Self-Emulsifying Drug Delivery Systems (SEDDS) Containing Reverse Micelles: Advanced Oral Formulations for Therapeutic Peptides.

Alternative methods to hydrophobic ion pairing for the formation of lipophilic complexes of peptide drugs to incorporate them in lipid-based nanocarriers such as self-emulsifying drug delivery systems (SEDDS) for oral administration are highly on demand. Such an alternative might be reverse micelles. Within this study, SEDDS containing dry reverse micelles (dRMsPMB ) formed with an anionic (sodium docusate; AOT), cationic (dimethyl-dioctadecyl-ammonium bromide; DODAB), amphoteric (soy lecithin; SL), or non-ionic (polysorbate 85; P85) surfactant loaded with the model peptide drug polymyxin B (PMB) are developed. They are characterized regarding size, payload, release kinetics, cellular uptake, and peptide activity. SEDDS exhibit sizes from 22.2 ± 1.7 (AOT-SEDDS-dRMsPMB ) to 61.7 ± 3.2 nm (P85-SEDDS-dRMsPMB ) with payloads up to 2% that are approximately sevenfold higher than those obtained via hydrophobic ion pairing. Within 6 h P85-SEDDS-dRMsPMB and AOT-SEDDS-dRMsPMB show no release of PMB in aqueous medium, whereas DODAB-SEDDS-dRMsPMB and SL-SEDDS-dRMsPMB show a sustained release. DODAB-SEDDS-dRMsPMB improves uptake by Caco-2 cells most efficiently reaching even ≈100% within 4 h followed by AOT-SEDDS-dRMsPMB with ≈20% and P85-/SL-SEDDS-dRMsPMB with ≈5%. The peptide drug maintains its antimicrobial activity in all SEDDS-dRMsPMB . According to these results, SEDDS containing dRMs might be a game changing strategy for oral peptide drug delivery.

S-Protected Thiolated Chitosan versus Thiolated Chitosan as Cell Adhesive Biomaterials for Tissue Engineering.

Chitosan (Ch) and different Ch derivatives have been applied in tissue engineering (TE) because of their biocompatibility, favored mechanical properties, and cost-effectiveness. Most of them, however, lack cell adhesive properties that are crucial for TE. In this study, we aimed to design an S-protected thiolated Ch derivative exhibiting high cell adhesive properties serving as a scaffold for TE. 3-((2-Acetamido-3-methoxy-3-oxopropyl)dithio) propanoic acid was covalently attached to Ch via a carbodiimide-mediated reaction. Low-, medium-, and high-modified Chs (Ch-SS-1, Ch-SS-2, and Ch-SS-3) with 54, 107 and 140 µmol of ligand per gram of polymer, respectively, were tested. In parallel, three thiolated Chs, namely Ch-SH-1, Ch-SH-2, and Ch-SH-3, were prepared by conjugating N-acetyl cysteine to Ch at the same degree of modification to compare the effectiveness of disulfide versus thiol modification on cell adhesion. Ch-SS-1 showed better cell adhesion capability than Ch-SS-2 and Ch-SS-3. This can be explained by the more lipophilic surfaces of Ch-SS as a higher modification was made. Although Ch-SH-1, Ch-SH-2, and Ch-SH-3 were shown to be good substrates for cell adhesion, growth, and proliferation, Ch-SS polymers were superior to Ch-SH polymers in the formation of 3D cell cultures. Cryogels structured by Ch-SS-1 (SSg) resulted in homogeneous scaffolds with tunable pore size and mechanical properties by changing the mass ratio between Ch-SS-1 and heparin used as a cross-linker. SSg scaffolds possessing interconnected microporous structures showed good cell migration, adhesion, and proliferation. Therefore, Ch-SS can be used to construct tunable cryogel scaffolds that are suitable for 3D cell culture and TE.

Smartwatch-derived heart rate variability: a head-to-head comparison with the gold standard in cardiovascular disease.

Aims: We aimed to investigate the concordance between heart rate variability (HRV) derived from the photoplethysmographic (PPG) signal of a commercially available smartwatch compared with the gold-standard high-resolution electrocardiogram (ECG)-derived HRV in patients with cardiovascular disease. Methods and results: We prospectively enrolled 104 survivors of acute ST-elevation myocardial infarction, 129 patients after an ischaemic stroke, and 30 controls. All subjects underwent simultaneous recording of a smartwatch (Garmin vivoactive 4; Garmin Ltd, Olathe, KS, USA)-derived PPG signal and a high-resolution (1000 Hz) ECG for 30 min under standardized conditions. HRV measures in time and frequency domain, non-linear measures, as well as deceleration capacity (DC) were calculated according to previously published technologies from both signals. Lin's concordance correlation coefficient (ρc) between smartwatch-derived and ECG-based HRV markers was used as a measure of diagnostic accuracy. A very high concordance within the whole study cohort was observed for the mean heart rate (ρc = 0.9998), standard deviation of the averages of normal-to-normal (NN) intervals in all 5min segments (SDANN; ρc = 0.9617), and very low frequency power (VLF power; ρc = 0.9613). In contrast, detrended fluctuation analysis (DF-α1; ρc = 0.5919) and the square mean root of the sum of squares of adjacent NN-interval differences (rMSSD; ρc = 0.6617) showed only moderate concordance. Conclusion: Smartwatch-derived HRV provides a practical alternative with excellent accuracy compared with ECG-based HRV for global markers and those characterizing lower frequency components. However, caution is warranted with HRV markers that predominantly assess short-term variability.

Replacing PEG-surfactants in self-emulsifying drug delivery systems: Surfactants with polyhydroxy head groups for advanced cytosolic drug delivery.

AIM: Evaluation of different polyhydroxy surfaces in SEDDS to overcome the limitations associated with conventional polyethylene glycol (PEG)-based SEDDS surfaces for intracellular drug delivery. METHODS: Anionic, cationic and non-ionic polyglycerol- (PG-) and alkylpolyglucoside- (APG-) surfactant based SEDDS were developed and compared to conventional PEG-SEDDS. Particular emphasis was placed on the impact of SEDDS surface decoration on size and zeta potential, drug loading and protective effect, mucus diffusion, SEDDS-cell interaction and intracellular delivery of the model drug curcumin. RESULTS: After self-emulsification, SEDDS droplets sizes were within the range of 35-190 nm. SEDDS formulated with high amounts of long PEG-chain surfactants (>10 monomers) a charge-shielding effect was observed. Replacing PEG-surfactants with PG- and an APG-surfactant did not detrimentally affect SEDDS self-emulsification, payloads or the protection of incorporated curcumin towards oxidation. PG- and APG-SEDDS bearing multiple hydroxy functions on the surface demonstrated mucus permeation comparable to PEG-SEDDS. Steric hinderance and charge-shielding of PEG-SEDDS surface substantially reduced cellular uptake up to 50-fold and impeded endosomal escape, yielding in a 20-fold higher association of PEG-SEDDS with lysosomes. In contrast, polyhydroxy-surfaces on SEDDS promoted pronounced cellular internalisation and no lysosomal co-localisation was observed. This improved uptake resulted in an over 3-fold higher inhibition of tumor cell proliferation after cytosolic curcumin delivery. CONCLUSION: The replacement of PEG-surfactants by surfactants with polyhydroxy head groups in SEDDS is a promising approach to overcome the limitations for intracellular drug delivery associated with conventional PEGylated SEDDS surfaces.

In Vitro Investigation of Thiolated Chitosan Derivatives as Mucoadhesive Coating Materials for Solid Lipid Nanoparticles.

In the present study, chitosan (CS) was thiolated by introducing l-cysteine via amide bond formation. Free thiol groups were protected with highly reactive 6-mercaptonicotinic acid (6-MNA) and less-reactive l-cysteine, respectively, via thiol/disulfide-exchange reactions. Unmodified CS, l-cysteine-modified thiolated CS (CS-Cys), 6-MNA-S-protected thiolated CS (CS-Cys-MNA), and l-cysteine-S-protected thiolated CS (CS-Cys-Cys) were applied as coating materials to solid lipid nanoparticles (SLN). The strength of mucus interaction followed the rank order plain < CS < CS-Cys-Cys < CS-Cys < CS-Cys-MNA, whereas mucus diffusion followed the rank order CS-Cys < CS-Cys-Cys < CS < CS-Cys-MNA < plain. In accordance with lower reactivity, CS-Cys-Cys-coated SLN were immobilized to a lower extent than CS-Cys-coated SLN, while CS-Cys-MNA-coated SLN dissociated from their coating material resulting in a similar diffusion behavior as plain SLN. Consequently, CS-Cys-Cys-coated SLN and CS-Cys-MNA-coated SLN showed the highest retention on porcine intestinal mucosa by enabling a synergism of efficient mucus diffusion and strong mucoadhesion.

Size shifting of solid lipid nanoparticle system triggered by alkaline phosphatase for site specific mucosal drug delivery.

We aim to prepare a size-shifting nanocarrier for site-targeting mucosal drug delivery that can penetrate through mucus gel layer and remain close to the absorption membrane. As nanocarriers can be engineered to penetrate mucus but they can also back diffuse into outer mucus regions, a size shifting to micron range once they have reached the absorption membrane would prevent back-diffusion effect and extend drug release over a long period of time. For this purpose, we loaded solid lipid nanoparticles (SLN) with a phosphate ester surfactant and octadecylamine. Alkaline phosphatase (AP), a membrane bound enzyme was for the first time utilized as an in situ partner for triggering the size conversion at epithelial cell surface. Having the size of ~120 nm, SLN with hydrophilic and phosphate-decorated shells were shown to penetrate through mucus gel and form aggregates above cell layer surface. Aggregates of 5-8 µm were formed due to interparticle interactions induced by enzymatic phosphate removal after ~30 min in contact with isolated AP. The developed SLN system could be a potential tool for mucosal drug delivery to AP-expressing tissues like colon, lung, cervix, vagina and some mucus-secreting tumors.

Charge reversal self-emulsifying drug delivery systems: A comparative study among various phosphorylated surfactants.

HYPOTHESIS: Phosphorylated surfactants having ethoxylate spacer arms are promising excipients for charge reversal self-emulsifying drug delivery systems (SEDDS). EXPERIMENTS: 1,2-Dipalmitoyl-sn-glycero-3-phosphatidic acid disodium salt (PA), 2-((2,3-bis(oleoyloxy)propyl)dimethylammonio)ethyl hydrogen phosphate (DOCP), nonylphenol monophosphate ester (PNPP), C12-15 alcohol 3 ethoxylate phosphate ester (PME) and polyoxyethylene (9) dioctanoyl glycerol pyrophosphate (DGPP) loaded SEDDS were developed and characterized. Zeta potential of SEDDS was measured before and after incubation with intestinal alkaline phosphatase (IAP). Phosphate release was monitored by incubation of SEDDS with isolated as well as cell-associated IAP. Primary amine content on the surface of SEDDS was determined in parallel. Cytotoxicity was evaluated on Caco-2 cells and in vitro hemolysis test was performed. Cellular uptake studies were performed by confocal scanning microscopy. FINDINGS: SEDDS formulations exhibited a size in the range of 17 and 193 nm and a polydispersity index (PDI) ≤ 0.5. Charge reversal from negative to positive values could be achieved in case of PNPP and PME loaded SEDDS with a zeta potential changing from -13 mV to +9 mV and from -7 to +2 mV, respectively, within 6 h. Significant amounts of phosphate were released from PNPP and PME loaded SEDDS incubated with isolated IAP and from all formulations incubated with cell-associated IAP in accordance with an increase in primary amines on the surface of oily droplets. SEDDS exhibited a concentration and time-dependent cytotoxicity. PNPP and PME SEDDS displayed an increased cellular uptake.

Polyphosphate coatings: A promising strategy to overcome the polycation dilemma.

AIM: It was the aim of this study to develop a zeta potential changing drug delivery system by decorating lipid-based nanocarriers with a polycationic cell penetrating peptide (CPP) and subsequently masking these cationic substructures with polyphosphates. METHODS: In order to anchor the CPP poly-l-lysine (PLL) on the surface of the oily droplets of an o/w nanoemulsion, stearic acid was covalently attached to the peptide. The resulting CPP-decorated oily droplets were coated with phytic acid and tripolyphosphate. The elimination of these polyphosphates due to cleavage by alkaline phosphatase was monitored by the release of monophosphate from the surface of the nanocarriers, by the change in zeta potential and by cellular uptake studies on Caco-2 cells. RESULTS: Polyphosphate coated PLL-decorated nanocarriers exhibited a pronounced conversion of zeta potential from -14.1 mV to +4.2 mV in case of tripolyphosphate coated nanocarriers and from -9.9 mV to -2.6 mV in case of phytic acid coated nanocarriers. The cellular uptake on Caco-2 cells of the polyphosphate coated nanocarriers was 4-fold improved compared to the control nanocarriers. Furthermore, confocal images showed that the majority of nanodroplets distributed in cytoplasm not being internalized into lysosomes. CONCLUSION: Polyphosphate coating of CPP-decorated nanocarriers seems to be a promising and simple strategy to overcome the polycation dilemma.

Lysine-Based Biodegradable Surfactants: Increasing the Lipophilicity of Insulin by Hydrophobic Ion Paring.

AIM: The aim of this study was to evaluate biodegradable cationic surfactants based on lysine. METHODS: Lysine was esterified with cholesterol, oleyl alcohol and 1-decanol resulting in cholesteryl lysinate (CL), oleyl lysinate (OL) and decyl lysinate (DL). Esters were investigated regarding their log Dn-octanol/water, critical micelle concentration (CMC) and biodegradability. Hemolytic potential of CL, OL, DL and the already established hexadecyl lysinate (HL) was determined and complexes with insulin (INS) were formed by hydrophobic ion pairing (HIP). Lipophilic characteristics of ion-pairs were examined by analyzing their log Pn-butanol/water. RESULTS: Successful synthesis of CL, OL and DL was confirmed by IR, NMR and MS. Log D analysis revealed amphiphilic properties for the esters and a CMC of 0.01 mM, 2.0 mM and 6.0 mM was found for CL, OL and DL, respectively. Biodegradability was proven, as over 99% of OL and DL were degraded by isolated enzymes within 30 min and after 3 h 97% of CL was cleaved by membrane bound enzymes. OL as well as DL displayed no hemolytic effect and for CL cytotoxicity was significantly reduced in comparison to HL. INS/CL complex exhibited highest lipophilicity. CONCLUSION: Cholesterol-amino acid based surfactants seem to be promising agents for HIP.

Impact of bile salts and a medium chain fatty acid on the physical properties of self-emulsifying drug delivery systems.

The aim of this study was the evaluation of the influence of bile salts and fatty acids, important components of intestinal fluids, on physical characteristics of self-emulsifying drug delivery systems (SEDDS) such as size, polydispersity (PDI), zeta potential (Zp), turbidity (T%), cloud point temperature (CPT) and drug release. At this purpose, nonionic (ni-SEDDS) and cationic (c-SEDDS) were emulsified in aqueous media containing increasing concentrations of bile salts (BS) and decanoate (Dec). Zp of ni-SEDDS and c-SEDDS became highly negative at 15 mM BS and Dec. Size of ni-SEDDS decreased of 112 nm and of 76 nm at 15 mM BS and Dec, respectively. Size of c-SEDDS decreased of 53 nm at 15 mM BS, but it was not affected by 15 mM Dec. PDI and T% of ni- and c-SEDDS were lowered as well. CPT of ni-SEDDS increased from 70 °C to 97 °C and 84 °C at 15 mM BS and Dec. CPT of c-SEDDS decreased from above 100 °C to 80 °C and to 85 °C at 1.5 mM BS and at 5 mM Dec, respectively. Generally, BS had a more pronounced effect on SEDDS Zp, size, PDI, T %, and CPT than Dec. The release of the model drug quinine was accelerated by BS and Dec. As BS and fatty acids affect the physical characteristics and drug release behavior of SEDDS, their impact should be addressed during the development process.

Cellular uptake of self-emulsifying drug-delivery systems: polyethylene glycol versus polyglycerol surface.

Aim: Comparison of the impact of polyethylene glycol (PEG) and polyglycerol (PG) surface decoration on self-emulsifying drug delivery system (SEDDS)-membrane interaction and cellular uptake. Materials & methods: PEG-, PEG/PG- and PG-SEDDS were assessed regarding their self-emulsifying properties, surface charge, bile salt fusibility, cellular uptake and interaction with endosome-mimicking membranes. Results: SEDDS exhibited droplet sizes between 150 and 175 nm, a narrow size distribution and self-emulsified within 7 min. Higher PEG-surfactant amounts in SEDDS resulted in charge-shielding and thus in a decrease of ζ potential up to Δ11 mV. The inert PEG-surface hampered bile salt fusion and interfered SEDDS-cell interaction. By reducing the PEG-surfactant amount to 10%, cellular uptake increased twofold compared with PEG-SEDDS containing 40% PEG-surfactant. PG-SEDDS containing no PEG-surfactants showed a threefold increased cellular uptake. Furthermore, complete replacement of PEG-surfactants by PG-surfactants led to enhanced cellular interaction and improved disruption endosome-like membranes. Conclusion: PG-surfactants demonstrated high potential to address PEG-surface associated drawbacks in SEDDS.

Strategies for improved hair binding: Keratin fractions and the impact of cationic substructures.

Keratin extracts and hydrolysates from varying sources, their chemical modifications and compositions thereof have shown potential in the restoration of hair properties. Within this study on reactivity of thiol groups and the shielding effect of anionic charges the binding of keratin-associated proteins (KAP) and α-keratins (Ker) extracted from human hair to natural and permed hair fibers was evaluated. Selectively extracted KAP and Ker were preactivated with 6-mercaptonicotinamide in a quantity of 194 ± 21 µmol/g for KAP and 169 ± 27 µmol/g for Ker resulting in 1.9- and 1.4-fold enhanced binding to natural hair, respectively. The amount of accumulated Ker on hair fibers was furthermore increased by 1.7-fold in presence of 25 mM L-arginine. Perming of hair impaired binding characteristics of Ker with negligible effects for preactivation, whereas unmodified and preactivated KAP showed results comparable to natural hair. Strongly enhanced penetrability after perming was reflected by the mean penetration depth for fluorescein of 25 µm compared to 5 µm for natural fibers.

Zeta potential changing nanoemulsions: Impact of PEG-corona on phosphate cleavage.

The aim of this study was to evaluate the impact of a PEG-corona on oily droplets of a nanoemulsion on phosphate cleavage on their surface. A PEG-free nanoemulsion composed of 60% oleic acid, 30% Capmul MCM EP and 10% Span 85 being additionally stabilized by 1% cetyltrimethylammonium bromide (CTAB) and 3% phosphatidic acid (PA) was evaluated regarding phosphate release, zeta potential change and mucus permeation properties. In order to evaluate the impact of PEG-corona on phosphate release 10%, 20% and 30% of polyethoxylated-35 castor oil were incorporated in the nanoemulsion. The developed PEG-free nanoemulsion exhibited the droplet size of 123 nm with PDI of 0.24, whereas the droplet size of the nanoemulsions containing PEG ranged from 166 nm to 128 nm with PDI about 0.26. In case of the PEG-free formulation enzymatically induced phosphate cleavage was 3-fold and 7-fold higher than that from formulations containing 20% and 30% PEG-surfactant, respectively. Accordingly, the zeta potential shift of PEG-free formulation reached ~Δ 40 mV within 4 h, whereas zeta potential of PEG-containing formulations did not show any significant changes remaining constant at ~-30 mV. In contrast, PEG-containing formulations exhibited a 3.3-fold to 4-fold higher mucus permeation than the PEG-free formulation. According to the results, a PEG-corona has a great impact on phosphate cleavage and zeta potential change, which has to be taken into consideration for the development of highly efficient zeta potential changing nanocarriers, as zeta potential constitutes one of the crucial parameter regarding the permeation properties through physiological barriers.

Grafting of wool fibers through disulfide bonds: An advanced application of S-protected thiolated starch.

The purpose of this study is to develop a potential pathway for grafting polymers onto wool fibers based on thiol-disulfide exchange reactions. S-protected thiolated starch (PTS) was synthesized by coupling 3-(2-pyridyldithio) propanoic acid to starch through esterification, resulting in 417.3 ± 15.1 µmol ligand binding to 1 g of starch. PTS was labelled with fluorescein isothiocyanate (FITC) prior to grafting. Wool fibers were preactivated by raising the amount of thiol groups utilizing mild reducing agents. The highest degree of preactivation on the surface of wool fibers was achieved by a 0.2% (w/v) sodium borohydride and 1.5% (w/v) sodium bisulfite mixture pH 5.0 resulting in 182.6 ± 8.7 µmol thiol groups per gram of fibers. Different incubation times and ratios between FITC-labelled PTS and wool fibers were investigated. A graft yield of 58.5% was achieved at a ratio of 1:1.5 (w/w) between wool fibers and FITC-labelled PTS within 18 h of incubation. Successful coating of PTS on wool fibers was confirmed by confocal imaging, scanning electron microscopy and FT-IR. Mechanical properties of grafted wool fibers were tested regarding elongation and tensile strength. These results provide evidence for the potential of S-protected thiolated starch as a superior coating material for wool fibers.

Reactive keratin derivatives: A promising strategy for covalent binding to hair.

HYPOTHESIS: Restoration of damaged hair structure by replacing lost keratin is still of paramount interest. On account of the fact that native keratin is a highly cross-linked protein with numerous disulfide bonds but just a few nucleophilic thiol groups, binding affinity to hair is comparatively low. Hence, the design of reactive keratin derivatives bearing free sulfhydryl groups that are optionally S-protected and preactivated should enhance permanent binding to hair fibers. EXPERIMENTS: Keratin was extracted from human Caucasian hair and reduced with NaBH4 to obtain free sulfhydryl groups (keratin-SH). These thiol groups were S-protected via disulfide linkage to 2-mercaptonicotinic acid (keratin-MNA). Hair fibers were either utilized in their natural form or chemically damaged by bleaching. Amount of keratin derivatives being bound to hair fibers was quantified by fluorescence detection of fluorescein isothiocyanate labeled keratins. FINDINGS: Both modifications induced higher affinity of keratin to hair fibers, resulting in up to 1.7-fold (keratin-MNA) improved binding to natural hair and up to 3.6-fold (keratin-MNA) improved binding to bleached hair. Confocal laser microscopy confirmed the accumulation of keratin derivatives in distinct regions of the cuticle layer. Thiol functionalization seems therefore to be a promising strategy for efficient durable binding of keratin to hair.

Development and in vitro evaluation of a self-emulsifying drug delivery system (SEDDS) for oral vancomycin administration.

The aim of this study was to develop a self-emulsifying drug delivery system (SEDDS) containing the glycopeptide antibiotic vancomycin (VAN) with improved intestinal mucosa permeating properties in order to increase oral drug absorption. VAN was effectively incorporated into SEDDS increasing the lipophilicity of the drug via hydrophobic ion pairing (HIP) with cetyltrimethylammonium bromid (CTAB). Newly developed SEDDS formulations containing VAN/CTAB complex were characterized with respect to droplet size, polydispersity index and zeta potential. Furthermore, permeating properties were investigated in porcine intestinal mucus using Transwell setup and on freshly excised porcine intestinal mucosa utilizing Ussing-type chamber. In addition, minimum inhibitory concentration (MIC) of VAN/CTAB-SEDDS against Staphylococcus aureus was evaluated. The developed formulations F1 (25% Capmul 808G EP/NF, 37.5% Cremophor RH 40, 37.5%), F2 (26.5% Capmul 808G EP/NF, 33.2% Cremophor RH 40, 13.8% Transcutol, 26.5% DMSO) and F3 (28.8% Captex 8000, 35% Cremophor EL, 20% Transcutol, 16.2% DMSO) with a mean droplet size of 14 nm, 15 nm and 153 nm, respectively, exhibited improved ability to permeate porcine intestinal mucosal barrier. F1-VAN/CTAB showed 219-fold, F2-VAN/CTAB 46-fold and F3-VAN/CTAB 63-fold higher permeation of VAN through the mucus layer after 4 h in comparison to free VAN. Moreover, all formulations demonstrated a 4-8-fold improvement in permeation of intestinal mucosa compared to free VAN solution. Additionally, F2-VAN/CTAB with a MIC of 0.313 mg/L showed higher effectivity against S. aureus (ATCC® 29213) compared to free VAN. According to these results, HIP combined with SEDDS should be taken into consideration as promising tool for oral antibiotic delivery.

Highly mucus permeating and zeta potential changing self-emulsifying drug delivery systems: A potent gene delivery model for causal treatment of cystic fibrosis.

AIM: It was the aim of the study to develop self-emulsifying drug delivery systems (SEDDS) with the ability to change their zeta potential towards higher values at the adsorption membrane and in this way facilitate the release of the DNA-cetrimonium complex and enhance transfection. METHODS: Plasmid DNA was complexed via hydrophobic ion pairing utilizing various surfactants and the complex was incorporated into SEDDS achieving a payload of 1% (m/v). Log PSEDDS/water of the complex was determined. SEDDS were characterized regarding droplet size, zeta potential, stability and toxicity. Alkaline phosphatase presented in the sputum of cystic fibrosis patients was quantified using 4-nitrophenyl phosphate disodium salt and 5-bromo-4-chloro-1H-indol-3-yl phosphate dipotassium salt as substrates. SEDDS containing 0.4% (m/v) 1,2-dipalmitoyl-sn-glycero-3-phosphate monosodium salt were characterized regarding their zeta potential changing properties utilizing isolated alkaline phosphatase and cystic fibrosis sputum. The mucus permeating properties of SEDDS were evaluated via Transwell method using cystic fibrosis sputum. Finally, the transfection efficiency of incorporated plasmid DNA was investigated. RESULTS: Cetrimonium bromide showed the highest precipitation efficiency of 99.5 ±â€¯2.72% for the complexation of pDNA. SEDDS containing propylene glycol, Capmul PG-8, Captex 300, Captex 355, Captex 8000, Cremophor EL, Cremophor RH-40 and Brij O10 showed stable emulsions with a droplet size between 20 and 100 nm and zeta potential <-3 mV over 4 h. SEDDS demonstrated highly protective effect against enzymatic degradation and moderate cell viability on freshly obtained pulmonary tissue. The pDNA-cetrimonium complex incorporated into SEDDS revealed a log PSEDDS/water of about 2. A concentration of 0.879 ±â€¯0.103 U/g alkaline phosphatase was found in the sputum of cystic fibrosis patients. SEDDS containing 1,2-dipalmitoyl-sn-glycero-3-phosphate monosodium salt showed a high potential of changing the zeta potential by applying isolated alkaline phosphatase as well as cystic fibrosis sputum along with high mucus permeating properties. Formulation C demonstrated the highest transfection efficiency with a 7.2-fold increased fluorescence intensity compared to naked pDNA. CONCLUSION: The novel developed zeta potential changing SEDDS are opening versatile opportunities for the treatment of cystic fibrosis caused by gene mutation.

Development of self-emulsifying drug delivery systems (SEDDS) for ciprofloxacin with improved mucus permeating properties.

The aim of this study was to develop a self-emulsifying drug delivery system (SEDDS) containing the fluoroquinolone antibiotic ciprofloxacin (CIP) exhibiting highly mucus permeating properties and antimicrobial activity in in vitro models. Various SEDDS formulations were developed and evaluated regarding droplet size, polydispersity index, zeta potential and formulation stability. Furthermore, SEDDS permeating properties were investigated in porcine intestinal mucus, as well as in cystic fibrosis (CF) sputum freshly collected from CF patients using Transwell® setup and single particle tracking (SPT), respectively. In order to evaluate antibacterial activity in an in vitro model against Staphylococcus aureus and other pathogens, minimum inhibitory concentrations (MIC) and time-kill curves were determined. In addition, in vitro release of ciprofloxacin and cytotoxicity studies were conducted. The preselected formulations F1 and F11 exhibited a mean droplet size of 79 nm and 25 nm, respectively, and a negative zeta potential. SEDDS containing CIP exhibit improved ability to permeate porcine intestinal mucus and CF sputum. After 4 h, F1-CIP formulation resulted in a 1.6 - fold and F11-CIP a 2.0 - fold higher amount of permeated ciprofloxacin through the sputum layer with respect to free CIP. Moreover, the antimicrobial activity of F11-CIP against S. aureus was higher than that of free CIP. According to these results, SEDDS formulations should be taken into consideration as promising delivery systems for the treatment of pulmonary infections accompanied by mucus dysfunction.