Influence of chitosan and polycarbophil on permeation of a model hydrophilic drug into the urinary bladder wall

Influence of dispersions of mucoadhesive polymers chitosan and polycarbophil on permeability properties of urinary bladder was investigated in vitro on isolated porcine urinary bladder. Pipemidic acid as a model hydrophilic drug was used. Its distribution in the bladder wall was determined from actual tissue concentrations by a method based on sectioning of frozen tissue and extraction of tissue slices. Pipemidic acid tissue concentration versus tissue depth profiles were evaluated by a diffusion model assuming constant diffusion coefficient. Increase in bladder wall permeability was observed in the presence of both polymers. Apparent permeability (mean+/-S.D.) of urinary bladder wall was increased 2.7+/-2.9 and 2.8+/-2.0 times for chitosan, and 2.3+/-2.0 and 4.3+/-4.2 times for polycarbophil at 0.5 and 1.0%, w/v polymer concentration, respectively. This increase is a consequence of the increased permeability of urothelium. These findings support investigations on application of chitosan and polycarbophil in development of mucoadhesive intravesical drug delivery systems. Experimental model may be applied to evaluate the results of experiments with drugs used in intravesical therapy.     

Intravesical drug delivery. Pharmacokinetic and clinical considerations.

Intravesical drug administration is widely used in the treatment of patients with superficial bladder cancer, and aims to optimise drug delivery in the vicinity of the tumour and reduce systemic availability. The most commonly employed intravesical agents in patients with superficial bladder cancer are mitomycin (mitomycin C), thiotepa, ethoglucid (ethoglucid), anthracyclines such as doxorubicin, bacille Calmette-Guérin (BCG) and, more recently, taxol and the new mitomycin derivative KW-2149. Recurrence rates in patients with superficial bladder cancer have been substantially reduced by combined transurethral resection and intravesical pharmacotherapy. The high concentration of cytotoxics in urine and tumour tissue explain the high efficacy rates. Furthermore, the low systemic availability of most intravesical agents is consistent with the low frequency of acute and delayed systemic adverse effects. Systemic toxicity is almost negligible, except in the case of thiotepa, and local toxicity is transient and tolerable. Pharmacokinetic models of drug absorption from the bladder have been developed, both in animals and humans. These have led to the identification of optimal intravesical treatment regimens.     

Permeability of pig urinary bladder wall: time and concentration dependent effect of chitosan

Chitosan in 0.5% w/v concentration enhanced the permeability of the isolated pig urinary bladder wall by desquamation of the urothelium as ascertained in our previous study. The aim of the present work was to determine the time and concentration dependence of chitosan's effect on the permeation of a model drug into the bladder wall and to establish if the mechanism of permeation enhancement depends on the concentration of chitosan used. In the permeability studies performed by the use of diffusion cells, transport of a model drug moxifloxacin into the isolated pig urinary bladder wall was determined. For morphological observations of the urothelium in response to chitosan treatment scanning and transmission electron microscopy were applied. Within 90 min the effect of chitosan on the tissue amounts of moxifloxacin gradually increased and approached its plateau. In one hour even 0.0005% w/v dispersion of chitosan significantly enhanced the permeability of the pig urinary bladder wall for the model drug and at 0.001% w/v concentration the maximal effect on the tissue permeability was achieved. All concentrations of chitosan that significantly enhanced the permeability of the bladder wall triggered necrosis of superficial cells or desquamation of the urothelium. However, at lower concentrations and shorter exposure times the damage of the urothelium was limited to the changes in tight junctions. Chitosan was ascertained to increase the permeation of moxifloxacin into the urinary bladder wall in a time and concentration dependent manner.     

Intravesical Treatments of Bladder Cancer: Review

For bladder cancer, intravesical chemo/immunotherapy is widely used as adjuvant therapies after surgical transurethal resection, while systemic therapy is typically reserved for higher stage, muscle-invading, or metastatic diseases. The goal of intravesical therapy is to eradicate existing or residual tumors through direct cytoablation or immunostimulation. The unique properties of the urinary bladder render it a fertile ground for evaluating additional novel experimental approaches to regional therapy, including iontophoresis/electrophoresis, local hyperthermia, co-administration of permeation enhancers, bioadhesive carriers, magnetic-targeted particles and gene therapy. Furthermore, due to its unique anatomical properties, the drug concentration-time profiles in various layers of bladder tissues during and after intravesical therapy can be described by mathematical models comprised of drug disposition and transport kinetic parameters. The drug delivery data, in turn, can be combined with the effective drug exposure to infer treatment efficacy and thereby assists the selection of optimal regimens. To our knowledge, intravesical therapy of bladder cancer represents the first example where computational pharmacological approach was used to design, and successfully predicted the outcome of, a randomized phase III trial (using mitomycin C). This review summarizes the pharmacological principles and the current status of intravesical therapy, and the application of computation to optimize the drug delivery to target sites and the treatment efficacy.     

Sustained Intravesical Drug Delivery Using Thermosensitive Hydrogel

PURPOSE: Direct instillation of drug solutions into the bladder through a urethral catheter (i.e., intravesical therapy) evades systemic adverse effects of drugs used for bladder diseases. However, conventional vehicles for these drugs fail to extend duration of drug exposure in the bladder beyond the first voiding of urine postinstillation. The current study seeks to overcome the aforementioned inherent limitation of intravesical drug administration by using thermosensitive hydrogel as a matrix for sustained intravesical drug delivery. METHODS: Under halothane anesthesia, normal adult female Sprague-Dawley rats were catheterized with PE-50 tubing to instill either 0.02% w/v solution of fluorescein isothiocyanate (FITC) or the same amount of FITC in a 30% w/v dispersion of thermosensitive [Poly(ethylene glycol)-Poly[lactic acid-co-glycolic acid]-Poly(ethylene glycol)) (PEG-PLGA-PEG) polymer in a 0.1 M phosphate buffer. After instillations, rats were kept in metabolic cages for urine collection. Fluorescence emanating from FITC was measured in the urine at various time points up to 24 h after instillation. A rat model of cyclophosphamide-induced cystitis was chosen for the efficacy study using misoprostol as a model drug entrapped in the thermosensitive hydrogel in place of FITC. Efficacy of hydrogel containing misoprostol was compared against rat groups instilled with saline, hydrogel, and misoprostol independently. RESULTS: Prolonged drug exposure to the bladder afforded by hydrogel was evident from the time course of FITC elimination in the urine and by the green fluorescence of FITC seen at the bladder surface when isolated 24 h after instillation. Rats instilled with free FITC voided almost all of the fluorescence in the urine within the first 8 h, whereas rats instilled with hydrogel encapsulated FITC showed sustained release up to 24 h after instillation. Using a cyclophosphamide-induced cystitis model, rats instilled with misoprostol, a synthetic PGE1 analog, showed significantly reduced frequency of urine voiding (p < 0.05) as compared to the rats instilled with saline. Histological examination of the urothelium showed near normal morphology in rats instilled with misoprostol in hydrogel, whereas extensive tissue damage was observed in rats instilled with saline. CONCLUSION: Our study showed that PEG-PLGA-PEG polymer could be used as a viable sustained drug delivery system for intravesical therapy of diseases of the bladder such as cystitis using misoprostol.     

Strategies to improve drug delivery in bladder cancer therapy

Bladder cancer is the ninth most common malignancy in the world featuring very high gender variability in occurrence. Current options for bladder cancer therapy include surgery, immunotherapy, chemotherapy and radiotherapy with a trend towards multimodal treatments. However, successful management remains a challenge for urologists and oncologists because of the high risk for recurrence and progression. Particularly in the field of bladder cancer chemotherapy, efficacy of treatment might be improved by advanced drug delivery strategies aimed at prolonged residence time within the bladder cavity and increased permeability of the bladder wall during intravesical instillation. Moreover, a deeper understanding of the biology of bladder carcinogenesis and malignant progression stimulated the development of a new generation of anticancer drugs for targeted therapies that might result in increased treatment specificity together with lower toxic potential and higher therapeutic indices. This review discusses the available strategies for ‘targeted therapy’, focusing on molecular targets, and for ‘controlled delivery’, comprising all other approaches towards improved drug delivery.     

Microemulsion-based delivery of triamcinolone acetonide to posterior segment of eye using chitosan and butter oil as permeation enhancer: an in vitro and in vivo investigation

The aim of the study was to formulate a microemulsion (ME) using chitosan (CH) and the butter oil (BO) as a permeation enhancer for targeting drug to the posterior segment of the eye, via topical route. Triamcinolone acetonide (TA) was selected as the model drug since it undergoes extensive first-pass metabolism, leading to poor oral bioavailability of 23%. For optimisation of BO concentration, different ratios of TA:BO were prepared by simple physical mixing in the ratio of 1:9 to 9:1 and diffusion study was performed. MEs containing TA, TA:BO and TA CH ME were formulated by water titration method. Globule sizes of TA ME, TA:BO ME and TA CH ME were found to be 66.06?±?0.32?nm, 78.52?±?1.50?nm and 97.30?±?2.50?nm, respectively. In ex vivo diffusion studies using goats eye, TA:BO ME (31.33?±?0.46 and 33.98?±?0.23) and TA CH ME (24.10?±?0.41 and 27.00?±?0.18) showed higher percentage of drug diffusion in comparison to TA ME (13.29?±?0.41and 15.56?±?0.34) and TA solution (8.20?±?1.04 and 10.39?±?0.22) in presence and in absence of vitreous humour. Fluorescence intensity of coumarin-6 (as a marker) loaded ME with BO and CH was found to be higher, confirming their role in altering membrane permeability and facilitating coumarin-6 diffusion to the posterior chamber. Overall, it was concluded that BO enhances the bioavailability of TA across the retina, thereby proving its potential as permeation enhancer in facilitating drug delivery to the posterior segment of the eye.     

The in vitro rabbit whole bladder as a model to investigate the urothelial transport of anticancer agents: The ONCOFID-P paradigm

Intravesical instillation of BCG or anticancer agents after transurethral resection is currently considered a standard of therapy. However, this approach is basically empirical; none of the anticancer agents used in this setting was specifically formulated for intravesical therapy. Moreover, concern is raised by the kinetic features of water soluble drugs, because of poor transport across the mucosal barrier, or of liphophylic compounds, for the increased risks of systemic toxicity. A need exists to improve the pre-clinical and clinical approaches used at present to test anticancer agents undergoing specific development for intravesical use. We used in vitro rabbit whole bladders as a new pre-clinical model to investigate the kinetics of locally administered anticancer agents. In this study, we investigated the rate of urothelial transport of a novel paclitaxel derivative, Oncofid-P. Male New Zealand albino rabbits were used. Bladders were rapidly explanted, filled with vehicle alone or vehicle containing graded concentrations of Oncofid-P, and kept for various times under standardized incubation conditions. At the end of experiments, drug concentrations were assessed by high-pressure-liquid-chromatography technique in the intravesical and external bath solutions, as well as in bladder wall homogenates. We found that less than 1% of the drug additioned to the intravesical solution is recovered within the bladder wall in the form of paclitaxel; experiments carried out collecting different areas from the same bladders showed that Oncofid-P is uniformly distributed over the internal surface of bladder mucosa. Isolated rabbit bladders may be a useful pre-clinical model to investigate the rate of transport of chemotherapeutic agents administered by intravesical route. In this paradigm, Oncofid-P displays a kinetic profile that is predictive of local activity over the whole urothelial surface, and low or absent systemic absorption.     

Thermosensitive Hydrogels Composed of Hyaluronic Acid and Gelatin as Carriers for the Intravesical Administration of Cisplatin

The aim of this work was to evaluate the use of thermosensitive hydrogels for intravesical cisplatin delivery into the bladder. Poly(N-isopropylacrylamide) (PNIPAM) was grafted onto hyaluronic acid (HA) to synthesize an HPN copolymer, which was further grafted with gelatin to form an HPNG copolymer. A 3% concentration of HPN and HPNG was sufficient to exert a thermosensitive response, whereas a concentration of 8% was needed for PNIPAM to form the hydrogel. The physicochemical and drug delivery properties were examined by scanning electron microscopy (SEM), the lower critical solution temperature (LCST), hydration ratio, and in vitro cisplatin release. The incorporation of HA and gelatin produced a different microstructure compared to the parent PNIPAM hydrogel. Gelatin conjugation increased the fibrous structure in the matrix. The LCSTs of PNIPAM, HPN, and HPNG were 32.3, 32.0, and 30.7°C, respectively. The copolymers showed an eightfold increase in the hydration capacity compared to PNIPAM, with no significant difference in values between HPN and HPNG. The release of cisplatin from an aqueous solution (control) was nearly complete after 8 h, compared to 85, 80, and 52% release from PNIPAM, HPN, and HPNG, respectively. In vivo evaluation of cisplatin levels in bladder tissues was performed following intravesical instillation in rats. When the dwell time was extended to 6 h, PNIPAM showed a sevenfold enhancement in the drug concentration in the bladder wall. HPNG also showed a twofold increase in the drug concentration. The administration of cisplatin by the HPN carrier did not change the drug accumulation compared to the control. Confocal laser scanning microscopic results confirmed the trend of drug absorption from various systems. A histological examination showed no adverse change in the urothelium with HPN or HPNG application. PNIPAM caused partial desquamation of umbrella cells. The thermosensitive hydrogels prepared in this study may be promising carriers for targeted drug delivery to the bladder.     

Novel in-situ gel for intravesical administration of ketorolac

The urinary bladder stores urine until the time of urination. Systemic administration of drugs to treat bladder diseases faces several limitations. Therefore, intravesical drug delivery is a promising alternative route of administration. An in-situ gel is used to form a gel inside the bladder cavity and ensure continuous release of the drug even after urination. The objective of the present study was to optimize an in-situ gel formulation of poloxamer and chitosan for intravesical delivery of ketorolac tromethamine. The gelling temperature of the prepared combinations ranged from 20.67 to 25.8?°C. In-vitro release of KT was sustained for up to 7?h using a poloxamer concentration ranging from 17% to 19% and a chitosan concentration ranging from 1% to 2%. Design-Expert® 10 was used to select the optimized formulation (poloxamer/chitosan 17/1.589% w/w) which significantly (p?<?0.05) extended the drug release more than each polymer alone. An ex-vivo study showed the ability of the optimized formulation to sustain drug release after emptying two times to mimic urination. Furthermore, the formed gel adhered to the bladder tissue throughout the time period of the experiment. Intravesical administration of the optimized formulation to rabbits via catheter showed no obstruction of urine flow and continuous release of the drug for 12?h.     

Pharmaceutical development and clinical effectiveness of a novel gel technology for transdermal drug delivery

Transdermal gels are designed to deliver sustained drug amounts, resulting in systemically consistent levels. They represent an improvement compared with transdermal delivery by patches because they offer more dosage flexibility, less irritation potential and a better cosmetic appearance. Advanced Transdermal Delivery (ATD) gel technology was developed in order to provide enhanced passive skin permeation of various active drugs for the treatment of many conditions, including hypogonadism, female sexual dysfunction, postmenopausal symptoms, overactive bladder and anxiety. The technology consists of a combination of solvent systems and permeation enhancers enabling systemic drug delivery, and is covered by many patents. Pharmaceutical development of formulations based on the technology allowed optimisation of physicochemical parameters (rheological profile, pH) as well as skin permeation properties (type and concentration of permeation enhancers, thermodynamic activity of the drug). This gel technology has demonstrated to be efficient for many drugs, as shown in the preclinical and clinical pharmacokinetic studies presented in this technology evaluation.     

Pharmaceutical development and clinical effectiveness of a novel gel technology for transdermal drug delivery

Transdermal gels are designed to deliver sustained drug amounts, resulting in systemically consistent levels. They represent an improvement compared with transdermal delivery by patches because they offer more dosage flexibility, less irritation potential and a better cosmetic appearance. Advanced Transdermal Delivery? (ATD?) gel technology was developed in order to provide enhanced passive skin permeation of various active drugs for the treatment of many conditions, including hypogonadism, female sexual dysfunction, postmenopausal symptoms, overactive bladder and anxiety. The technology consists of a combination of solvent systems and permeation enhancers enabling systemic drug delivery, and is covered by many patents. Pharmaceutical development of formulations based on the technology allowed optimisation of physicochemical parameters (rheological profile, pH) as well as skin permeation properties (type and concentration of permeation enhancers, thermodynamic activity of the drug). This gel technology has demonstrated to be efficient for many drugs, as shown in the preclinical and clinical pharmacokinetic studies presented in this technology evaluation.     

A Method to Study Drug Concentration–Depth Profiles in Tissues: Mitomycin C in Dog Bladder Wall

Determination of the depth of penetration of locally applied drug therapy and evaluation of possible mechanisms of drug transport require knowledge of drug concentration-versus-tissues depth profiles. A method to determine the drug concentration–depth profile is needed. We have devised such a method and used it to determine the penetration of mitomycin C (MMC) in the dog bladder wall after intravesical drug instillation. This method is based on sectioning of frozen tissue into 40-µm segments, followed by drug extraction and high-pressure liquid chromatography analysis. Tissue concentrations could be detected with a sensitivity of 1 ng/sample, or 20 ng/g for tissue samples of approximately 2 × 2 cm. This sensitivity was sufficient to describe the penetration of MMC in the bladder wall of dogs, using an identical instillation technique, dwell time, and MMC concentration as in human patients. Tissue concentrations were expressed relative to tissue weight or tissue protein contents. For MMC, standardization to tissue weight yielded a better mathematical fit of the concentration-versus-depth profiles than standardization to protein content. The time interval between tissue harvesting and freezing was critical. The MMC concentration at the urothelial side of dog bladders was 2- to 10-fold higher in samples processed immediately after harvesting, compared to samples processed after 1 hr or longer. This significant decrease was not due to drug metabolism in situ. In separate in vitro experiments, we found that the degradation of MMC in 8% tissue homogenate was relatively slow, with only a 30% decline in concentration over 24 hr. We speculate that the decrease in concentration was due to passive diffusion of MMC, away from the urothelial side. In summary, the present study demonstrates that determination of drug penetration into tissues in vivo is feasible.     

Computational analysis of drug transport in tumor microenvironment as a critical compartment for nanotherapeutic pharmacokinetics

Over the last decade, nanotherapeutics gained increasingly important role in drug delivery because of their frequently beneficial pharmacokinetics (PK) and lower toxicity when compared to classical systemic drug delivery. In view of therapeutic payload delivery, convective transport is crucial for systemic distribution via circulatory system, but the target domain is tissue outside vessels where transport is governed by diffusion. Here, we have computationally investigated the understudied interplay of physical transports to characterize PK of payload of nanotherapeutics. The analysis of human vasculature tree showed that convective transport is still 5 times more efficient than diffusion suggesting that circulating and payload releasing drug vectors can contribute mostly to systemic delivery. By comparing payload delivery using systemic circulation and drug vectors to microenvironment, internalized vectors were the most efficient and showed Area under the Curve almost 100 higher than in systemic delivery. The newly introduced zone of influence parameter indicated that vectors, especially internalized, lead to the largest tissue fraction covered with therapeutically significant payload concentration. The internalization to microenvironment minimizes effects of plasma domain on payload extravasation from nanotherapeutics. The computed results showed that classical PK, which mostly relies on concentration profiles in plasma, sometimes might be inadequate or not sufficient in explaining therapeutic efficacy of nanotherapeutics. These results provide a deeper look into PK of drug vectors and can help in the design of better drug delivery strategies.     

A theoretical model for transdermal drug delivery from emulsions and its dependence upon formulation

This article presents a theoretical model of transdermal drug delivery from an emulsion-type vehicle that addresses the vehicle heterogeneity and incorporates the prediction of drug transport parameters as function of the vehicle composition. The basic mass transfer model considers interfacial and diffusion resistances within the emulsion and partition/diffusion phenomena across two skin compartments in series. Drug transport parameters are predicted as follows: partition coefficients are derived from regular solutions theory, drug diffusivity in the continuous phase is computed from a free volume theory with segmental motion, and permeability of the surfactant layer around droplets is estimated based on a free surface area model. These relationships are incorporated within the basic mass transfer model, so that the overall model is able to predict temporal profiles of drug release from the vehicle and of drug concentration in plasma, as a function of vehicle composition. In this way, the proposed model provides a sound physicochemical basis to support the development of new formulations and the planning of experiments. A simulated case study regarding a nitroglycerin ointment is presented in detail, illustrating how thermodynamic and kinetic factors inherent to the emulsion vehicle can modulate drug release and subsequent systemic absorption.     

Intravesical delivery of 5‐aminolevulinic acid from water‐in‐oil nano/submicron‐emulsion systems

The present work reports on the development of water‐in‐oil (w/o) emulsions for the intravesical administration of 5‐aminolevulinic acid (ALA). The physicochemical properties of droplet size, zeta potential, and viscosity of the emulsions are characterized and the ability of the emulsions to release ALA following in vitro application is tested. The delivery systems are administered intravesically for 1 and 3 h in rats to examine the drug accumulation in bladder tissue. The mean size and zeta potential of the emulsions are 50–200 nm and ?3 to ?14 mV, respectively. The loading of ALA into the emulsions resulted in a slower and sustained release. The release extent was found to be inversely related to the droplet size of the emulsions. The emulsions did not increase the drug permeation into tissues during short exposure duration (1 h). When the dwell time was extended to 3 h, the systems showed a 2.7‐fold increase in the ALA concentration in the bladder wall. Images of confocal laser scanning microscopy demonstrated a higher and deeper fluorescence signal, with emulsion administration, as compared to the aqueous control. Intravesical emulsion delivery provides a significant advantage for drugs targeting bladder tissues. © 2009 Wiley‐Liss, Inc. and the American Pharmacists Association J Pharm Sci 99: 2375–2385, 2010     

Permeability of pig urinary bladder wall: the effect of chitosan and the role of calcium.

Chitosan is a cationic polysaccharide widely employed as an absorption enhancer. The aim of this work was to examine the effect of chitosan on the permeability of isolated pig urinary bladder wall as well as to determine the role of calcium ions in this process. Besides permeability studies, scanning electron microscopy and fluorescent microscopy were applied to get an insight into the mechanism by which chitosan increases the permeability of urinary bladder wall. Additionally, the obtained findings were compared to the mechanism proposed for Caco-2 cells. The results show that 0.5% (w/v) chitosan increases the permeability of urinary bladder wall by causing the desquamation of the urothelium. Calcium ions, when applied to the luminal surface of the urinary bladder at the same time as chitosan, decreases the effect of chitosan on permeation of the model drug moxifloxacin into the bladder wall in concentration dependent way. The desquamation of urothelium cells caused by chitosan was reduced in the presence of calcium, but not to such extent as it would be expected from the permeability studies. When present, calcium obviously interferes directly in the interactions between chitosan and the surface of urothelium.     

Visualized intravesical floating hydrogel encapsulating vaporized perfluoropentane for controlled drug release

Intravesical drug delivery is the main strategy for the treatment of bladder disorders. To reduce the relief arising from frequent intravesical instillation, mucoadhesive hydrogel was used for the controlled release of the drug. However, the viscosity of mucoadhesive gel might cause severe urinary obstruction and bladder irritation. To solve all these problems, a floating hydrogel delivery system was developed using perfluoropentane (PFP) as the floating agent. After intravesical instillation of the floating hydrogel, the increased temperature in bladder vaporized PFP, resulting in the generation of microbubbles in the hydrogel. Then, it can float in urine to avoid the urinary obstruction and bladder irritation. In this study, systematic experiments were conducted to investigate the influences of PFP vaporization on the morphology and floating ability of hydrogels. The floating process is much milder and safer than other floating methods published before. In addition, PFP had been used as contrast agent, which affiliated the monitoring of gels during the operation. Therefore, this new drug delivery system addresses the problems of conventional intravesical instillation and is promising for clinic use.     

Bladder Tissue Pharmacokinetics of Intravesical Mitomycin C and Suramin in Dogs

Suramin, at non-cytotoxic doses, reverses chemoresistance and enhances the activity of mitomycin C (MMC) in mice bearing human bladder xenograft tumors. The present study evaluated the pharmacokinetics of the intravesical suramin and MMC, alone or in combination, in dogs. Animals received either high dose suramin (20 mg/ml), low dose suramin (6 mg/ml), MMC (2 mg/ml), or combination of low dose suramin and MMC, instilled for 2 h. The dosing volume was 20 ml. All groups showed dilution of drug levels over time due to continued urine production. For single agent suramin, the results showed (a) 5% to 10% penetration into bladder tissues, (b) minimal and clinically insignificant systemic absorption (i.e., undetectable at low dose or a peak concentration that was 6,000× lower than urine concentrations), and (c) disproportionally higher drug penetration and concentrations in bladder tissues at the higher dose. Results for single agent MMC are consistent with our earlier observations. The co-administration of MMC did not alter the plasma, urine, or tissue pharmacokinetics of suramin. Adding suramin did not alter plasma or tissue pharmacokinetics of MMC, but lowered the MMC concentrations in urine by about 20%. This may be in part due to accelerated MMC degradation by co-incubation of suramin or due to variations in urine production rate (because animals were allowed for water during treatment). Suramin readily penetrates the urothelium and into deeper bladder tissues, indicating its potential utility in intravesical therapy.     

Nanoparticles for urothelium penetration and delivery of the histone deacetylase inhibitor belinostat for treatment of bladder cancer

Nearly 40% of patients with non-invasive bladder cancer will progress to invasive disease despite locally-directed therapy. Overcoming the bladder permeability barrier (BPB) is a challenge for intravesical drug delivery. Using the fluorophore coumarin (C6), we synthesized C6-loaded poly(lactide-co-glycolide) (PLGA) nanoparticles (NPs), which were surface modified with a novel cell penetrating polymer, poly(guanidinium oxanorbornene) (PGON). Addition of PGON to the NP surface improved tissue penetration by 10-fold in intravesically-treated mouse bladder and ex vivo human ureter. In addition, NP-C6-PGON significantly enhanced intracellular uptake of NPs compared to NPs without PGON. To examine biological activity, we synthesized NPs that were loaded with the histone deacetylase (HDAC) inhibitor belinostat (NP-Bel-PGON). NP-Bel-PGON exhibited a significantly lower IC50 in cultured bladder cancer cells, and sustained hyperacetylation, when compared to unencapsulated belinostat. Xenograft tumors treated with NP-Bel-PGON showed a 70% reduction in volume, and a 2.5-fold higher intratumoral acetyl-H4, when compared to tumors treated with unloaded NP-PGON.From the Clinical EditorThese authors demonstrate that PLGA nanoparticles with PGON surface functionalization result in greatly enhanced cell penetrating capabilities, and present convincing data from a mouse model of bladder cancer for increased chemotherapy efficacy.