Computational modelling of polymer-based drug delivery systems

Mackenzie, R. C.

January 2015

Polymer-based drug delivery systems have fantastic potential in chemotherapy as they can reduce drug side effects, help in patient compliance and provide targeting. Nanoprecipitation is used to encapsulate small drug molecules into polymer nanoparticles to form a drug delivery system. A major obstacle in polymer-based drug delivery systems reaching the clinic is their inability to load sufficient drug molecules. Little is known about the processes involved in the encapsulation of drug molecules into these delivery systems. An insight into the processes that govern the formation of these particles and encapsulation of small drug molecules within them is therefore desirable. We used molecular dynamics to model nanoprecipitation by simulating the dispersion of an acetone drop, containing polymer, into water containing drug. To allow sufficient dispersion of acetone a large amount of water is required, thus coarse-graining becomes mandatory. However, we maintain accuracy for our polymer-drug interactions by using a multiscale force field. Atomistic polymer and drug molecules contain coarse-grain virtual sites which facilitate interactions with the coarse-grain solvent molecules. We also employed fully atomistic reference simulations via resolution transformation to optimise our multiscale force field. This thesis details the theory and design behind this model of nanoprecipitation including how other techniques produced inferior results. Initial simulations with our multiscale model matched an experimental trend and were shown to be accurate relative to atomistic reference simulations. We also analysed a fully atomistic simulation of nanoprecipitation that took several months to complete. This atomistic simulation was used as a reference to update the multiscale force field. The updated force field improved on some aspects of the simulation but there are still areas that need improvement. Insight from the simulations provides an understanding of the experimental results and trends. The transferability of the model should help in designing more efficient polymer-based drug delivery systems in the future. We conclude with future work on modelling polymer-based drug delivery systems including alternate methods to gain understanding of not only drug incorporation but also drug release.

615.7

RS Pharmacy and materia medica

Novel amphiphilic polymers from renewable feedstock : synthesis, characterisation and applications

Bansal, Kuldeep Kumar

January 2015

Development of novel biodegradable polymers from renewable resources has attracted attention due to the limitations associated with polymers obtained from petroleum resources. The objective of the work presented in this thesis was to develop various novel biodegradable amphiphilic block copolymers from commercially available sustainable feedstocks for drug delivery applications. Synthesis was performed using a reported method under mild reaction conditions. Renewable δ-decalactone was chosen as a key monomer to synthesise novel amphiphilic block copolymers via ROP using PEG as initiator. A diblock (i.e. mPEG-b-PDL) and a triblock (i.e. PDL-b-PEG-b-PDL) copolymer of poly(decalactone) (PDL) was synthesised and purified successfully. Additionally, a novel triblock copolymer (i.e. mPEG-b-PDL-b-PPDL) was synthesised using ω-pentadecalactone as monomer and mPEG-b-PDL as initiator via ROP to generate a copolymer with different physical properties. Further, a di-block copolymer of ε-caprolactone (i.e. mPEG-b-PCL) was synthesised for comparative studies with novel block copolymers. Micelles of synthesised block copolymers were fabricated using a reported nanoprecipitation method. Micelles fabricated from these novel block copolymers were of sizes <200nm and possessed low critical micelle concentration (CMC) values. Curcumin and Amphotericin B were successfully encapsulated in the novel block copolymer micelles via nanoprecipitation method. The results obtained from curcumin loading and release studies suggested that these novel PDL block copolymers could perform in similar fashion when compared with poly(caprolactone) (PCL) block copolymer micelles. However, in subsequent study micelle of mPEG-b-PDL gave high loading content compared to mPEG-b-PCL micelles when amphotericin B was used as a drug. Further, a preliminary in vitro degradation study of mPEG-b-PDL micelles was performed and the results proposed that the ester linkage of PDL chain were susceptible to hydrolytic degradation in physiological condition. Additionally, in vitro cytotoxicity studies performed on HCT-116 human colon cancer cells revealed that the novel mPEG-b-PDL micelles have similar toxicity profiles when compared to the well-established mPEG-b-PCL micelles. Ligand mediated targeting efficiency of novel diblock copolymer micelles was also studied for potential future applications in cancer therapy. Amphiphilic block copolymers using PEG and PDL were synthesised via click chemistry to generate functionalised block copolymers. Folic acid and rhodamine B were used as targeting ligand and tracker dye respectively. Mixed micelles fabricated from functionalised block copolymers (i.e. FA-PEG-b-PDL, RhB-PEG-b-PDL and mPEG-b-PDL) were tested on folate receptor positive (MCF-7 FR+ve) and folate receptor negative (A549 FR-ve) human cancer cell lines for receptor mediated endocytosis. The acquired confocal images demonstrated the nonspecific uptake of the PEG-b-PDL micelles formulations (targeted and non-targeted) in both cell lines selected in current study. The results obtained from this thesis study suggested that the synthesised novel PDL block copolymer micelles have potential to act as a novel drug delivery system. However, further studies have been proposed to explore the possible applications of these renewable block copolymers.

615.1

RS Pharmacy and materia medica

Estudo da variabilidade de ondas no oceano Atlântico sul e a contribuição energética de um ciclone extratropical intenso nos espectros das ondas ao largo do Rio Grande do Sul

Parise, Cláudia Klose

January 2010

Devido à escassez de instrumentos de medição de onda bem como a grande dificuldade e os altos custos de coleta em regiões oceânicas, a modelagem numérica tem se tornado uma ferramenta bastante útil no estudo de comportamento de ondas costeiras e de oceano profundo. No presente trabalho foi utilizado um modelo numérico global (WAM) para obtenção de dados (modelados) de onda no Oceano Atlântico Sul entre junho de 2006 e julho de 2007. Foram aplicadas as análises EOF e SVD para agrupar as ondas em modos principais de variabilidade espaço-temporais. Em ambas as análises foram obtidos quatro modos principais de variabilidade de todas as variáveis analisadas, sendo que a maior correlação encontrada foi entre o swell e o período de pico. Os padrões espaciais mostraram a contribuição do swell oriundo dos oceanos Pacífico e Índico se propagando no Oceano Atlântico Sul. Foi observado, também, fortes relações entre a variabilidade das ondas e as variáveis atmosféricas de pressão e vento a 10 m de altura. Posteriormente, foi utilizado o mesmo modelo para geração dos espectros de onda durante um estudo de caso de um ciclone extratropical intenso no Oceano Atlântico Sul. Foram selecionados pontos no centro e na periferia do ciclone ao longo da sua trajetória a fim de investigar a presença de interação não linear onda-onda (ressonância) e três pontos offshore à Praia do Cassino com o intuito de estimar a contribuição de energia oriunda do ciclone. A máxima energia espectral no centro do ciclone ocorreu às 21h do dia 01 de setembro e na região offshore à Praia do Cassino o pico ocorreu nas 48 h seguintes. Na maioria dos espectros a densidade espectral foi maior à esquerda do ciclone o que torna válida a hipótese de ocorrência de ressonância nessa região. Assumindo esse evento como extremo em uma escala anual, é possível concluir que um evento de ciclone extratropical de mesma magnitude venha contribuir com mais de 70% da sua energia nos espectros de onda ao largo da costa do Rio Grande do Sul. / Due to the shortage of measurement instruments of wave besides the many difficulties and the high price of date acquisition in oceanic regions, the numerical modeling has been came a useful tool in studies of coastal and ocean deep wave behavior. In this paper was employed a numerical global model (WAM) to obtain the wave data in the South Atlantic Ocean from June 2006 to July 2007. In order to group the waves in leading modes of spatial-temporal variability was applied the EOF and SVD statistic methods. In both analyses were obtained four principal modes of variability for all variables analyzed, where the biggest correlation found was between swell and peak period. The spatial patterns showed the contribution of swell from the Pacific and Indic oceans propagating on the South Atlantic Ocean. Strong relations between the wave variability and atmospheric fields like sea level pressure and wind speed at 10 m height. Later, the same model was used to generate the wave spectra during a case study of intense extratropical cyclone over the South Atlantic Ocean. Points in the center and periphery of cyclone following its track were selected in order to investigate the presence of non-linear wave-wave interaction (resonance) and others three offshore points to the Cassino Beach to estimate the energy contribution from this cyclone. The maximum spectral energy at the cyclone core occurred on September 01 and at the Cassino Beach offshore point just 48h after. In the majority of spectra the energy was greater at the left side of cyclone what become valid the assumption of resonance in the region. Taking this cyclone event like extreme in the annual scale is possible to conclude that a event of extratropical cyclone with the same magnitude can contribute with more that 70% from its energy over the wave spectra in offshore region of Rio Grande do Sul coast.

Geologia marinha

Cassino, Praia do (RS)

Evaluation of community pharmacy electronic patient medication record systems' functionality focusing on safety features and alerts

Ojeleye, Oluwagbemileke Oluwabukade

January 2015

Studies on electronic patient medication record (ePMR) systems that are used in community pharmacy in England have focused primarily on the ability of these systems to highlight potentially hazardous co-prescriptions and prevent clinical hazards and harm to patients. As such, there is a scarcity of literature on the use of ePMR systems, other safety functionality of the systems and user responses to alerts. This thesis aims to fill this gap by examining the functionality of ePMR systems used in community pharmacy in England, focusing on safety features and alerts. This research was conducted in England between July 2010 and July 2013. Evidence for the effectiveness of safety features and alerts in ePMR systems during the dispensing process was evaluated through a systematic review of the literature. Stakeholder perspectives of ePMR systems’ functionality were then obtained through qualitative interviews. The performance of ePMR systems licensed for the electronic prescription service (release 2) in the community pharmacy setting were then assessed using a simulated observational testing approach. Ethnographically informed observations in community pharmacies were subsequently used to study how community pharmacy professionals use ePMR systems and manage alerts in practice. The systematic review included five studies - three randomised controlled trials and two before-after studies, with drug-drug interaction (1), drug-laboratory (2), drug-pregnancy (1) and drug-age (1) alerts. The review revealed that ePMR systems in conjunction with embedded safety features are effective in picking up clinical hazards at the point of dispensing. However, there are problems of false alerts and inconsistencies in alert management. Empirical findings indicate that there are significant issues with the way ePMR systems and alerts are designed and used. Thirty participants took part in the qualitative interviews - community pharmacy professionals (13), health care policy makers (5), legal practitioners specialising in pharmacy (3), ePMR systems’ software vendors (4) and ePMR systems’ software knowledgebase creators (5). Participants attributed alert ineffectiveness in community pharmacy practice to factors such as lack of harmonisation of alert severity levels in systems, poor alert design, over-presentation of alerts and absence of management advice in alerts. Five unique ePMR systems were evaluated in eight participating pharmacies with a sixth ePMR system assessed in a demonstration setting. The systems’ performance was variable and sub-optimal. The ethnographically informed observations took place in the eight pharmacies where system assessment was conducted. The observations revealed that the current design of ePMR systems and presentation of alerts are limiting the quality of support provided to pharmacists and their support staff. This research is part of a growing body of work on the functionality of ePMR systems, their safety features and alerts indicating that ePMR systems require improvements if they are to effectively support patient safety and consistently deliver better patient outcomes. The findings highlight the need to incorporate patient context into alerting to increase alert relevance. In addition, system vendors need to make use of the evidence in the literature to design effective ePMR systems, alerts and user interfaces. An authoritative body should set the minimum specifications for ePMR systems and alerts, and identify the critical alerts that pharmacy professionals should evaluate at the point of dispensing. Additionally, training of pharmacy professionals in health information and communication technology is required to improve patient safety. This should cover areas such as informatics, human factors, safety culture, clinical decision-making, alert management, risk management and communication. Many of the findings are likely to be relevant to similar medication record systems in ambulatory pharmacies around the world; however, further work is required to understand fully the extent of the issues identified in this research.

610.285

RS Pharmacy and materia medica

Manufacturing of oral solid dosage forms using 3D inkjet printing

Kyobula, Mary

January 2017

Ink-jet printing is a precise and versatile technique that accurately deposits small volumes of solutions (pico litres) in specific locations. Recently inkjet printing has attracted increasing attention in the pharmaceutical industry because of its ability to deliver low adjustable doses, variable drug release profiles and drug combinations suitable for the paradigm of personalised medicines. The significant growth in the aging population and the rise in the number of patients suffering from multiple chronic diseases are the key drivers. The current traditional tablet compression methods are largely limited in terms of flexibility and complexity of dosage form. There is a need for new innovative technologies that can produce bespoke medicines in a relatively cheap and efficient manner at the point of care. 3D inkjet printing (3DIJP) provides a platform with the potential to address the above need. This thesis investigates the capability of 3DIJP as a tool for manufacturing solid dosage forms. In chapter 3, a piezoelectric drop on demand printer was used. The chapter focuses on two solvent based inkjet printing methods. In the first solvent based method, excipients including hydroxypropyl methylcellulose (HPMC), poly (vinyl pyrrolidone) (PVP) and Eudragit RL were investigated for printability. PVP (K10) which showed the best printability behaviour was loaded with digoxin or carbamazepine (CBZ) and printed to obtain films. In the second solvent based method, a solution containing CBZ dissolved in a mixture of of polyethylene glycol diacrylate (PEGDA) and with poly(caprolactone dimethyl acrylate) (PCLDMA) was printed and polymerised in situ using ultraviolet light to form films. The printed drug loaded films were investigated using time of flight secondary ion mass spectroscopy (ToF SIMS), atomic force microscopy (AFM), scanning electron microscopy (SEM) and differential scanning microscopy (DSC). PVP formulations were homogeneous, with no evidence of crystallisation PEGDA/PCLDA/CBZAFM images showed a clear phase separation at the micron scale and no drug was detected at the surface. In this chapter, the production of adjustable doses was also evaluatedusing UV-VIS spectrophotometry. In chapters 4 and 5, a solvent-free hot-melt 3D inkjet printing method suitable for manufacturing solid dosage forms was developed. Excipients including beeswax, carnuba wax, gelucire 44/14 and trimyristin were examined for printability. Beeswax a naturally derived and FDA approved material showed the best printability behaviour and was selected as the drug carrier. Traditional circular shaped tablets and cylindrical implants loaded with 5% w/w fenofibrate were successfully fabricated. The printed tablets and implants were well-defined, smooth surfaced and with no apparent defects. The architecture of the tablets was investigated using 3D micro X-ray computed tomography (μCT), revealing well defined and ordered honeycomb channels in the interior of the tablets. The distribution of the drug was evaluated at the macro scale level using DSC and at the micro scale level using ToF - SIMS and Raman spectroscopy. The drug was homogenously distributed within the drug carrier (beeswax matrix ) at the microscale level. At the micron scale level, the drug was heterogeneously distributed. ToF - SIMS studies also revealed that the drug was depleted from the upper most top surfaces. Production of solid dosage forms with intricate and adaptable geometries was demonstrated by printing honeycomb architecture tablets with predetermined variable cell diameters. The diamater of the honeycomb cells was varied, in order to achieve controlled variable drug release profiles. The ablity to control drug release was only applicable above an established critical cell diameter of 0.5 mm. An analytical model describing Fickian diffusion from a slab geometry was developed to allow for the prediction of drug release from the honeycomb tablets. The predicted drug release profiles varied slightly from the experimental data, but the trends for the two data set were identical. For both data sets the rate of drug release increased with increase in the surface area to volume ratio. The findings and the developments demonstrated in this thesis provide an insight into the potential application of 3DIJP as a tool for manufacturing solid dosage forms with bespoke properties for controlled drug release but also highlights some limitations.

615.1

RS Pharmacy and materia medica

Larmöverföring via SMS

Sylvan, Tomas

January 2011

För många med en inbrottscentral hemma eller på sitt företag  kan det vara intressant att i realtid kunna få information om statusförändringar. I vanliga fall kontaktas man av larmcentralen som man är ansluten till, men då oftast enbart vid allvarliga händelser som t.ex. larm eller sabotage och oftast med någon minuts fördröjning.I detta arbete visar jag hur man med enkla medel kan utöka funktionaliteten på sitt larmsystem genom att använda sig av en mikroprocessor och en mobiltelefon. Arbetet resulterar i en fungerande konceptuell enhet med förslag till enkla förändringar för utökad funktionalitet och säkerhet.

RS-232 SMS TTL mikroprocessor

Application of analytical techniques for the study of metal-based anticancer complexes

McQuitty, Ruth J.

January 2013

Transition metal coordination complexes show great promise as novel therapeutic agents with new mechanisms of action, but their characterisation, and identification of their target sites present significant challenges. In this thesis a variety of new analytical methods is explored for the study of platinum, ruthenium, osmium and iridium anticancer complexes. High performance liquid chromatography (HPLC) was used to determine the relative hydrophobicity of a series of photoactivatable Pt(IV) diazido complexes of the general type trans,trans,trans-[Pt(N3)2(OH)2(R)(F11]. Interestingly the hydrophobicities did not follow trends based on literature Log P values of individual ligands and did not correlate with the cellular uptake or antiproliferative activity of the drugs. Other factors such as the quantum yield of the complex, and the type of DNA adducts appear to be more important for their efficacy. Chromatography and high-resolution mass spectrometry were used to study the formation of platinum adducts on DNA when the most active complex trans,trans,trans-[Pt(N3)2(OH)2(PYridine)2], 8 was irradiated in the presence of short single strand oligonucleotides 14 bases in length. Complex 8 was found to bind to the oligonucleotides as a {Pt(pyridine)2}2+ adduct. Modifying the wavelength of activation from UVA to 420 nm had no effect on the type of adduct formed, but the higher energy irradiation achieved maximum levels of DNA platination more quickly. Changing the sequence of the oligonucleotide suggested that the photoactivated form of 8 does not favour the formation of the 1,2-(GpG) bisadduct formed by cisplatin and other clinically approved platinum based drugs, but may form 1,3-(GpNpG) or 1,3-(ApNpG) adducts, as is the case with other trans-platinum complexes. Chiral chromatography using cellulose- and amylose-based stationary phases successfully separated the enantiomers of a series of organometallic 'piano stool' anticancer complexes. This appears to be the first successful separation of facially chiral Ru(II) arene complexes, the enantiomers of which were stable in solution for over 3 h. In contrast, separated cyclopentadienyl WI) complexes with chiral metal centres epimerized within 2 h in solution at ambient temperature. Under similar conditions the enantiomers of the Os(II) arene complex [Os(n6-p-cym)(4-(2-pyridylazo)-N,N-dimethylaniline)Ir remained stable, as did those of the ruthenium-based complex [Ru(9,10- diydrophenanthrene)(en)C1r. It was shown that it is possible to separate the diasteriomers of [Ru(t)6-para-cymene)(iminopyridine)I], that can also be resolved by crystallisationtechniques, and hence, decrease the time required to separate the enantiomers. This work will therefore allow exploration of the biological properties of some of these enantiomers A novel technique for the rapid irradiation and detection of light¬senstive species was developed. Photonic crystal fibers (PCFs) were coupled to a mass spectrometer using HPLC tubing and fittings. This continuous flow method of analysis was validated using the photaquation of cyanocobalamin. The PCF system was compared to the conventional cuvette-based approach. No significant difference in the species detected by MS could be found, but the PCF system had the advantage of requiring 20 times less sample (25 pL), and only 15 min of irradiation compared to 10 h by conventional methods. The new PCF-MS system was then used to study the interaction of the photoactivateable ruthenium-based drug [{(e-indan)RuC1}201-2,3-dPa2+ with a range of small molecules that acted as models for intracellular components, e.g. 5'GMP for DNA. The nucleobase binding properties were consistent with those previously reported with plasmid DNA by Magennis et al: a small amount of binding took place in the dark in view of the aquation of the mondentate leaving groups but this dramatically increased upon photoactivation and loss of the arene ligands. The complex was also found to bind to glutathione (GSH), which is known to detoxify metal-based drugs, an observation possibly explaining its poor anticancer activity.

540

RS Pharmacy and materia medica

The effect of organic salts on HPMC

Mongkolpiyawat, Jiraporn

January 2012

The presence of organic salts as drug counter-ions and buffers in hydroxypropylmethylcellulose (HPMC) matrices is often overlooked. This study investigates their potential to influence polymer solution properties and matrix drug release kinetics. A homologous series of aliphatic organic salts influenced solution and matrix properties in rank order of hydrocarbon chain length. Monovalent salts containing 1to4 C-atoms had little effect on polymer surface activity, but lowered sol:gel transition temperatures (SGTT), and accelerated matrix drug release in comparison with a dextrose control. Divalent salts were more potent. These observations are consistent with Hofmeister effects in which anions restructure water in the polymer hydration sheath, induce 'salting-out' and suppressing particle swelling and matrix gel layer formation. Organic salts with StoB C-atoms increasingly influenced polymer surface activity, elevated SGTT, and retarded matrix drug release. This suggests these salts enhance HPMC hydration, possibly through interaction with hydrophobic regions. The effects of these salts on matrix drug release show that these ions impact on water:polymer interactions important to gel layer formation and diffusion barrier properties. HPMC matrices containing SOS and its homologues were also investigated. Turbidimetric, tensiometric and rheological studies supported a mechanism in which these surfactants solubilise HPMC at post-micellar concentrations. Incorporating 10% SOS into HPMC matrices was shown to increase the resistance of HPMC matrices to sucrose medium up to 2.0M, suggesting a role for surfactants in avoiding food solute effects. This study shows that organic salts incorporated in HPMC matrices have the potential to influence drug release in a rank order that reflects their modulation of the HPMC polymer hydration sheath in solution. SOS and its homologous series could retard drug release from HPMC matrices only when their critical aggregation concentration (CAC) was reached. However, it suggests this excipient may have uses as an excipient for improving HPMC matrix release performance.

615.19

RS Pharmacy and materia medica

Polymer bioadhesives for drug delivery

Deacon, Matthew

January 1999

This study is a natural follow on from previous work by M. T. Anderson and I. Fiebrig. The goal of those latter and of the present study is to find a mucoadhesive system for improving the oral bioavailability of a number of drugs, for example bioactive peptides and proteins. This current work evaluates the adhesive properties of a cationic polymer and a cationic protein to mucus glycoproteins as a step towards the future development of a mucoadhesive drug delivery system. Four different mucin populations were analysed in solution (a freshly purified sample PGM-MD, and three purified from different regions of the porcine stomach cardiac, antrum and fundus). Their interaction with two groups of chitosans differing in degree of deacetylation (FA = 0.11 and 0.25) and a protein purified from the foot of the blue mussel Mytilus edulis foot protein-1 (Mefp-1) were studied. Interaction was determined using analytical ultracentrifugation and with the chitosan/mucin interaction specifically atomic force microscopy. The influence of ionic strength on the interaction was studied in detail studied as was the effect of the oligosaccharide composition of the mucin population on the interaction. It was found that both groups of chitosans (FA = 0.11 and 0.25) formed a large complex with a freshly purified mucin population (PGM-MD). Ionic strengths above 0.2 M were found to inhibit the interaction. The three mucin species differed in terms of their net charge, with cardiac being the most negatively charged and antrum the least negative. It was found that the cardiac species interacted the most and antrum the least, as would be expected for an ionic interaction. Increasing ionic strength was found to inhibit the interaction. There was also evidence for a hydrophobic interaction at high ionic strengths. The atomic force microscopy results allowed the complex to be visualised under atmospheric conditions and to get away from the harsh sample preparation techniques employed by electron microscopy. Large spherical complexes were seen as entanglements of mucin and chitosan strands.

572

RS Pharmacy and materia medica

The influence of powder bed porosity variations on the filling of hard gelatin capsules by a dosator system

Woodhead, Philip John

January 1980

The weight variation of gelatin capsules filled by a dosator-type machine has several possible causes, one of which, the presence of density variations within the powder feed bed, has been evaluated, using a number of particle size fractions of material. Existing theories suggested that the bulk density, or porosity of a powder bed depends on the velocity and intensity of deposition of the particles, together with the properties of the powder. Experiments with lactose confirmed this, indicating in particular that low velocity deposition encourages the formation of regions of relatively high porosity. The application of vibration, especially in a vertical direction, proved effective in reducing the porosity of powder packings, and optimum frequency and acceleration appeared to be largely independent of particle size. A system was developed for detecting porosity variations within powder beds, using the technique of gamma-ray attenuation, the principle being that the reduction in intensity of a Gamma-ray beam traversing a powder bed is a function of local porosity. The observed linear attenuation coefficient of lactose was found to be a function of porosity, for reasons not fully established, hence a calibration expression for the attenuation coefficient was proposed, and was used in subsequent local porosity determinations. The radial distribution of porosity within cylindrical samples of lactose, prepared under various conditions, was studied, and a means of presenting such distributions pictorially was developed. The influence of deposition method, and applied vibration, on the uniformity, of such packings, was clearly demonstrated. A semi-automatic dosator-type capsule filling machine was used to evaluate the relationship between powder feed bed porosity variations and capsule fill weight variation. The results indicated that in the case of lactose, the influence of porosity variations, of the order of magnitude encountered, tends to be masked by other phenomena affecting the filling process.

660

RS Pharmacy and materia medica