BAL) fluid and histopathology study. AH showed a stepwise reduced level of cytokines in BAL at a different time interval after being injected of AH-loaded RSE. Furthermore, in vivo lung distribution experiments were performed for optimized formulation, and degree of distribution of the drugs inside the targeted organ was found to be satisfactory.

High-dose intramyocardial HMGB1 induces long-term cardioprotection in sheep with myocardial infarction

Abstract

In rodents with acute myocardial infarction (AMI), high mobility group box 1 (HMGB1) injection has produced controversial results. Given the lack of data in large mammals, we searched the dose that would promote angiogenesis and expression of specific regenerative genes in sheep with AMI (protocol 1) and, subsequently, use this dose to study long-term effects on infarct size and left ventricular (LV) function (protocol 2). Protocol 1: Sheep with AMI received 250 μg (high-dose, n = 7), 25 μg (low-dose, n = 7) HMGB1, or PBS (placebo, n = 7) in 10 intramyocardial injections (0.2 ml each) in the peri-infarct area. Seven days later, only the high-HMGB1-dose group exhibited higher microvascular densities, Ki67-positive cardiomyocytes, and overexpression of VEGFCkitTbx20Nkx2.5, and Gata4. Protocol 2: Sheep with AMI received HMGB1 250 μg (n = 6) or PBS (n = 6). At 60 days, HMGB1-treated sheep showed smaller infarcts (8.5 ± 2.11 vs. 12.2 ± 1.97% LV area, P < 0.05, ANOVA-Bonferroni) and higher microvascular density (capillaries, 1798 ± 252 vs. 1266 ± 250/mm2; arterioles, 18.3 ± 3.9 vs. 11.7 ± 2.2/mm2; both P < 0.01). Echocardiographic LV ejection fraction, circumferential shortening, and wall thickening increased from day 3 to 60 with HMGB1 (all P < 0.05). Conclusion: in ovine AMI, high-dose HMGB1 induces angio-arteriogenesis, reduces infarct size, and improves LV function at 2 months post-treatment.

Protective effect of surface-modified berberine nanoparticles against LPS-induced neurodegenerative changes: a preclinical study

Abstract

Berberine (BBR) exerts documented protection against neurodegenerative disorders. However, data on the effect of nano-encapsulation on the neuroprotective effect of BBR are lacking. We investigated the effect of BBR loading into chitosan (CS) nanoparticles (NPs) and their surface modification with Tween 80 (T80), polyethylene glycol 4000 (PEG), and miltefosine (MFS) against lipopolysaccharide (LPS)-induced neurodegenerative changes in addition to hepatotoxicity in rats. BBR-NPs were prepared by ionic gelation and characterized for morphology by transmission electron microscopy (TEM), colloidal properties, and entrapment efficiency (EE%). The neuroprotective and hepatoprotective effects of a 14-day pretreatment with four BBR-NPs formulations (4 mg/kg BBR/day) by intraperitoneal (i.p.) injection were challenged by a single i.p. 4 mg/kg dose of LPS on the fifteenth day. Neuroprotective efficacy and potential toxicity of BBR-NPs relative to BBR solution were assessed biochemically and histopathologically. One-way ANOVA followed by Tukey’s comparison test was used for statistical analysis. CS nano-encapsulation and surface modification of BBR-NPs altered the neuroprotective and hepatoprotective effects of BBR depending on the physicochemical and/or biological effects of BBR, CS, coating materials, and NP-related features. Similar to the prophylactic and treatment efficacy of NPs for brain delivery, safety of these nanostructures and their individual formulation components warrants due research attention.

Mechanism of human nail poration by high-repetition-rate, femtosecond laser ablation

Abstract

Optical poration, or drilling, of the human nail has the potential to drastically improve transungual drug delivery. However, this approach is accompanied by thermal damage to the nail tissue surrounding the laser radiation-created pore. In this paper, fluorescence microscopy has been employed to quantitatively evaluate thermal damage to the nail induced by laser ablation with 80 MHz, nanojoule, femtosecond pulses delivered via a hollow-core fibre. An empirical relation has been established between the intensity of the resulting fluorescence signal and temperature to which the nail was exposed. Using this relationship, detailed temperature maps have been created of the areas surrounding the pores, enabling the mechanism of poration to be better understood. It was deduced that plasma-mediated ablation is primarily responsible for nail tissue ablation at the centre of the pore, while cumulative photothermal processes dominate at the pore edges. It is concluded, furthermore, that temperature mapping represents a useful new tool with which to optimise the process of nail poration. The method is potentially generic and may be applicable to other biological materials.

Mesoporous silica nanoparticles, a safe option for silymarin delivery: preparation, characterization, and in vivo evaluation

Abstract

The present work aimed to prepare silymarin-loaded mesoporous silica nanoparticles (MSNs) and to assess the system’s dissolution enhancement ability on the pharmacodynamic performance of silymarin as a hepatoprotective agent. For this purpose, a soft-templating technique was used to prepare silymarin-loaded MSNs. The loaded MSNs were further characterized for their particle size, zeta potential, surface properties, and in vitro drug dissolution testing. In addition, differential scanning calorimetry (DSC) and Fourier transform infrared spectroscopy (FTIR) were also carried out. DSC and specific surface area data confirmed deposition of silymarin in an amorphous state in MSNs’ pores. In vitro drug dissolution testing displayed enhanced dissolution rate of silymarin upon loading on MSNs compared with the free drug. Paracetamol-induced rat model of liver injury was used for the in vivo study. Plasma aspartate aminotransferase (AST), alanine aminotransferase (ALT), total proteins, liver homogenate content of thiobarbituric acid reactive species (TBARS), or lactate dehydrogenase (LDH) were assessed for all animal groups, treated and control ones. Based on parameters indicative of liver function, our results showed that the oral use of silymarin loaded onto MSNs at a dose of 250 mg/kg is significantly superior to free silymarin. Moreover, prolonged administration of the formulation had no evident toxicity on rats.

Effect of formulation parameters on pharmacokinetics, pharmacodynamics, and safety of diclofenac nanomedicine

Abstract

This study reports the development of a nanoformulation of diclofenac sodium, a potent non-steroidal anti-inflammatory drug, at its clinical dose, utilizing a FDA approved polymer, hydroxyethyl starch. The study specifically focused on the control of pharmacokinetics, pharmacodynamics, and biodistribution by particle surface functionalization and alteration of excipient levels in the final formulation. Stable diclofenac sodium–loaded hydroxyethyl starch nanoparticles (nanodiclo) of size 170 ± 5 nm and entrapment efficiency 72 ± 3% were prepared. Free diclofenac, nanodiclo, nanodiclo surface functionalized by PEGylation, nanodiclo with excipients removed, and finally PEGylated nanodiclo with excipients removed were all tested comparatively at two different doses. The results showed substantial impact of both excipients and PEGylation on the pharmacokinetics and pharmacodynamics in vivo. Further, the results proved that excipient removed PEGylated nanodiclo at lower dose achieved clinical therapeutic levels in blood for up to 120 h, with minimal accumulation in critical organs, and much better efficacy than other controls.

Collagen biomaterial for the treatment of myocardial infarction: an update on cardiac tissue engineering and myocardial regeneration

Abstract

Myocardial infarction (MI) remains one of the leading cause of mortality over the world. However, current treatments are more palliative than curative, which only stall the progression of the disease, but not reverse the disease. While stem cells or bioactive molecules therapy is promising, the limited survival and engraftment of bioactive agent due to a hostile environment is a bottleneck for MI treatment. In order to maximize the utility of stem cells and bioactive molecules for myocardial repair and regeneration, various types of biomaterials have been developed. Among them, collagen-based biomaterial is widely utilized for cardiac tissue engineering and regeneration due to its optimal physical and chemical properties. In this review, we summarize the properties of collagen-based biomaterial. Then, we discuss collagen-based biomaterial currently being applied to treat MI alone, or together with stem cells and/or bioactive molecules. Finally, the delivery system of collagen-based biomaterial will also be discussed.

In vitro evaluation of a self-emulsifying drug delivery system (SEDDS) for nasal administration of dimenhydrinate

Abstract

The objective of the study was the development and in vitro characterization of a self-emulsifying drug delivery system (SEDDS) for the nasal application of dimenhydrinate. Final composition of SEDDS was established based on drug solubility and stability studies. Dimenhydrinate was loaded into the SEDDS pre-concentrates to 7.5% (m/v). The droplet size of the final SEDDS formulations was in a range between 60 and 220 nm. Permeability, as well as tissue toxicity, of the formulations was investigated using bovine nasal mucosa. Enhancement in permeation up to 2.8-fold compared to pure dimenhydrinate was confirmed. Furthermore, toxicity studies did not reveal any serious tissue damages related to the SEDDS. Additionally, irritation potential of SEDDS was evaluated in ciliary beat frequency measurements. Incorporation of dimenhydrinate into SEDDS might therefore be considered as a promising approach within the field of nasal delivery of antiemetics by utilizing permeation enhancement strategy.

Nose-to-brain delivery of lamotrigine-loaded PLGA nanoparticles

Abstract

Direct nose-to-brain delivery of drugs and faster onset of action have made intra-nasal route a much sought-after alternative to conventional routes of drug delivery to the brain. Lamotrigine is used for the treatment and management of neuropathic pain, and in the present work, lamotrigine (LTG)-PLGA nanoparticles were developed for intra-nasal delivery. The LTG-PLGA nanoparticles were prepared using modified nanoprecipitation method via high-speed homogenization and ultra-sonication techniques. Entrapment efficiency (EE%) of developed LTG-PLGA-NPs was found to be 84.87 ± 1.2% with drug loading of 10.21 ± 0.89%. The particle size of developed nanoparticles was found to be 184.6 nm with PDI value of 0.082 and zeta potential of − 18.8 mV. Dissolution profiles were studied in PBS (pH 7.4), simulated nasal fluid, and simulated cerebrospinal fluid where almost complete release was observed within 5 h in CSF. In vitro, cytotoxicity was analyzed using MTT assay where dose-dependent cytotoxicity was observed for developed LTG-PLGA-NPs. In vitro cytokine analysis showed positive effects of LTG-PLGA-NPs as pro-inflammatory cytokine suppressors. Further, in vivo studies were performed for radiolabeled formulation and drug (99mTc-LTG-PLGA-NPs and 99mTc-LTG-aqueous) using Sprague Dawley rats where with the help of gamma scintigraphy studies, various routes of administration viz. oral, intra-nasal, and intra-venous were compared. Various pharmacokinetic parameters were evaluated using biodistribution studies to estimate the drug levels in blood and brain. For 99mTc-LTG-PLGA-NPs via intra-nasal route, drug targeting efficiency (DTE%) was found to be 129.81% and drug target organ transport (DTP%) to be 22.81% in brain with Cmax of 3.82%/g within Tmax 1.5 h. Thus, the developed PLGA nanoparticles for intra-nasal delivery provide a possible alternative for existing available drug formulation for neuropathic pain management.

Development of anti-angiogenic erlotinib liposomal formulation for pulmonary hypertension: a QbD approach

Abstract

Pulmonary arterial hypertension (PAH) is the increase in mean pulmonary arterial pressure (> 25 mmHg). The development of the non-reversible plexiform lesions on the arterial walls of the pulmonary arteries has evolved as the reason to increase the pressure. The current treatments are directed towards the vasodilation of the pulmonary arteries via the endothelin, prostacyclin, and NO pathways which provides symptomatic relief. Deeper understanding of the disease leads to the various pathophysiological targets that play an important role in the development of PAH. Out of these, the angiogenetic mechanism of the pulmonary arterial smooth muscle cells has been proved to play an important role in PAH. Targeted therapies by anti-proliferative drugs may lead to the efficient treatment strategies to the root cause of PAH. Erlotinib, a receptor tyrosine kinase inhibitor, which acts on the epidermal growth factor receptor (EGFR), has shown promising results in clinical trials of PAH. The objective of the work has been the development of liposomal formulation of anti-proliferative drug, erlotinib HCl, via Quality by Design (QbD) approach. The liposomal formulation was developed using thin-film hydration technique and characterised for various physicochemical parameters, like particle size, % entrapment efficiency, DSC, FTIR, pXRD, and TEM. In the drug release study, the formulation showed sustained release of erlotinib over 24 h in simulated lung fluid pH 7.4. This developed formulation was evaluated in zebrafish tail fin regeneration assay for its anti-angiogenetic activity. The liposomal formulation inhibited the tail fin regeneration for 14 days indicating anti-angiogenetic activity.

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