Thermal and Convective Loading Methods for Releasing Hydrophobic Therapeutics from Contact Lenses

Horne, Ryan Ruben

01 June 2016

This thesis investigates the feasibility of loading silicone hydrogel (SiHy) contact lenses with two different hydrophobic therapeutics, latanoprost and DMPC (1,2-dimyristoyl-sn-glycero-3-phosphocholine), for treatment of glaucoma and hyperemia respectively. The two methods of loading were 1) thermal loading in an aqueous medium and 2) convective loading in a solution of n-propanol. Dailies Total1® lenses prepared in this manner were tested for their loading and their release into artificial tears. Continuous release over 1-4 days at therapeutic levels is achievable from thermal loading of DMPC, convective loading of DMPC, and convective loading of latanoprost. The DMPC loading processes can be naturally integrated into standard manufacturing lines for Dailies Total1®. Both DMPC and latanoprost release at rates proportional to the amount loaded into a contact lens. Latanoprost loads into a contact lens strictly proportionally to the loading concentration and the time of loading. The convective loading step represents a significant improvement on both the time of loading (reduced from days to minutes) and the loading capacity of silicone hydrogel contact lenses. This thesis also compares the loading and release of latanoprost in the convective loading procedure using the SiHy contact lenses of Acuvue Advance® (Johnson & Johnson Vision Care, Jacksonville, FL) , Air Optix® (Alcon, Copenhagen, Denmark), Biofinity® (CooperVision), PureVision® (Bausch & Lomb), and Dailies Total1® (Alcon), and the polyHEMA lens, SofLens 38® (Bausch & Lomb), finding that silicone hydrogels load an order of magnitude more drug than the polyHEMA lens and release into artificial tears for an order of magnitude longer. Overall, these experiments provide a quantitative understanding of the dynamics of loading and release for both DMPC and latanoprost.

drug delivery

controlled release

contact lens

latanoprost

DMPC

thermal loading

convective loading

silicone hydrogel

glaucoma

dry eye

Chemical Engineering

Distributed Model Predictive Control for Cooperative Highway Driving

Liu, Peng

January 2017

No description available.

Electrical Engineering

Transportation

Robotics

cooperative driving

connected and automated vehicles

CAV

highway collaboration

distributed model predictive control

spatially interconnected systems

DMPC

Lipid bilayers and their interactions with the antimicrobial peptide LL37: a TIR Raman study / Lipidmembran och deras interaktioner med den antimikrobiella peptiden LL37: en TIR Raman studie

Jacob, Rebecca

January 2016

As a direct consequence of the misuse of antibiotics since its first discovery, bacteria have developed extensive resistance mechanisms making them once again potential lethal threats. This eventuality has triggered a vast research effort from scientists worldwide to find solutions to mitigate antimicrobial resistance. One such option is the identification of new potential antimicrobial agents, like for example antimicrobial peptides (AMPs). Various methods have been applied to evaluate the properties and determine the complex mechanism of AMPs. However, the details of the mechanism remain unknown and hence the work in this project seeks to examine the suitability of using TIR Raman, a vibrational spectroscopy technique which is sufficiently surface sensitive to study the interaction of AMPs in contact with lipid bilayers, which are just a few nanometres thick. In order to evaluate the information that could be extracted from TIR Raman, measurement of solid supported lipid bilayers in the absence of peptides were first carried out. In particular, the lipid DMPC with a phase transition close to room temperature, was measured at various temperatures to determine spectral changes associated with the transition. For the peptide-membrane interactions, the AMP LL37 was put into contact with solid supported lipid bilayers modelling the cell membranes of bacteria (DOPE, DOPG) or humans (DOPC) respectively. The data clearly indicates that the membrane composition, and specifically the lipid head group charge, play an important role in the peptide-membrane interactions. In the bilayers mimicking bacteria cell membranes, the peptide either absorbed onto or inserted into the bilayer. In contrast, for the bilayer modelling a human cell membrane, no significant variations were detected, indicating no interaction with LL37. The findings presented in this work generally coincide with similar research of LL37 using other techniques. At hand of the herein presented data, TIR Raman has proven suitable and effective in detecting effects of antimicrobial peptides in contact with model lipid bilayers, and hence can be recommended for further studies. / Som en direkt följd av missbruket av antibiotika sedan det först upptäcktes, har bakterier utvecklat omfattande resistensmekanismer vilket föranlett dem att återigen utgöra potentiellt dödlig hot. Denna situation har manat fram en väsentlig forskningsinsats från forskare världen över att hitta lösningar för att minska antimikrobiell resistens. Ett sådant alternativ har varit identifieringen av nya potentiella antimikrobiella substanser, så som till exempel antimikrobiella peptider. Ett flertal metoder har använts för att både evaluera peptiders egenskaper och fastställa deras komplexa mekanism. Detta till trots förblir de exakta detaljerna i mekanismen okända, vilket föranlett arbetet i detta projekt att undersöka lämpligheten i att använda TIR Raman, en vibrational-spektroskopisk metod som är tillräckligt ytkänslig för att studera interaktionen hos antimikrobiella peptider i kontakt med lipidmembran, vilka endast är några få nanometer tjocka. För att evaluera informationen som kan utvinnas med TIR Raman, utfördes först mätningar av lipidmembran, skapade på ett solitt underlag, utan tillägg av peptider. Mer noggrant, har lipiden DMPC med en fasövergång nära vid rumstemperatur, mätts vid olika temperaturer för att fastställa spektrala variationer associerade till övergången. För peptid-membran interaktionerna, sattes den antimikrobiella peptiden LL37 i kontakt med lipidmembran som modellerar cellmembranet hos bakterier (DOPE, DOPG) respektive människor (DOPC). Mätdatan indikerar tydligt att membrankompositionen, och där specifikt laddningen av lipidens huvudgrupp, spelar en viktig roll i membran-peptid interaktionerna. För lipidmembranen som imiterar bakteriella cellmembran, adsorberade peptiden till membranet eller integrerades in i det. Till skillnad från detta, kunde inga signifikanta variationer detekteras för lipidmembranet som modellerade ett mänskligt membran vilket indikerar att det inte interagerar med peptiden LL37. Upptäckterna som presenteras i detta arbete sammanfaller generellt med andra, liknande studier där andra instrument använts för att undersöka LL37. Det kan ur materialet som presenterats här utläsas att TIR Raman visat sig lämpligt och effektivt i detekteringen av antimikrobiella peptider i kontakt med modeller av lipidmembran, och kan därav rekommenderas för fortsatta studier.

TIR

Raman

LL37

lipid

bilayers

antimicrobial

peptide

AMP

resistance

antibiotics

DMPC

DOPC

DOPE

DOPG

Other Chemistry Topics

Annan kemi

Biological membrane interfaces involved in diseases : a biophysical study

Lindström, Fredrick

January 2006

Interactions between peptides and biological lipid membranes play a crucial role in many cellular processes such as in the mechanism behind Alzheimer’s disease where amyloid-beta peptide (Abeta)is thought to be a key component. The initial step of binding between a surface active peptide and its target membrane or membrane receptor can involve a non specific electrostatic association where positively charged amino acid residues and a negatively charged membrane surface interact. Here, the use of high resolution MAS NMR provides a highly sensitive and non perturbing way of studying the electrostatic potential present at lipid membrane surfaces and the changes resulting from the association of peptides. The interaction between pharmacologically relevant peptides and lipid membranes can also involve incorporation of the peptide into the membrane core and by complementing the NMR approach with differential scanning calorimetry (DSC) the hydrophobic incorporation can be studied in a non invasive way. By using 14N MAS NMR on biological lipid systems for the first time, in addition to 31P, 2H NMR and differential scanning calorimetry (DSC), gives a full picture of the changes all along the phospholipid following interactions at the membrane interface region. Being able to monitor the full length of the phospholipid enables us to differentiate between interactions related to either membrane surface association or hydrophobic core incorporation. This approach was used to establish that the interaction between nociceptin and negatively charged lipid membranes is electrostatic and hence that nociceptin can initially associate with a membrane surface before binding to its receptor. Also, it was found that Abeta can interact with phospholipid membranes via two types of interactions with fundamentally adverse effects. The results reveal that Abeta can associate with the surface of a neuronal membrane promoting accelerated aggregation of the peptide leading to neuronal apoptotic cell death. Furthermore it is also shown that Abeta can anchor itself into the membrane and suppress the neurotoxic aggregation of Abeta.

Solid-state NMR

DSC

Amyloid-beta peptide

Nociceptin

DMPC

DMPG

DDAB

peptide-lipid interaction

branched-chain fatty acid.

Biophysical chemistry

Biofysikalisk kemi

Fluktuationen in Membranen - Schallgeschwindigkeitsmessungen, Kalorimetrie sowie dielektrische und akustische Spektroskopie an wäßrigen Phospholipidsuspensionen / Fluktuations in Membranes - Sound Velocity Measurements, Calorimetry, dieletric Spectroscopy and acoustic Spectroscopy of phospholipidvesicles

Schrader, Wilfried

19 April 2001

No description available.

530 Physik

Mathematics and Computer Science

Fluktuationen

Domänen

Vesikel

Phospholipid

dielektrische Spektroskopie

akustische Spektroskopie

Bhattacharjee

Ferell

DMPC

Schallgeschwindigkeit

33.07

RR 000: Spektroskopie {Physik}

Photon-Echo-Spektroskopie zur Dynamik der Solvatation in Wasser und an Lipidmembran-Wasser-Grenzschichten / Photon-echo spectroscopy in water and at lipidmembrane-water-interfaces: a solvation dynamic study

Bürsing, Helge

24 April 2002

No description available.

540 Chemie

Mathematics and Computer Science

Photon-Echo

Laser

Spektroskopie

Peakshift

Femtosekunde

Solvatation

Membran

DMPC

DPPC

DOPC

Wasser

gehinderte Translation

Rotationsdiffusion

Wasserstoffbrückennetzwerk

photon-echo

Laser

spectroscopy

peakshift

femtosecond

solvation

membrane

DMPC

DPPC

DOPC

water

restricted translation

rotational diffusion

hydrogen-bonded network

35.16

35.21

35.78

RRQ 000: Laser-Spektroskopie {Physik}

WHC 100: Zellmembranen

Zelloberfläche

Zellwand

intrazelluläre Membranen {Cytologie}

SMG 600: Solvolyse {Chemie}

SMG 620: Hydrolyse {Chemie}

Solvatationsdynamik an biologischen Grenzschichten / Solvation dynamics at biological interfaces

Seidel, Marco Thomas

05 November 2003

No description available.

540 Chemie

Mathematics and Computer Science

Femtochemie

Femtobiologie

Laserspektroskopie

Zeitkorreliertes Einzelphotonenzählen

Fluoreszenzkonversionsspektroskopie

Photon-Echo-Spektroskopie

Peakshift

Ultraschnelle Dynamik

Strukturelle Relaxation

Solvatation

Stokes-Shift

Wasser

Wassernanotröpfchen

inverse Mizellen

Membranen

Lipid-Vesikel

AOT

DMPC

HIDCI

Laurdan

TICT

femtochemistry

femtobiology

laser spectroscopy

time-correlated single photon counting

fluorescence up-conversion

photon-echo spectroscopy

peakshift

ultrafast dynamics

structural relaxation

solvation

Stokes-shift

water

water nano-droplets

reverse micelles

membranes

lipid vesicles

AOT

DMPC

HIDCI

laurdan

TICT

35.16

35.21

35.25

35.78

RRQ 000: Laser-Spektroskopie {Physik}

SIL 000: Laser-Chemie {Strahlungschemie}

SMG 000: Lösungen {Chemie}

WCE 000: Photobiologie {Biophysik}

WHC 100: Zellmembranen

Zelloberfläche

Zellwand

intrazelluläre Membranen {Cytologie}