Teerapol Srichana

The effect of sericin from various extraction methods on cell viability and collagen production.

Silk sericin (SS) can accelerate cell proliferation and attachment; however, SS can be extracted by various methods, which result in SS exhibiting different physical and biological properties. We found that SS produced from various extraction methods has different molecular weights, zeta potential, particle size and amino acid content. The MTT assay indicated that SS from all extraction methods had no toxicity to mouse fibroblast cells at concentrations up to 40 μg/mL after 24 h incubation, but SS obtained from some extraction methods can be toxic at higher concentrations. Heat-degraded SS was the least toxic to cells and activated the highest collagen production, while urea-extracted SS showed the lowest cell viability and collagen production. SS from urea extraction was severely harmful to cells at concentrations higher than 100 μg/mL. SS from all extraction methods could still promote collagen production in a concentration-dependent manner, even at high concentrations that are toxic to cells.

Monitoring of inflammatory mediators induced by silk sericin.

Silk proteins have been shown to be good candidates for biomedical materials. However, there have been some reports regarding immunological and allergic responses to silk sericin. Our objective was to investigate the inflammatory mediators induced by sericin both in vitro and in vivo. Mouse monocyte and alveolar macrophage cell lines were used for monitoring levels of interleukin (IL)-1beta and tumor necrosis factor (TNF)-alpha generated after activation by sericin at concentrations of 0.2-1.0 mg/mL. The amounts of TNF-alpha and IL-1beta produced by both cell lines corresponded, in a dose-dependent manner, with the sericin concentration in the culture medium. The levels of TNF-alpha and IL-1beta generated after sericin activation by macrophage cells were higher than those generated by monocytes. However, these cytokine levels would not cascade to other inflammatory effects. Inflammatory mediators were also monitored from sericin-treated, cream base-treated and normal saline-soaked full-thickness rat excisions. Using wound size measurements and ELISA assays, sericin-treated wounds were shown to heal faster and had lower levels of inflammatory mediators, as compared with the cream base-treated and normal saline-soaked wounds. It can be concluded that sericin promotes the wound healing process without causing inflammation.

Dry powder inhalers: the influence of device resistance and powder formulation on drug and lactose deposition in vitro.

It is a principal in the formulation of a dry powder aerosol that the device should enable a high fine particle fraction (FPF) of drug to be delivered to the lung whilst any carrier, such as lactose, should remain in the upper airways. Both the device and the dry powder formulation itself contribute to the resultant FPF and few studies have considered the deposition of lactose carrier. It was the purpose of this study to determine the effect of the resistance of the device and the influence of powder formulation on the deposition of drug and carrier. Measurement of the pressure drop across the devices investigated in this study showed that the two types of Inhalator Ingelheim had the highest resistance, whilst lower pressure drops were found across the Diskhaler, Cyclohaler and Accuhaler devices. The lowest pressure drops were measured across the Rotahaler and Spinhaler devices. Employing Rotacaps 400 capsules as the formulated salbutamol product, the FPF of drug was greater from the high resistance devices, being in the order Inhalators Ingelheim>Cyclohaler>Rotahaler=Spinhaler. However, the Diskhaler, employing its own developed formulation, produced the highest FPF, approximately twice that from the Accuhaler. There was no statistical difference between the FPF of salbutamol (approximately 20% nominal dose) from the Rotacaps formulation when aerosolised using high resistance devices (Inhalators Ingelheim) operated at 30 l min-1, a medium resistance device (Cyclohaler) operated at 60 l min-1 and low resistance devices (Spinhaler and Rotahaler) operated at a flow-rate of 90 l min-1. The Ventolin Diskhaler using its own formulation operated at 60 l min-1 gave a FPF of 40.33%, but the FPF obtained was sensitive to flow, being only 25.65% of the nominal dose at 30 l min-1. Whereas no lactose was found in the FPF from the Accuhaler operated at 60 l min-1, 100, 400 and 3500 microg were obtained from the Diskhaler, Rotacaps and micronised lactose formulation, respectively, when operated at the same flow-rate. An in-house formulation comprising salbutamol sulphate blended with micronised lactose in a weight ratio of 1:67.5 and aerosolised from a Cyclohaler produced a similar FPF to the Diskhaler at 60 l min-1. When air flow was reduced to 30 l min-1, the FPF from the in-house formulation was reduced considerably less than that from the Diskhaler formulation.

Potential applications of silk sericin, a natural protein from textile industry by-products

Silk is composed of two major proteins, fibroin (fibrous protein) and sericin (globular, gumming protein). Fibroin has been used in textile manufacturing and for several biomaterial applications, whereas sericin is considered a waste material in the textile industry. Sericin has recently been found to activate the proliferation of several cell-lines and has also shown various biological activities. Sericin can form a gel by itself; however, after mixing with other polymers and cross-linking it can form a film or a scaffold with good characteristics that can be used in the cosmetic and pharmaceutical industries. Sericin is proven to cause no immunological responses, which has resulted in a more acceptable material for biological applications.

Formulation and characterization of silk sericin–PVA scaffold crosslinked with genipin

A porous-three-dimensional scaffold shows several advantages in terms of tissue engineering since it can provide a framework for cells to attach, proliferate and form an extracellular matrix. Sericin, a by-product from the silk industry, can form a three-dimensional scaffold with PVA after freeze-drying but has a fragile structure. Glycerin (as a plasticizer) and genipin (a crosslinking agent) are necessary to make a strong and stable matrix. Our objective was to investigate the properties of a three-dimensional silk sericin and PVA scaffold with and without glycerin and genipin at various concentrations. SEM showed that adding glycerin into scaffold gave better uniformity and porosity. Smaller pore sizes and better uniformity were found as the concentration of genipin in the scaffold increased. The results of FTIR indicated that glycerin retained a high moisture content and had a major effect at 3286 cm(-1), indicating the presence of water molecule in the matrix structure. Adding genipin into the scaffold resulted in a higher degree of crosslinking or fewer free ∈-amino groups, as shown by the decrease in the stretching (=C-H) peak and absorption peaks around 1370-1650 cm(-1), respectively. The sericin/PVA scaffold had a low water sorption capacity, but adding glycerin significantly increased this property. Genipin further enhanced the moisture absorption capacity of the scaffold and extended the time taken to reach equilibrium. After immersing the sericin/PVA scaffold into purified water, the scaffold completely dissolved within an hour, whereas the scaffolds containing glycerin or glycerin with 0.1% genipin swelled 8 and 11 times, respectively, compared with the initial stage after 6h of immersion. In terms of mechanical properties, the sericin/PVA/glycerin scaffold exhibited a similar compressive strength to the scaffold with a high genipin concentration, whereas a low concentration of genipin softened and reduced the compressive strength of the scaffold. A small amount of sericin was released from the scaffold and a higher concentration of genipin, resulting in less protein leaching compared to non-crosslinked sericin/PVA. The fraction of protein released from the sericin/PVA/glycerin scaffold was about 4%, with values of about 1 and 0.04% in the case of scaffolds with 0.01 and 0.1% genipin, respectively. All results indicated that the composition of the scaffolds had a significant effect on their physical properties, and that can easily be tuned to obtain scaffolds suitable for biological applications.

Development of a pH-responsive drug delivery system for enantioselective-controlled delivery of racemic drugs.

This study aimed to develop enantioselective-controlled drug delivery systems for selective release of the required (S)-enantiomer in a dose formulation containing a racemic drug in response to pH stimuli. The recognition system was obtained from a nanoparticle-on-microsphere (NOM) molecularly imprinted polymer (MIP) with a multifunctional chiral cinchona anchor synthesised by suspension polymerisation using ethylene glycol dimethacrylate as a cross-linker. (S)-omeprazole was used as an imprinting molecule conferring stereoselectivity upon the polymers. The ability of the prepared recognition polymers to selectively rebind (S)-omeprazole was evident at different pH levels (the highest being at pH 7.4). The partial selective-release phenomenon of the (S)-enantiomer in MIP-containing composite cellulose membranes with increased vehicular racemic omeprazole concentrations was highly pH-dependent. Cinchona-bonded polymers imprinted with (S)-omeprazole could recognise the moldable contact site of (S)-omeprazole independently of its chirality; this is responsible for the delivery of (S)-enantiomer from racemic omeprazole. The controlled-release drug devices were fabricated with synthesised composite latex, and consisted of a pH stimuli-responsive poly(hydroxyethyl methacrylate) (HEMA) and polycaprolactone-triol (PCL-T) blend, and a MIP with preloaded drug, along with pH 7.4 buffer in the devices interior. The results demonstrate that drug delivery systems containing (S)-omeprazole imprinted cinchona-polymer nanoparticle-on-microspheres may maximise efficacy while minimising dose frequency.

Evaluation of matrices containing molecularly imprinted polymers in the enantioselective-controlled delivery of β-blockers

Granules and beads of methacrylic acid (MAA) and granules of N-acryloyl-alanine polymer (NAA) were produced using ethylene glycol dimethacrylate as cross-linking monomer either by bulk (in the case of granules) or suspension (in the case of beads) polymerization. Either R- or S-propranolol, were used as an imprint molecule, acting as a template, with a view to conferring enantioselectivity of release upon the polymer. The molecularly imprinted polymers (MIPs) or nonMIPs (control) were formulated with racemic propranolol and other excipients and compressed to form matrix tablets. Enantioselective release of propranolol in vitro was monitored using a stereoselective HPLC assay. The influence of the method of polymer synthesis, drug: polymer ratio, pH and temperature on the release of the two enantiomers was determined. Stereoselectivity of release was identified in tablets containing either MAA or NAA granules or MAA beads, with the latter showing the greatest differences between enantiomers. Release of the enantiomer used as the print was always faster than the release of the nonprint enantiomer. In the case of S-propranolol-MIP bead matrices composed of MAA, greater differences in the release of enantiomers could be promoted by increasing the polymer: drug ratio of the tablet. Differences in the release rate of the two propranolol enantiomers was still apparent as the pH was varied between 3 and 7.4 and when the temperature was decreased from 37 to 25 degrees C. S-Propranolol-MIP bead matrices demonstrated cross-reactivities of stereoselective dissolution for enantiomers of pindolol and oxprenolol, both of which have structural similarities to the imprint molecule. It is concluded that polymers of this type may have great potential in controlling, via means of formulation, the release of drug eutomer whilst enhancing retention of distomer in the dosage form.

Development of a reservoir-type transdermal enantioselective-controlled delivery system for racemic propranolol using a molecularly imprinted polymer composite membrane

The aims of this study were to develop a transdermal patch for selective controlled delivery of the active S-enantiomer from racemic propranolol, and to evaluate its performance in vivo using Wistar rats. A molecularly imprinted polymer (MIP) thin-layer composited cellulose membrane with selectivity for S-propranolol was employed as the enantioselective-controlled release system. The effect of gel reservoir (poloxamer and chitosan) on enantioselective delivery was investigated. The chitosan gel allowed excellent selectivity for delivery of the S-propranolol enantiomer, whilst the more rheologically structured poloxamer gel formulation provided no selective release of S-propranolol. The chitosan gel exhibited high flux and had the ability to enantioselective deliver S-propranolol across excised rat skin. The results from confocal laser scanning microscopy study, carried out with the R- and S-propranolol enantiomers labeled with a 1-pyrenebutyric acid probe as fluorescent markers, suggested that the MIP composite membrane selectively regulated the release of the recognised S-enantiomer via a facilitated transport pathway through complex formation with the selective receptor sites, while the release of the R-enantiomer was via a non-selective route. The reservoir patch for enantiomer-controlled delivery of propranolol was therefore fabricated by incorporating the chitosan gel formulation containing racemic propranolol hydrochloride into the MIP composite membrane laminated backing. These patch devices were shown to exhibit the significant stereoselectivity uptake of propranolol when attached to the skin, using pharmacokinetic studies in rats. S-Propranolol enantiomer plasma concentration profiles for the transdermal patch in the in vivo study were comparable to data for the gel formulations that were applied directly to skin, and containing a single S-enantiomer of propranolol. The results demonstrate that the transdermal patch based on the MIP composite membrane-controlled release system may have potential in the enantioselective-controlled delivery of the S-isomer of racemic propranolol.

The Effect of Sericin with Variable Amino-Acid Content from Different Silk Strains on the Production of Collagen and Nitric Oxide

Although silk sericin (SS) enhances the growth and attachment of fibroblast cells, its toxicity remains questionable. We investigated the effect of SS extracted by heat with variable amino-acid content on in vitro collagen promotion and nitric oxide synthesis. After 24 h of incubation, SS, especially from the Chul 1/1 strain which has the most methionine and cysteine content, enhanced fibroblast growth. The molecular mass of heat-extracted SS from these three strains showed a slightly different range, but within 20–200 kDa, which were all identified as sericin. SS from all strains promoted type-I collagen production in a concentration-dependent manner, while SS from Chul 1/1 strain could induce the highest amount of collagen synthesis when compared to SS from other strains. Nitric oxide was found in the culture medium after activation by SS from the Chul 1/1 strain but reached a level that was not toxic to the cells. We conclude that SS is not toxic to fibroblast cells. Moreover, methionine and cysteine content in SS are important factors to promote cell growth and collagen synthesis.

Physicochemical Characterization and Stability of Rifampicin Liposome Dry Powder Formulations for Inhalation

Liposomes were used to encapsulate rifampicin (RIF) as an alternative formulation for delivery to the respiratory tract. Factors affecting the stability of liposomes containing RIF were determined. Four liposome suspensions were prepared, containing different millimole ratios of cholesterol (CH) and soybean L-infinity-phosphatidylcholine (SPC) by the chloroform film method, followed by freeze-drying. Cryo-transmission electron microscopy, photon correlation spectroscopy, (2)H and (31)P solid-state nuclear magnetic resonance were used to characterize the liposome suspensions. Differential scanning calorimetry and X-ray diffraction were used to examine the properties of the powder formulations. The powder was dispersed through an Andersen cascade impactor to evaluate the performance of the aerosolized powder. The liposomes were a mixture of 200-300 nm unilamellar and multilamellar vesicles. Higher CH content in the liposome formulation resulted in a smaller change in size distribution with time, and higher CH content was associated with an increase in the (2)H NMR splitting, indicative of an increase in order of the lipid acyl chains. Furthermore, the SS-NMR results indicated that RIF was located between the acyl chains of the phospholipid bilayer and associated with CH molecules. Fifty percent encapsulation of RIF was obtained when the lipid content was high (SPC 10 mM: CH 10 mM). Mannitol was found to be a suitable cryoprotectant, which is attributed to its crystallinity, and use of mannitol gave particles with a mass median aerodynamic diameter of less than 5 microm. In terms of chemical stability, RIF in dry powder formulations was considerably more stable when compared to RIF aqueous solutions and RIF liposomal suspensions.