Microneedle assisted percutaneous delivery of lidocaine carboxymethylcellulose with gelatine co-polymer hydrogel

Nayak, Atul

January 2016

Local anaesthetic drugs are usually administered as symptom relieving drug formulations for the treatment of pain in superficial skin extremities. The anaesthesia is delivered into skin tissues at the site of pain because of nociceptive receptors. Concerns that exist regarding local anaesthetic drug formulations are low drug encapsulation efficiency, polydispersity of colloidal formulations, chemical interactions of released local anaesthetic drug with skin proteins and bulk viscoelastic properties. Complimenting drug formulation characteristics are the desirable rates of controlled release of drug molecules from chosen formulations pertaining to favourable in vitro skin permeation kinetics are imperative pharmaceutics based research areas because skin percutaneous delivery has distinct barrier property restrictions for passive diffusion (PD) of active molecules. Lidocaine is currently the active anaesthetic molecule of choice in local anaesthesia by clinicians because of minimum toxicity and good potency. It is a low molecular weight drug comprising of electron donating and electron withdrawing functional groups with the capacity to interact by hydrogen bonding and electrostatic interactions with several drug formulation vehicles. In this work, a naturally occurring bi-polymeric formulation was achieved with lidocaine NaCMC:gelatine hydrogel. Lidocaine NaCMC:gelatine ratio of 1:2.3 was the most favourable formulation because of faster skin permeation kinetics. Lidocaine NaCMC:gelatine 1:2.7 provided the highest drug encapsulation efficiency. This resulted in high, sustained permeation rates after adaptation of the microneedle (MN) poke and patch technique, past the stratum corneum layer of skin for quick target delivery in attaining a maximum permeation flux of near 6.0 μg/cm2/h in the hypodermis layer. Mass balance of in vitro studies using an indirect approach to quantify lidocaine permeation showed significant lidocaine permeation in skin. Subsequent vertical and horizontal (depth averaged) in vitro studies using similar MN techniques resulted in crossing minimum therapeutic level across a 10 mm radius from the epicentre of the skin sample at major reduced lag times of minutes for vertical permeation and within 0.5 hours for horizontal permeation. Furthermore, the spreadability of lidocaine NaCMC:gelatine hydrogel shows favourability in the control of droplet spreading on MN treated skin.

615.3

Influence of environmental factors on molecular transport through bacterial membranes

Wu, Tong, 0000-0001-7099-5320

January 2022

Bacterial membranes act as protective barriers and help to regulate molecular interactions between a cell and its surrounding environment. External chemical and physical influences have the potential to alter the properties of bacterial membranes and therefore impact the viability of the cell. This can stem from natural or seasonal changes to the local environment (e.g., temperature, pH, and salinity), or even deliberate application of an antimicrobial agent. Regardless, understanding exactly how such external stimuli influence bacterial membrane properties is of fundamental importance, both in terms of basic microbiology as well as for designing pharmaceutical interventions. Experimentally, this is a non-trivial task as this requires selective isolation of a signal arising from the membrane, which is typically buried in the overwhelming background response of the surrounding bulk environment. In particular, our lab has previously developed the surface-sensitive nonlinear optical method, second harmonic light scattering (SHS), as a means of interrogating molecular interactions at the membrane surfaces of living cells, even for multimembrane systems (e.g., Gram-negative bacteria). In this dissertation, time-resolved SHS was employed to study a variety of membrane properties across two separate projects, including 1) chemical and physical induced changes in membrane permeability and 2) temperature-induced membrane permeability changes. Specifically, in the first project (Chapter 4), the influence of the signaling molecule, indole, on the permeability of the bacterial cytoplasmic membrane was quantified. It was revealed that the interaction of indole with the tryptophan specific transporting protein, Mtr permease, resulted in enhanced passive diffusion across the membrane. For the second project (Chapter 5), we examined the influence of temperature on the rate of passive diffusion across a membrane, both in model systems (liposomes) and in living cells (E. coli). For both bacterial and liposome systems, increasing temperatures resulted in a modest increase in passive diffusion rates across the membrane. However, when the temperature range included a phase transition, passive diffusion increased by an order of magnitude. Therefore, by monitoring transport rate in relation to temperature, membrane phase transitions can be quantitatively determined based on the characteristic discontinuities in the measured trend. / Chemistry

Physical chemistry

Biophysics

Molecular biology

Cell membrane

Environmental factors

Indole

Passive diffusion kinetics

Permeability

Phase transition

Electrochemical Methods for Drug Characterisation and Transdermal Delivery : Capillary Zone Electrophoresis, Conductometry, and Iontophoresis

Merclin, Nadia

January 2003

<p>This thesis concerns the development and utilisation of techniques for characterisation and transdermal delivery of various systems for pharmaceutical applications.</p><p>The degree of dissociation of drug molecules and the mobilities of the different species formed are essential factors affecting the rate of drug delivery by iontophoresis. Hence, determination of drug mobility parameters and equilibrium constants are important for the development of iontophoretic systems. With capillary zone electrophoresis using a partial filling technique and methyl-β-cyclodextrin as chiral selector, the enantiomers of orciprenaline were separated. The association constants between the enantiomers of the drug and the selector were also evaluated. Precision conductometry studies were performed for the hydrochloride salts of lidocaine and 5-aminolevulinic acid in aqueous propylene glycol and water as media, respectively.</p><p>Iontophoresis is a technique for drug delivery where charged molecules are transported into and through skin by application of a weak direct electrical current. The drugs 5-aminolevulinic acid and its methyl ester were used as model compounds and incorporated in two different drug delivery vehicles, a sponge phase and carbopol gel. The bicontinuous structure of the sponge phase, constituted of monoolein and a mixture of propylene glycol and water, makes it interesting for use in iontophoretic delivery, since ions can move more or less freely in the aqueous as well as in the lipid domains. Furthermore, all three components are known for their penetration enhancing abilities. Hydrogels like carbopol gels are interesting media with respect to iontophoretic studies, since devices for iontophoresis often utilize hydrogels as contact interfaces between the skin and the electrodes. The results indicate that the transport achieved iontophoretically using the gel (1 % active substance) was comparable with the passive delivery of clinically used formulations (16 % - 20 % active substance).</p>

Pharmaceutical chemistry

Capillary zone electrophoresis

precision conductometry

iontophoresis

passive diffusion

lidocaine

ALA

ALA-ester derivatives

sponge phase

carbopol gel

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi

Electrochemical Methods for Drug Characterisation and Transdermal Delivery : Capillary Zone Electrophoresis, Conductometry, and Iontophoresis

Merclin, Nadia

January 2003

This thesis concerns the development and utilisation of techniques for characterisation and transdermal delivery of various systems for pharmaceutical applications. The degree of dissociation of drug molecules and the mobilities of the different species formed are essential factors affecting the rate of drug delivery by iontophoresis. Hence, determination of drug mobility parameters and equilibrium constants are important for the development of iontophoretic systems. With capillary zone electrophoresis using a partial filling technique and methyl-β-cyclodextrin as chiral selector, the enantiomers of orciprenaline were separated. The association constants between the enantiomers of the drug and the selector were also evaluated. Precision conductometry studies were performed for the hydrochloride salts of lidocaine and 5-aminolevulinic acid in aqueous propylene glycol and water as media, respectively. Iontophoresis is a technique for drug delivery where charged molecules are transported into and through skin by application of a weak direct electrical current. The drugs 5-aminolevulinic acid and its methyl ester were used as model compounds and incorporated in two different drug delivery vehicles, a sponge phase and carbopol gel. The bicontinuous structure of the sponge phase, constituted of monoolein and a mixture of propylene glycol and water, makes it interesting for use in iontophoretic delivery, since ions can move more or less freely in the aqueous as well as in the lipid domains. Furthermore, all three components are known for their penetration enhancing abilities. Hydrogels like carbopol gels are interesting media with respect to iontophoretic studies, since devices for iontophoresis often utilize hydrogels as contact interfaces between the skin and the electrodes. The results indicate that the transport achieved iontophoretically using the gel (1 % active substance) was comparable with the passive delivery of clinically used formulations (16 % - 20 % active substance).

Pharmaceutical chemistry

Capillary zone electrophoresis

precision conductometry

iontophoresis

passive diffusion

lidocaine

ALA

ALA-ester derivatives

sponge phase

carbopol gel

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi

ATP-Binding Cassette Efflux Transporters and Passive Membrane Permeability in Drug Absorption and Disposition

Matsson, Pär

January 2007

<p>Transport into and across the cells of the human body is a prerequisite for the pharmacological action of drugs. Passive membrane permeability and active transport mechanisms are major determinants of the intestinal absorption of drugs, as well as of the distribution to target tissues and the subsequent metabolism and excretion from the body. In this thesis, the role of ATP-binding cassette (ABC) transporters and passive permeability on drug absorption and disposition was investigated. Particular emphasis was placed on defining the molecular properties important for these transport mechanisms. </p><p>The influence of different transport pathways on predictions of intestinal drug absorption was investigated using experimental models of different complexity. Experimental models that include the paracellular pathway gave improved predictions of intestinal drug absorption, especially for incompletely absorbed drugs. Further, the inhibition of the ABC transporters breast cancer resistance protein (BCRP/ABCG2) and multidrug-resistance associated protein 2 (MRP2/ABCC2) was experimentally investigated using structurally diverse datasets that were representative of orally administered drugs. A large number of previously unknown inhibitors were identified among registered drugs, but their clinical relevance for drug-drug interactions and drug-induced toxicity remains to be determined. The majority of the inhibitors affected all three major ABC transporters BCRP, MRP2 and P-glycoprotein (P gp/ABCB1), and these multi-specific inhibitors were found to be enriched in highly lipophilic weak bases. </p><p>To summarize, the present work has led to an increased knowledge of the molecular features of importance for ABC transporter inhibition and passive membrane permeability. Previously unknown ABC transporter inhibitors were identified and predictive computational models were developed for the different drug transport mechanisms. These could be valuable tools to assist in the prioritization of experimental efforts in early drug discovery.</p>

Pharmaceutics

ATP-binding cassette

ABC transporter

P-gp

P-glycoprotein

ABCB1

BCRP

Breast cancer resistance protein

ABCG2

MRP2

ABCC2

Membrane permeability

Drug transport

Active transport

Passive diffusion

Multivariate data analysis

PLS

OPLS

QSAR

Galenisk farmaci

ATP-Binding Cassette Efflux Transporters and Passive Membrane Permeability in Drug Absorption and Disposition

Matsson, Pär

January 2007

Transport into and across the cells of the human body is a prerequisite for the pharmacological action of drugs. Passive membrane permeability and active transport mechanisms are major determinants of the intestinal absorption of drugs, as well as of the distribution to target tissues and the subsequent metabolism and excretion from the body. In this thesis, the role of ATP-binding cassette (ABC) transporters and passive permeability on drug absorption and disposition was investigated. Particular emphasis was placed on defining the molecular properties important for these transport mechanisms. The influence of different transport pathways on predictions of intestinal drug absorption was investigated using experimental models of different complexity. Experimental models that include the paracellular pathway gave improved predictions of intestinal drug absorption, especially for incompletely absorbed drugs. Further, the inhibition of the ABC transporters breast cancer resistance protein (BCRP/ABCG2) and multidrug-resistance associated protein 2 (MRP2/ABCC2) was experimentally investigated using structurally diverse datasets that were representative of orally administered drugs. A large number of previously unknown inhibitors were identified among registered drugs, but their clinical relevance for drug-drug interactions and drug-induced toxicity remains to be determined. The majority of the inhibitors affected all three major ABC transporters BCRP, MRP2 and P-glycoprotein (P gp/ABCB1), and these multi-specific inhibitors were found to be enriched in highly lipophilic weak bases. To summarize, the present work has led to an increased knowledge of the molecular features of importance for ABC transporter inhibition and passive membrane permeability. Previously unknown ABC transporter inhibitors were identified and predictive computational models were developed for the different drug transport mechanisms. These could be valuable tools to assist in the prioritization of experimental efforts in early drug discovery.

Pharmaceutics

ATP-binding cassette

ABC transporter

P-gp

P-glycoprotein

ABCB1

BCRP

Breast cancer resistance protein

ABCG2

MRP2

ABCC2

Membrane permeability

Drug transport

Active transport

Passive diffusion

Multivariate data analysis

PLS

OPLS

QSAR

Galenisk farmaci