16 research outputs found
Home based formulation of personalised medicines by means of inkjet printing technique
The potential application of inkjet printing technology to produce precisely dosage care is demonstrated in this thesis. Inkjet printing technology as it offers the opportunity to deliver quantities with high accuracy can produce medicines tailored for each patient.
The viability of this method was first demonstrated by using Felodipine as an active pharmaceutical ingredient polyvinyl pirrolidone (PVP) as an excipient. Felodipine is an antihypertensive drug which is poorly soluble in water and PVP is a highly soluble polymer commonly used to improve drugs' bioavailability. These were dissolved at various ratios in a mixture of ethanol and DMSO (95/5). Using a piezoelectric driven dispenser, picolitre size droplets of the solutions were dispensed onto suitable hydrophobic substrates. The dried products were characterized using AFM, localized nano-thermal analysis and high resolution vibrational spectroscopy (ATR-IR and Raman). Results indicate intimate mixing of the micro-dot API and excipient mixtures. Specifically, ATR-IR confirmed the interaction of felodipine and PVP by means of hydrogen bonding. Nanothermal analysis indicates a single glass transition point which is lowered as the API concentration increases. Finally, confocal Raman microscopy mapping on single droplets allows the visualization of the homogeneous distribution of the drug.
Also, capozide has been used as a model therapeutic system which could be produced rapidly as a viable formulation using the inkjet printing technology. Capozide consists of captopril, an angiotensin converting enzyme (ACE) inhibitor and hydrochlorothiazide, a thiazide diuretic drug, in varying ratios. These active pharmaceutical ingredients (APIs) and poly(lactic-co-glycolic acid) (PLGA) were dissolved in appropriate solvents and using a piezoelectric driven dispenser and pipetting, picolitre and microlitre size droplets respectively were deposited onto hydrophobic coated glass slides. Captopril and PLGA were dissolved in chloroform, ethanol and DMSO (75/18/7). Hydrochlorothiazide (HCT) and PLGA were dissolved in acetone and DMSO (93/7). The dried products where characterised using AFM and high resolution Raman microscopy. The results showed that both capropril and HCT are phase separated with the PLGA. Also, the dissolution profiles of the final products were measured using HPLC where it has been shown that PLGA can control the release of the drug from the formulation. These results are a promising first step to produce pharmaceutical by means of inkjet printing
3D printed "Starmix" drug loaded dosage forms for paediatric applications
Purpose:
Three- dimensional (3D) printing has received significant attention as a manufacturing process for pharmaceutical dosage forms. In this study, we used Fusion Deposition Modelling (FDM) in order to print "candy - like" formulations by imitating Starmix sweets to prepare paediatric medicines with enhanced palatability. Methods Hot melt extrusion processing (HME) was coupled with FDM to prepare extruded filaments of indomethacin (IND), hypromellose acetate succinate (HPMCAS) and polyethylene glycol (PEG) formulations and subsequently feed them in the 3D printer. The shapes of the Starmix objects were printed in the form of a heart, ring, bottle, ring, bear and lion. Differential scanning calorimetry (DSC), X-ray powder diffraction (XRPD), Fourier Transform Infra-red Spectroscopy (FT-IR) and confocal Raman analysis were used to assess the drug - excipient interactions and the content uniformity.
Results:
Physicochemical analysis showed the presence of molecularly dispersed IND in the printed tablets. In vivo taste masking evaluation demonstrated excellent masking of the drug bitterness. The printed forms were evaluated for drug dissolution and showed immediate IND release independently of the printed shape, within 60min.
Conclusions:
3D printing was used successfully to process drug loaded filaments for the development of paediatric printed tablets in the form of Starmix designs
Home based formulation of personalised medicines by means of inkjet printing technique
The potential application of inkjet printing technology to produce precisely dosage care is demonstrated in this thesis. Inkjet printing technology as it offers the opportunity to deliver quantities with high accuracy can produce medicines tailored for each patient.
The viability of this method was first demonstrated by using Felodipine as an active pharmaceutical ingredient polyvinyl pirrolidone (PVP) as an excipient. Felodipine is an antihypertensive drug which is poorly soluble in water and PVP is a highly soluble polymer commonly used to improve drugs' bioavailability. These were dissolved at various ratios in a mixture of ethanol and DMSO (95/5). Using a piezoelectric driven dispenser, picolitre size droplets of the solutions were dispensed onto suitable hydrophobic substrates. The dried products were characterized using AFM, localized nano-thermal analysis and high resolution vibrational spectroscopy (ATR-IR and Raman). Results indicate intimate mixing of the micro-dot API and excipient mixtures. Specifically, ATR-IR confirmed the interaction of felodipine and PVP by means of hydrogen bonding. Nanothermal analysis indicates a single glass transition point which is lowered as the API concentration increases. Finally, confocal Raman microscopy mapping on single droplets allows the visualization of the homogeneous distribution of the drug.
Also, capozide has been used as a model therapeutic system which could be produced rapidly as a viable formulation using the inkjet printing technology. Capozide consists of captopril, an angiotensin converting enzyme (ACE) inhibitor and hydrochlorothiazide, a thiazide diuretic drug, in varying ratios. These active pharmaceutical ingredients (APIs) and poly(lactic-co-glycolic acid) (PLGA) were dissolved in appropriate solvents and using a piezoelectric driven dispenser and pipetting, picolitre and microlitre size droplets respectively were deposited onto hydrophobic coated glass slides. Captopril and PLGA were dissolved in chloroform, ethanol and DMSO (75/18/7). Hydrochlorothiazide (HCT) and PLGA were dissolved in acetone and DMSO (93/7). The dried products where characterised using AFM and high resolution Raman microscopy. The results showed that both capropril and HCT are phase separated with the PLGA. Also, the dissolution profiles of the final products were measured using HPLC where it has been shown that PLGA can control the release of the drug from the formulation. These results are a promising first step to produce pharmaceutical by means of inkjet printing
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3D printed chitosan dressing crosslinked with genipin for potential healing of chronic wounds
Recently, various additive manufacturing (3D printing) approaches have been employed to fabricate dressings such as film scaffolds that possess well defined architecture and orientation at the micro level. In this study, crosslinked chitosan (CH) based film matrices were prepared using 3D printing with genipin (GE) as a crosslinker, with glycerol (GLY) and poly ethylene glycol (PEG) as plasticizer. The 3D printed films were functionally characterized using (tensile, fluid handling, mucoadhesion, drug dissolution, morphological properties and cell viability as well physico-chemical characterization using scanning electron microscopy, Fourier transform infrared spectroscopy and X-ray diffraction. CH-GE-PEG600 3D printed films having the ratio of 1:1 polymer: plasticizer was selected due to their appropriate flexibility. Fourier transform infrared results showed intermolecular interaction between CH, GE and PEG which was confirmed by X-ray diffraction showing amorphous matrix structure. In vitro mucoadhesion studies of CH-GE-PEG600 films showed the capability of the 3D printed film to adhere to the epithelial surface. Scanning electron microscopy images showed that the surface of the plasticised films were smooth indicating content uniformity of CH, GE and PEG whilst micro cracks in unplasticised films confirmed their brittle nature. Plasticised films also showed high swelling capacity which enhanced water absorption. Cytotoxicity (MTT) assay using human skin fibroblast cell lines demonstrated that more than 90% of cells were viable after 48 h confirming non-toxic nature of the 3D printed CH-GE-PEG600 films and therefore promising dressing for chronic wound healing applications
Inkjet printing of insulin microneedles for transdermal delivery
Inkjet printing technology was used to apply insulin polymeric layers on metal microneedles for transdermal delivery. A range of various polymers such as gelatin (GLN), polyvinyl caprolactame-polyvinyl acetate-polyethylene glycol (SOL), poly(2-ethyl-2-oxazoline) (POX) and trehalose (THL) were assessed for their capacity to form thin uniform and homogeneous layers that preserve insulin intact. Atomic force microscopy (AFM) showed homogeneous insulin–polymer layers without any phase separation while SOL demonstrated the best performance. Circular discroism (CD) analysis of rehydrated films showed that insulin’s alpha helices and β–sheet were well preserved for THL and SOL. In contrast, GLN and POX insulin layers revealed small band shifts indicating possible conformational changes. Insulin release in Franz diffusion cells from MNs inserted into porcine skin showed rapid release rates for POX and GLN within the first 20 min. Inkjet printing was proved an effective approach for transdermal delivery of insulin in solid state
Taste masked thin films printed by jet dispensing
Taste masking of bitter active substances is an emerging area in the pharmaceutical industry especially for paediatric/geriatric medications. In this study we introduce the use of jet – dispensing as a taste masking technology by printing mucosal thin films of three model bitter substances, Cetirizine HCl, Diphenylhydramine HCl and Ibuprofen. The process was used to dispense aqueous drugs/polymer solutions at very high speed where eventually the drugs were embedded in the polymer matrix. The in vivo evaluation of jet – dispensed mucosal films showed excellent taste masking for drug loadings from 20 - 40%. Jet dispensing was proved to make uniform, accurate and reproducible thin films with excellent content uniformity
Continuous manufacturing of high quality pharmaceutical cocrystals integrated with process analytical tools for in-line process control
A continuous manufacturing process for pharmaceutical indomethacin–saccharine cocrystals was achieved by extrusion processing with high throughput. Down-stream milling and blending of the extrudates was followed by feeding the formulated cocrystals in a capsule-filling machine. By applying a quality by design approach, the process was optimized and scaled up to produce 3000 capsules/h of pharmaceutical cocrystals. Process analytical tools such as near infrared reflectance and spatial filter velocimetry probes were coupled at various process stages for in-line monitoring and quality control. Further physicochemical characterization of extruded batches confirmed the manufacturing of high quality cocrystals. A fully integrated continuous process starting from raw materials to produce a finished product was assembled with only six unit operations and a small footprint. The study is a paradigm of continuous manufacturing of pharmaceutical cocrystals
Development and biological evaluation of Iinkjet printed drug coatings on intravascular stent
Inkjet–printing technology was used to apply biodegradable and biocompatible polymeric coatings of poly(D, L lactide) with the antiproliferative drugs simvastatin (SMV) and paclitaxel (PCX) on coronary metal stents. A piezoelectric dispenser applied coating patterns of very fine droplets (300 xL) and ink jetting was optimized to develop uniform, accurate and reproducible coatings of high yields on the stent strut. The drug loaded polymeric coatings were assed by scanning electron microscopy (SEM), atomic force microscopy (AFM) and transition thermal microscopy (TTM) where a phase separation was observed for SMV/PLA layers while PCX showed a uniform distribution within the polymer layers. Cytocompatibility studies of PLA coatings showed excellent cell adhesion with no decrease of cell viability and proliferation. In vivo stent implantation studies showed significant intra stent restenosis (ISR) for PXC/PLA and PLA plain coatings similar to marketed Presillion (bare metal) and Cypher (drug eluting) stents. The investigation of several cytokine levels after seven days of stent deployment showed no inflammatory response and hence no in vivo cytotoxicity related to PLA coatings. Inkjet printing can be employed as a robust coating technology for the development of drug eluting stents compared to the current conventional approaches
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STENT WO 2016116748 A1
The invention provides a method of manufacturing a stent (12) using a three dimensional (3D) printer. The invention also extends to 3D printed stents and second medical uses of such stents. The invention also extends to electric signals carrying computer-executable instructions adapted to cause a 3D printer to print a stent, computer-readable programs and computer-readable mediums