Spray-Dried Monoclonal Antibody Suspension for High-Concentration and Low-Viscosity Subcutaneous Injection.

Administration of highly concentrated monoclonal antibodies (mAbs) through injection is often not possible as the viscosity can be readily above 50 mPa·s when the concentration exceeds 150 mg/mL. Besides, highly concentrated mAb solutions always exhibit increased aggregation propensity and lower stability, which raise the difficulty for the successful development of highly concentrated mAb formulations. We hereby explored the possibility of suspension as another formulation form for high-concentration proteins to reduce viscosity and maintain stability. Specifically, we demonstrated that spray drying can serve as a process to prepare particles for suspension. Particles prepared from formulations with different mAb/trehalose mass ratios displayed good physical stability and antibody binding affinity, as indicated by circular dichroism, fluorescence spectroscopy, and surface plasmon resonance (SPR)-based bioassay analyses. During spray drying, a surface tension-dominated enrichment of mAb on the particle surface was observed, but this did not show a significant negative impact on mAb stability. Spray-dried particles were subsequently suspended into benzyl benzoate, and the resulting suspension showed good stability and a lower viscosity when compared to its counterpart solution. Furthermore, mAbs recovered from the suspension maintained their conformational structure. Our study demonstrated that the suspension displayed low viscosity and good physical stability, so it may offer novel opportunities for the preparation of highly concentrated protein formulations.

In vitro evaluation of innovative light-responsive nanoparticles for controlled drug release in intestinal PDT.

Nanoparticles (NP) have gained importance as drug delivery systems for pharmaceutical challenging drugs. Their size properties allow passive targeting of cancer tissue by exploiting the enhanced permeability and retention (EPR) effect. Furthermore, surface modifications enable an active drug targeting for diseased regions in the human body. Besides the advantages, the drug release from commonly used biodegradable NP is mostly depending on physiological circumstances. Hence, there is a need for a more controllable drug release. The use of light-responsive polymers is an innovative conception enabling a more distinct drug release by an external light stimulus. The idea provides potential for an increase in efficiency and safety of local therapies. In this study, innovative light-sensitive NP were investigated for a photodynamic therapy (PDT) of gastrointestinal tumors. Nanoparticles based on a newly developed light-responsive polycarbonate (LrPC) and poly(lactic-co-glycolic-acid) (PLGA) were loaded with the approved photosensitizer 5,10,15,20-tetrakis(m-hydroxyphenyl)chlorin (mTHPC). Mucus penetrating properties were obtained by surface PEGylation of the nanoparticles either by using LrPC in combination with a PEGylated PLA (PEG-PLA) or by a combination with PEGylated LrPC (LrPC-PEG). Cytotoxic potential in dependency of a light-induced drug release was investigated in different cytotoxicity assays. Intracellular accumulation in mucus producing colon-carcinoma cell line HT-29-MTX was analysed by HPLC and confocal laser microscopy.

The impact of gastrointestinal mucus on nanoparticle penetration - in vitro evaluation of mucus-penetrating nanoparticles for photodynamic therapy.

Over the last years nanoparticles (NP) have become a promising vehicle as drug delivery systems for photodynamic therapy (PDT), combining the advantages of an effective drug transport to the target cells and the reduction of undesired side effects. The in vitro evaluation of new nanoparticulate formulations has become a rising problem since cell culture models differ from the in vivo situation of the human body to a large extent. Particularly, in case of gastrointestinal tumors, after peroral application nanoparticles are challenged by overcoming the mucus layer as a first physical barrier before reaching the target cells, an aspect often neglected in literature. However, the presence of mucus is crucial for in vitro models to evaluate mucus-penetrating potential of surface-modified nanoparticulate drug carrier systems. Biodegradable poly(dl-lactide-co-glycolide) (PLGA) NP loaded with the model photosensitizer 5,10,15,20-tetrakis(m-hydroxyphenyl)porphyrin (mTHPP) were surface modified with either poly(ethylene glycol) (PEG) or chitosan (CS) to gain mucus-penetrating or mucoadhesive particle properties. All NP systems were compared to each other and to free mTHPP regarding cytotoxicity and cellular uptake in HT-29 cells and mucus producing HT-29-MTX cells. For PEGylated mTHPP-PLGA-PEG-NP a significantly higher accumulation was obtained in HT-29-MTX cells compared to all other tested nanoparticles and the free drug. Additionally, a mucus-containing Transwell® model, consisting of HT-29-MTX cells, confirmed these results, representing a promising in vitro screening method for mucus-penetrating particle properties.

Light-Responsive Serinol-Based Polycarbonate and Polyester as Degradable Scaffolds.

Stimuli-responsive self-immolative aliphatic polycarbonates (APCs) and polyesters (APEs) have attractive advantages for biomedical and pharmaceutical applications. In the present work, polycondensation of o-nitrobenzyl-protected serinol was explored as a simple route to obtain light-responsive polycarbonate (LrPC) and polyester (LrPE). By exposure to UV light, these polymers decomposed rapidly and completely into oligomers and small molecules, as detected by size exclusion chromatography (SEC), UV/vis, and 1H nuclear magnetic resonance (NMR) spectroscopies. The degradation mechanism of serinol-based APC and APE was investigated with the help of the Boc-protected model APC and APE, showing that the APC underwent intramolecular cyclization, accompanied by intermolecular transcarbamation, and degraded into oxazolidinone and 2-aminopropanol terminated oligourethanes. Different from APC, the degradation process of serinol-based APE has been proven by electrospray ionization time-of-flight mass spectrometry (ESI-ToF-MS) to follow intramolecular cyclization of the functional amine group with the remote ester group, forming a ten-membered cyclic degradation compound. Further processing of the serinol-based polymers was performed by preparation of nanoparticles (NP). With light-responsive characteristics, a drug delivery system could be potentially obtained enabling a controllable drug release. Based on this strategy, a variety of self-immolative polymers responsive to different triggers can be prepared by polycondensation without the limit of ring-opening polymerization and will expand the family of biodegradable polymers.

Light-responsive nanoparticles based on new polycarbonate polymers as innovative drug delivery systems for photosensitizers in PDT.

Nanoparticles based on biodegradable polymers are well-known as approved carrier systems for a diversity of drugs. Despite their advantages, such as the option of an active drug targeting or the physicochemical protection of instable payloads, the controlled drug release often underlies intra- and interindividual influences and is therefore difficult to predict. To circumvent this limitation, the release behavior can be optimized using light-responsive materials for the nanoparticle preparation. The resulting light-responsive nanoparticles are able to release the embedded drug after an external light-stimulus, thereby increasing efficacy and safety of the therapy. In the present study light-responsive self-immolative polymers were used for the nanoparticle manufacturing. Light-responsive polycarbonates (LrPC) as well as PEGylated LrPC (LrPC-PEG) were synthesized via ring-opening polymerization of trimethylene carbonate-based monomers and fully physico-chemically characterized. Light-responsive nano formulations were obtained by blending LrPC or (LrPC-PEG) with the FDA-approved polymer poly(DL-lactide-co-glycolide) (PLGA). The nanoparticles were loaded with the photosensitizer 5,10,15,20-tetrakis(m-hydroxyphenyl)chlorin (mTHPC). The light-induced nanoparticle degradation was analyzed as well as the drug release behavior with and without illumination. Furthermore, biological safety of the degradation products was investigated in an in vitro cell culture study.

Use of Light-Degradable Aliphatic Polycarbonate Nanoparticles As Drug Carrier for Photosensitizer.

Aliphatic poly(carbonate)s (APCs) with rapid and controlled degradation upon specific stimulation have great advantages for a variety of biomedical and pharmaceutical applications. In the present work, we reported a new poly(trimethylene carbonate) (PTMC)-based copolymer containing multiple 4,5-dimethoxy-2-nitrobenzyl photo cleavable groups as pendent chains. The six-membered light-responsive cyclic carbonate monomer (LrM) was first prepared from 2-(hydroxymethyl)-2-methylpropane-1,3-diol and 4,5-dimethoxy-2-nitrobenzyl alcohol and then copolymerized with trimethylene carbonate (TMC) by 1,8-diazabicyclo(5.4.0)undec-7-ene (DBU) catalyzed ring-opening polymerization (ROP) to afford the light-responsive polycarbonate (LrPC). The light-triggered decomposition of LrM and LrPC was studied by NMR, UV/vis spectroscopy, and size exclusion chromatography (SEC), as well as ESI-ToF mass spectrometry. Stable monodisperse nanoparticles with hydrodynamic diameter of 100 nm could be formulated from 25% LrPC and 75% poly(lactide- co-glycolide) (PLGA) and applied for the encapsulation of temoporfin. Upon irradiation with UV light these particles displayed a significant decrease of the particle countrate and increased the release rate of temoporfin in comparison to standard PLGA nanoparticles. This work demonstrated that a combination of encapsulation of photosensitizer and light degradation using light-responsive polymers is suitable to enhance photodynamic therapy (PDT).

Mucus-penetrating nanoparticles: Promising drug delivery systems for the photodynamic therapy of intestinal cancer.

Photodynamic therapy (PDT) is an auspicious therapy approach for the treatment of cancer. Despite its numerous benefits, the drug delivery of the used photosensitizer (PS) to target locations inside the human body remains a main therapy challenge, since the standard intravenous PS injection often causes systemic side-effects. To circumvent this therapy drawback, the oral application represents a promising administration alternative. Especially for the treatment of intestinal cancer it offers the possibility of a local treatment with a reduced likelihood for adverse drug reactions. To establish a suitable drug delivery system for intestinal PDT, we developed nanoparticles (NP) of the biodegradable and biocompatible polymer poly(lactic-co-glycolic) acid (PLGA), loaded with the model PS 5,10,15,20-tetrakis(m-hydroxyphenyl)porphyrin (mTHPP). By functionalizing the particle surface with either poly(ethylene glycol) (PEG) or chitosan (CS), mucus-penetrating or mucoadhesive properties were obtained. These particle characteristics are important to enable an overcoming of the intestinal mucus barrier and thus lead to a PS accumulation close to and in the target cells. In permeation studies with a biosimilar mucus and in cell culture experiments with mucus-covered Caco-2 cells, PEG-modified NP were identified as a superior drug vehicle for an intestinal PDT, compared to surface unmodified or mucoadhesive NP.

Quantitative detection of caffeine in human skin by confocal Raman spectroscopy--A systematic in vitro validation study.

For rational development and evaluation of dermal drug delivery, the knowledge of rate and extent of substance penetration into the human skin is essential. However, current analytical procedures are destructive, labor intense and lack a defined spatial resolution. In this context, confocal Raman microscopy bares the potential to overcome current limitations in drug depth profiling. Confocal Raman microscopy already proved its suitability for the acquisition of qualitative penetration profiles, but a comprehensive investigation regarding its suitability for quantitative measurements inside the human skin is still missing. In this work, we present a systematic validation study to deploy confocal Raman microscopy for quantitative drug depth profiling in human skin. After we validated our Raman microscopic setup, we successfully established an experimental procedure that allows correlating the Raman signal of a model drug with its controlled concentration in human skin. To overcome current drawbacks in drug depth profiling, we evaluated different modes of peak correlation for quantitative Raman measurements and offer a suitable operating procedure for quantitative drug depth profiling in human skin. In conclusion, we successfully demonstrate the potential of confocal Raman microscopy for quantitative drug depth profiling in human skin as valuable alternative to destructive state-of-the-art techniques.

Combining confocal Raman microscopy and freeze-drying for quantification of substance penetration into human skin.

In the area of dermatological research, the knowledge of rate and extent of substance penetration into the human skin is essential not only for evaluation of therapeutics, but also for risk assessment of chemicals and cosmetic ingredients. Recently, confocal Raman microscopy emerged as a novel analytical technique for analysis of substance skin penetration. In contrast to destructive drug extraction and quantification, the technique is non-destructive and provides high spatial resolution in three dimensions. However, the generation of time-resolved concentration depth profiles is restrained by ongoing diffusion of the penetrating substance during analysis. To prevent that, substance diffusion in excised human skin can instantly be stopped at defined time points by freeze-drying the sample. Thus, combining sample preparation by freeze-drying with drug quantification by confocal Raman microscopy yields a novel analytical platform for non-invasive and quantitative in vitro analysis of substance skin penetration. This work presents the first proof-of-concept study for non-invasive quantitative substance depth profiling in freeze-dried excised human stratum corneum by confocal Raman microscopy.