Pik-Ling Lam

Development of formaldehyde-free agar/gelatin microcapsules containing berberine HCl and gallic acid and their topical and oral applications

The safety issues of biomedical applications have been a major concern in recent years. Drug delivery associated with microencapsulation technology has been focused on as microencapsulated drugs are believed to promote comparative therapeutic efficiency on human absorption and prolong the life cycle of drugs. The most commonly applied crosslinker is formaldehyde in a gelatin microencapsulation system, which is considerably toxic to the human body. To reduce the risks involved when using formaldehyde, agar was associated with gelatin as the wall matrix materials of microcapsules as it could crosslink with gelatin to give a gel network in the microcapsules formation. Here we report the development, characterization and safe use of agar–gelatin microcapsules. We further demonstrate that both oral and topical applications are possible using the berberine HCl and gallic acid loaded microcapsules respectively. Microcapsules containing both drugs were prepared combining the optimal parameters identified. The mean drug loading efficiency and the mean particle sizes of the berberine HCl loaded microcapsules were 78.16% and 16.75 μm respectively, while those of gallic acid loaded microcapsules were 70.28% and 21.98 μm respectively. The compositions and surface morphology of berberine HCl and gallic acid containing microcapsules were examined using Fourier transform infrared (FTIR) spectroscopy and scanning electron microscopy (SEM). The in vitro controlled release models demonstrated that the drugs could be gradually released from the microcapsules. The minimum inhibitory concentrations (MICs) and anti-Staphylococcus aureus activity also proved that the berberine HCl loaded microcapsules exhibited better antibacterial activity towards Staphylococcus aureus when compared with those of the original drugs. The in vitro drug delivery model also demonstrated the delivery of berberine HCl from microcapsule treated textiles into nude mice skin. The in vivo mice disease model also showed that gallic acid loaded microcapsules were helpful in the treatment of acute liver and kidney toxicity after an overdose administration of acetaminophen. The development of agar–gelatin microcapsules was demonstrated to be an efficient, deliverable tool for both oral and topical applications.

Development of hydrocortisone succinic acid/and 5-fluorouracil/chitosan microcapsules for oral and topical drug deliveries

Recently, we demonstrated the safety use of calendula oil/chitosan microcapsules as a carrier for both oral and topical deliveries. We also reported the improved biological activity towards skin cells and Staphylococcus aureus of phyllanthin containing chitosan microcapsules. However, the possibility of both oral and topical applications was still necessary to be further studied. Here we investigated that both oral and topical applications of chitosan-based microcapsules were tested using hydrocortisone succinic acid (HSA) and 5-fluorouracil (5-FU), respectively. The drug loading efficiency, particle size, surface morphology and chemical compositions of both drug loaded microcapsules were confirmed by UV-vis spectrophotometer, particle size analyzer, scanning electron microscope and Fourier transform infrared spectroscopy. The in vitro release studies revealed that both HSA and 5-FU could be released form chitosan microcapsules. The mean adrenocorticotropic hormone concentration in HSA loaded microcapsule mice plasma was detected to be lower than that of water control. One hundred micrograms per milliliter of 5-FU containing microcapsules exhibited a stronger growth inhibition towards skin keratinocytes than that of free 5-FU. In vitro drug delivery model demonstrated the delivery of 5-FU from microcapsule treated textiles into nude mice skin. Further uses of the drug loaded microcapsules may provide an efficiency deliverable tool for both oral and topical applications.

d-glucose as a modifying agent in gelatin/collagen matrix and reservoir nanoparticles for Calendula officinalis delivery

Gelatin/Collagen-based matrix and reservoir nanoparticles require crosslinkers to stabilize the formed nanosuspensions, considering that physical instability is the main challenge of nanoparticulate systems. The use of crosslinkers improves the physical integrity of nanoformulations under the-host environment. Aldehyde-based fixatives, such as formaldehyde and glutaraldehyde, have been widely applied to the crosslinking process of polymeric nanoparticles. However, their potential toxicity towards human beings has been demonstrated in many previous studies. In order to tackle this problem, D-glucose was used during nanoparticle formation to stabilize the gelatin/collagen-based matrix wall and reservoir wall for the deliveries of Calendula officinalis powder and oil, respectively. In addition, therapeutic selectivity between malignant and normal cells could be observed. The C. officinalis powder loaded nanoparticles significantly strengthened the anti-cancer effect towards human breast adenocarcinoma MCF7 cells and human hepatoma SKHep1 cells when compared with the free powder. On the contrary, the nanoparticles did not show significant cytotoxicity towards normal esophageal epithelial NE3 cells and human skin keratinocyte HaCaT cells. On the basis of these evidences, D-glucose modified gelatin/collagen matrix nanoparticles containing C. officinalis powder might be proposed as a safer alternative vehicle for anti-cancer treatments.

A novel green gelatin-agar microencapsulation system with P. urinaria as an improved anti-A. niger model

In this study, a novel green microencapsulation system was used to develop Phyllanthus urinaria (PU) extract containing microcapsules. Agar was used with gelatin as the wall matrix materials of microcapsules to prevent the use of toxic crosslinker formaldehyde. Microencapsulated PU extract was developed to improve the potential antifungal activities of PU water extracts. The active components and surface morphology of PU extract containing microcapsules were analyzed by liquid chromatography/mass spectrometry and scanning electron microscopy, respectively. The in vitro release study demonstrated that approximately 80% of drug was released after 120 h. PU loaded microcapsules were shown to have a stronger anti-Aspergillus niger activity than the free drug.

Synthesis, characterization and preliminary analysis of in vivo biological activity of chitosan/celecoxib microcapsules

The use of chitosan as the wall of microcapsule designed for delivery of encapsulated celecoxib is reported. Microcapsules were characterised with respect to size and encapsulation efficiency of celecoxib. In vivo animals demonstrated that both free celecoxib administration and chitosan/celecoxib microcapsules administration lead to a significant inhibition of cyclooxygenase-2 protein expression in the hepatocytes when compared with vehicle control mice. Interestingly, microcapsule containing celecoxib showed a better inhibition of cyclooxygenase-2 protein expression when compared with a simple oral administration of free celecoxib. Gas-chromatography-mass-spectrometry analysis showed that in mice treated with free celecoxib or chitosan/celecoxib microcapsules, their plasma concentration of celecoxib was similar. Microcapsules-based biomaterials as oral drug delivery vehicles may help to improve the absorption efficiency of therapeutic drugs.

Development of phyllanthin containing microcapsules and their improved biological activity towards skin cells and Staphylococcus aureus

Chitosan based microcapsule which encapsulated with phyllanthin was developed by simple coacervation. The composition and surface morphology of phyllanthin containing microcapsules were analyzed by Fourier Transform Infrared spectroscopy and Scanning Electron Microscopy, respectively. The release of phyllanthin from the microcapsules was found to be more than 60% after 120 h. In vitro biological assays demonstrated that these phyllanthin containing microcapsules showed a stronger anti-oxidation potential on both human fibroblasts and keratinocytes as well as a better growth inhibitory activity towards Staphylococcus aureus.

Recent advances in green nanoparticulate systems for drug delivery: efficient delivery and safety concern

Nanotechnology manipulates therapeutic agents at the nanoscale for the development of nanomedicines. However, there are current concerns over nanomedicines, mainly related to the possible toxicity of nanomaterials used for health medications. Due to their small size, they can enter the human body more readily than larger sized particles. Green chemistry encompasses the green synthesis of drug-loaded nanoparticles by reducing the use of hazardous materials in the synthesis process, thus reducing the adverse health impacts of pharmaceutics. This would greatly expand their potential in biomedical treatments. This review highlights the potential risks of nanomedicine formulations to health, delivery routes of green nanomedicines, recent advances in the development of green nanoscale systems for biomedical applications and future perspectives for the green development of nanomedicines.

Development of miconazole nitrate containing chitosan microcapsules and their anti-Aspergillus niger activity

In this article, we report the development of chitosan/miconazole nitrate microcapsules. Four miconazole nitrate ratios including 12.5, 25, 50 and 100 mg were performed in the chitosan-based microencapsulation system. Chitosan microcapsules with the drug input of 25 mg showed the highest encapsulation efficiency (52.47%) and acceptable mean particle size (5.65 µm) when compared with those of 12.5, 50 and 100 mg. Fourier transform infrared spectroscopic spectrum proved the entrapment of miconazole nitrate into chitosan microcapsules. The antifungal result demonstrated that microcapsules containing 75 µg miconazole nitrate possessed comparable anti-Aspergillus niger activity as the commercial ointment. The growth inhibition of miconazole nitrate containing chitosan microcapsules towards human skin keratinocytes was found to be dose dependent. A total of 75 µg of miconazole nitrate containing microcapsules revealed about 25% of growth inhibition while that of 150 µg showed approximately 70% of growth inhibition. Special monitoring should be taken if a higher dose of miconazole nitrate was used to develop the microcapsules.

Evaluation of berberine/bovine serum albumin nanoparticles for liver fibrosis therapy

Excretion of hazardous pharmaceutical residues causes the emergence of toxic potential to the environment. Nanomedicine is commonly associated with nanoparticulate drug delivery to offer the improved therapeutic effects at a lower dose for disease treatments. Green chemistry aims to reduce or exclude the utilisation or generation of toxic substances in the design, manufacture and application of chemical products. The use of non-toxic and biodegradable materials in pharmaceutical formulations could minimize the adverse effects of pharmaceutical residues entering the environment in the first place. In our study, bovine serum albumin, a non-toxic, biodegradable and biocompatible protein, was used in the formation of nanoparticulate drug delivery systems. Glucose was used instead of glutaraldehyde to modify albumin nanoparticles for berberine delivery in order to prevent the potential toxicity to humans and the environment. These nanoparticles highly inhibited LX-2 cell growth and exhibited stronger caspase 3 activation at a lower dose when compared with free drug in vitro. Nanoparticles with berberine at doses of 1 and 2 μg g−1 could rescue mice from CCl4-induced hepatotoxicity in vivo. Green glucose-bovine serum albumin nanoparticles could be safe and effective to deliver berberine at low doses in liver fibrosis treatment.

Non-toxic agarose/gelatin-based microencapsulation system containing gallic acid for antifungal application

Aspergillus niger (A. niger) is a common species of Aspergillus molds. Cutaneous aspergillosis usually occurs in skin sites near intravenous injection and approximately 6% of cutaneous aspergillosis cases which do not involve burn or HIV-infected patients are caused by A. niger. Biomaterials and biopharmaceuticals produced from microparticle-based drug delivery systems have received much attention as microencapsulated drugs offer an improvement in therapeutic efficacy due to better human absorption. The frequently used crosslinker, glutaraldehyde, in gelatin-based microencapsulation systems is considered harmful to human beings. In order to tackle the potential risks, agarose has become an alternative polymer to be used with gelatin as wall matrix materials of microcapsules. In the present study, we report the eco-friendly use of an agarose/gelatin-based microencapsulation system to enhance the antifungal activity of gallic acid and reduce its potential cytotoxic effects towards human skin keratinocytes. We used optimal parameter combinations, such as an agarose/gelatin ratio of 1:1, a polymer/oil ratio of 1:60, a surfactant volume of 1% w/w and a stirring speed of 900 rpm. The minimum inhibitory concentration of microencapsulated gallic acid (62.5 µg/ml) was significantly improved when compared with that of the original drug (>750 µg/ml). The anti-A. niger activity of gallic acid -containing microcapsules was much stronger than that of the original drug. Following 48 h of treatment, skin cell survival was approximately 90% with agarose/gelatin microcapsules containing gallic acid, whereas cell viability was only 25-35% with free gallic acid. Our results demonstrate that agarose/gelatin-based microcapsules containing gallic acid may prove to be helpful in the treatment of A. niger-induced skin infections near intravenous injection sites.