Doris Gabriel

Polymeric photosensitizer prodrugs for photodynamic therapy

A targeting strategy based on the selective enzyme‐mediated activation of polymeric photosensitizer prodrugs (PPP) within pathological tissue has led to the development of agents with the dual ability to detect and treat cancer. Herein, a detailed study of a simple model system for these prodrugs is described. We prepared “first‐generation” PPP by directly tethering the photosensitizer (PS) pheophorbide a to poly‐(l)‐lysine via epsilon amide links and observed that by increasing the number of PS on a polymer chain, energy transfer between PS units improved leading to better quenching efficiency. Fragmentation of the PPP backbone by trypsin digestion gave rise to a pronounced fluorescence increase and to more efficient generation of reactive oxygen species upon light irradiation. In vitro tests using the T‐24 bladder carcinoma cell line and ex vivo experiments using mouse intestines illustrated the remarkable and selective ability of these PPP to fluoresce and induce phototoxicity upon enzymatic activation. This work elucidated the basic physicochemical parameters, such as water solubility and quenching/activation behavior, required for the future elaboration of more adaptable “second‐generation” PPP, in which the PS is tethered to a proteolytically stable polymer backbone via enzyme‐specific peptide linkers. This polymer architecture offers great flexibility to tailor make the PPP to target any pathological tissue known to over‐express a specific enzyme.

It is All About Proteases: From Drug Delivery to In Vivo Imaging and Photomedicine

Clinical studies provide overwhelming evidence for the importance of proteolytic imbalance and the upregulation of diverse protease classes in diseases such as cancer and arthritis. While the complex nature of proteolytic networks has hampered the development of protease inhibitors for these indications, aberrant enzyme activity could be successfully exploited for the development of proteasesensitive drug delivery systems and fluorescent in vivo imaging agents. More recently, these concepts have also been translated into photomedical applications to develop dual modality prodrugs for the simultaneous treatment and imaging of disease. After an introductory overview of proteases and their role in cancer, we present and discuss different strategies to exploit upregulated protease activity for the development of drug delivery systems, fluorescent in vivo reporter probes, and photosensitizer-prodrugs with respect to their potential and limitations. The main approaches used for targeting proteases in all three areas can be roughly divided into peptide-based and macromolecular strategies. Both involve the use of a short, peptide-based protease substrate, which is either directly tagged to the therapeutic agent or dye/quencher pair, or alternatively, serves as a linker between the polymeric carrier and a functional unit. In the latter case, the pharmacokinetic properties of peptide-based protease-sensitive prodrugs and imaging probes can be further ameliorated by the passive targeting capacity of macromolecular drug delivery systems for neoplastic and inflammatory lesions.

Thrombin-sensitive photodynamic agents: A novel strategy for selective synovectomy in rheumatoid arthritis

Protease-sensitive macromolecular prodrugs have attracted interest for bio-responsive drug delivery to sites with up-regulated proteolytic activities such as inflammatory or cancerous lesions. Here we report the development of a novel polymeric photosensitizer prodrug (T-PS) to target thrombin, a protease up-regulated in synovial tissues of rheumatoid arthritis (RA) patients, for minimally invasive photodynamic synovectomy. In T-PS, multiple photosensitizer units are tethered to a polymeric backbone via short, thrombin-cleavable peptide linkers. Photoactivity of the prodrug is efficiently impaired due to energy transfer between neighbouring photosensitizer units. T-PS activation by exogenous and endogenous thrombin induced an increase in fluorescence emission by a factor of 16 after in vitro digestion and a selective fluorescence enhancement in arthritic lesions in vivo, in a collagen-induced arthritis mouse model. In vitro studies on primary human synoviocytes showed a phototoxic effect only after enzymatic digestion of the prodrug and light irradiation, thus demonstrating the functionality of T-PS induced PDT. The developed photosensitizer prodrugs combine the passive targeting capacity of macromolecular drug delivery systems with site-selective photosensitizer release and activation. They illuminate lesions with pathologically enhanced proteolytic activity and induce cell death, subsequent to irradiation.

Improved topical delivery of tacrolimus: A novel composite hydrogel formulation for the treatment of psoriasis

We have developed a composite hydrogel for improved topical delivery of the poorly soluble drug Tacrolimus (TAC) to psoriasis lesions. TAC is efficiently solubilized in methoxy poly- (ethylene glycol) hexyl substituted poly-(lactic acid) (mPEGhexPLA) based nanocarriers. For convenient and patient-friendly topical administration, TAC loaded polymeric nanocarriers were incorporated in a Carbopol® based hydrogel, to yield a composite hydrogel formulation (TAC composite hydrogel). TAC composite hydrogel was designed to have superior pharmaceutical formulation properties, delivery efficiency and local bioavailability, compared to currently available paraffin-based TAC ointments. Composite hydrogel formulations had good local tolerance and showed no signs of immediate toxicity after repeated topical administration in healthy mice. Skin delivery of TAC composite hydrogel in an imiquimod-induced psoriasis mouse model was found to be twice as high as for the commercial formulation Protopic™, used as benchmark. TAC composite hydrogel showed significant improvement in the in vivo and histopathological features of the imiquimod-induced psoriasis model.

Selective Photodetection and Photodynamic Therapy for Prostate Cancer through Targeting of Proteolytic Activity

Frequent side effects of radical treatment modalities and the availability of novel diagnostics have raised the interest in focal therapies for localized prostate cancer. To improve the selectivity and therapeutic efficacy of such therapies, we developed a minimally invasive procedure based on a novel polymeric photosensitizer prodrug sensitive to urokinase-type plasminogen activator (uPA). The compound is inactive in its prodrug form and accumulates passively at the tumor site by the enhanced permeability and retention effect. There, the prodrug is selectively converted to its photoactive form by uPA, which is overexpressed by prostate cancer cells. Irradiation of the activated photosensitizer exerts a tumor-selective phototoxic effect. The prodrug alone (8 μmol/L) showed no toxic effect on PC-3 cells, but upon irradiation the cell viability was reduced by 90%. In vivo, after systemic administration of the prodrug, PC-3 xenografts became selectively fluorescent. This is indicative of the prodrug accumulation in the tumor and selective local enzymatic activation. Qualitative analysis of the activated compound confirmed that the enzymatic cleavage occurred selectively in the tumor, with only trace amounts in the neighboring skin or muscle. Subsequent photodynamic therapy studies showed complete tumor eradication of animals treated with light (150 J/cm2 at 665 nm) 16 hours after the injection of the prodrug (7.5 mg/kg). These promising results evidence the excellent selectivity of our prodrug with the potential to be used for both imaging and therapy for localized prostate cancer. Mol Cancer Ther; 12(3); 306–13. ©2012 AACR.

Enhanced prostate cancer targeting by modified protease sensitive photosensitizer prodrugs.

Prodrugs combining macromolecular delivery systems with site-selective drug release represent a powerful strategy to increase selectivity of anticancer agents. We have adapted this strategy to develop new polymeric photosensitizer prodrugs (PPP) sensitive to urokinase-like plasminogen activator (uPA). In these compounds (to be referred to as uPA-PPPs) multiple copies of pheophorbide a are attached to a polymeric carrier via peptide linkers that can be cleaved by uPA, a protease overexpressed in prostate cancer (PCa). uPA-PPPs are non-phototoxic in their native state but become fluorescent and produce singlet oxygen after uPA-mediated activation. In the present work, we studied the influence of side-chain modifications, molecular weight, and overall charge on the photoactivity and pharmacokinetics of uPA-PPPs. An in vitro promising candidate with convertible phototoxicity was then further investigated in vivo. Systemic administration resulted in a selective accumulation and activation of the prodrug in luciferase transfected PC-3 xenografts, resulting in a 4-fold increase in fluorescence emission over time. Irradiation of fluorescent tumors induced immediate tumor cell eradication as shown by whole animal bioluminescence imaging. PDT with uPA-PPP could therefore provide a more selective treatment of localized PCa and reduce side effects associated with current radical treatments.

Thrombin-sensitive dual fluorescence imaging and therapeutic agent for detection and treatment of synovial inflammation in murine rheumatoid arthritis

We have developed a thrombin-sensitive polymeric photosensitizer prodrug (T-PS) to selectively image and eradicate inflammatory lesions in rheumatoid arthritis (RA). Thrombin is a serine protease up-regulated in synovial tissues of rheumatoid arthritis (RA) patients. T-PS consists of a polymeric backbone, to which multiple photosensitizer (PS) units are tethered via short thrombin-cleavable peptide linkers. Fluorescence emission and phototoxicity of the prodrug are efficiently quenched due to the interaction of neighboring photosensitizer units. The prodrug is passively delivered to the inflammation site via the enhanced permeability and retention (EPR) effect. Subsequent site-selective proteolytic cleavage of the peptide linkers restores its photoactivity by increasing the mutual distance between PS. Whole animal imaging in murine collagen-induced arthritis, an experimental model of RA revealed a dose-dependent fluorescence increase in arthritic paws after systemic prodrug injection. In addition, administration of T-PS resulted in much higher fluorescence selectivity for arthritic joints as compared to the free PS. Irradiation of the arthritic joints induced light dose dependent phototoxic effects such as apoptosis, vascular damage and local hemorrhage. Long-term observations showed complete regression of the latter. Irradiated non-arthritic tissues or non-irradiated arthritic tissues showed no histological effects after photodynamic therapy with T-PS. This illustrates that T-PS can localize inflammatory lesions with excellent selectivity and induce apoptosis and vascular shut down after irradiation.

Self-assembling polymeric nanocarriers to target inflammatory lesions in ulcerative colitis

&NA; We have developed a self‐assembling polymeric nanocarrier to deliver the potent immunosuppressive drug Cyclosporine A (CsA) to inflammatory lesions in ulcerative colitis (UC) patients. Our nanocarrier has a high drug loading capacity and efficiently targets its CsA payload to the diseased tissue after local administration. Tissue drug levels were several orders of magnitude higher in animals suffering from a trinitrobenzene‐sulfonic acid (TNBS) – induced colitis, compared to healthy control animals; no drug was detectable in the plasma, underlining the localized delivery strategy. An efficient reduction in inflammation score was obtained with a CsA dose of 1 mg/mL. Therapeutic efficacy was comparable to 5‐aminosalicylic acid (5‐ASA), the positive control treatment in the TNBS‐induced colitis model. Repetitive treatment of healthy animals with CsA nanocarriers for seven days was well tolerated with no alterations in colon histology. Graphical abstract Figure. No Caption available.

Topical Administration of Spironolactone-Loaded Nanomicelles Prevents Glucocorticoid-Induced Delayed Corneal Wound Healing in Rabbits

The objective was to investigate whether mineralocorticoid receptor antagonism using a novel topical micellar formulation of spironolactone could prevent glucocorticoid-induced delayed corneal wound healing in New Zealand white rabbits. Spironolactone micelles (0.1%, w/v) with a mean number weighted diameter of 20 nm were prepared using a pegylated copolymer (mPEG-dihexPLA) and showed a preliminary stability of at least 12 months at 5 °C. Preclinical studies in New Zealand white rabbits demonstrated that the 0.1% spironolactone micellar formulation was well-tolerated since no reaction was observed in the cornea following multiple daily instillation over 5 days. As expected, the preclinical studies also confirmed that dexamethasone significantly delayed epithelial wound healing as compared to untreated control (percentage re-epithelialization after day 4: 84.6 ± 13.9% versus 99.5 ± 1.0% for the control, p < 0.05). However, the addition of the 0.1% spironolactone micellar formulation significantly improved the extent of re-epithelialization, countering the dexamethasone induced delayed wound healing with a percentage re-epithelialization that was statistically equivalent to the control (96.9 ± 7.3% versus 99.5 ± 1.0%, p > 0.05). The biodistribution study provided insight into the ocular metabolism of spironolactone and hence the relative contributions of the parent molecule and its two principal metabolites, 7α-thiomethylspironolactone and canrenone, to the observed pharmacological effects. Comparison of the efficacies of spironolactone and potassium canrenoate (a water-soluble precursor of canrenone) in overcoming the dexamethasone-induced delayed wound healing confirmed that the former had greater efficacy. The results pointed to the greater potency of 7α-thiomethylspironolactone over canrenone as a mineralocorticoid receptor antagonist, which explained its superior ability in countering the glucocorticoid-induced overactivation that was responsible for the delayed wound healing. In conclusion, the preliminary results supported the above-mentioned hypothesis suggesting that coadministration of mineralocorticoid receptor antagonists to patients under glucocorticoid therapy might prevent the deleterious effects of glucocorticoids on complex corneal wound healing processes.

Cyclosporine A-Loaded Nanocarriers for Topical Treatment of Murine Experimental Autoimmune Uveoretinitis

In the present study, tissue distribution and the therapeutic effect of topically applied cyclosporine A (CsA)-loaded methoxy-poly(ethylene-glycol)-hexyl substituted poly(lactic acid) (mPEGhexPLA) nanocarriers (ApidSOL) on experimental autoimmune uveitis (EAU) were investigated. The CsA-loaded mPEGhexPLA nanocarrier was tolerated well locally and showed no signs of immediate toxicity after repeated topical application in mice with EAU. Upon unilateral CsA treatment, CsA accumulated predominantly in the corneal and sclera-choroidal tissue of the treated eye and in lymph nodes (LN). This regimen reduced EAU severity in treated eyes compared to PBS-treated controls. This improvement was accompanied by reduced T-cell count, T-cell proliferation, and IL-2 secretion of cells from ipsilateral LN. In conclusion, topical treatment with CsA-loaded mPEGhexPLA nanocarriers significantly improves the outcome of EAU.