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Decreased inflammatory response in rat bladder after intravesical administration of capsaicin-loaded liposomes

ABSTRACT

The objective of this work was to study the reduction in the capsaicin toxicity by encapsulation in liposomes. Capsaicin was extracted from peppers and characterized with high performance liquid chromatography (HPLC). We determined the zeta potential, polydispersivity index (PdI) and vesicle size of liposomes. Wistar rats were submitted to intravesical instillation of liposomes (LIP), capsaicin (CAP) or liposomes with capsaicin (CAPLIP). After 24 hours, bladders were removed for histological analysis. Vesicle size ranged from 68 to 105 nm with PdI smaller than 0.2 and zeta potential around -30 mV. The vesicles maintained stability over the 14-day study. The histological analysis of the CAP group showed intense inflammation in almost all bladder layers, as well as ulcer formation. Conversely, the CAPLIP group showed a smooth inflammatory reaction and hyperemia. In conclusion, the liposomes effectively protected the bladder against the irritative action of capsaicin.

Key words:
capsaicin; liposomes; urinary incontinence; intravesical administration

INTRODUCTION

Capsaicin is the chemical component responsible for the spiciness of peppers belonging to genus Capsicum. This substance is primarily found in the seeds of these fruits, and in mammals it leads to irritative symptoms caused by vanilloid receptor activation, subsequent activation of peripheral terminations and the liberation of substance P and other cytokines (Nirmal et al. 2012NIRMAL J, CHUANG YC , TYAGI P, MICHAEL B and CHANCELLOR MB. 2012. Intravesical therapy for lower urinary tract symptoms. Urol Sci 23: 70-77., Barbero et al. 2008BARBERO GF, LIAZID A, PALMA M and BARROSO CG. 2008. Fast determination of capsaicinoids from peppers by high-performance liquid chromatography using a reversed phase monolithic column. Food Chem 107: 1276-1282., Petrovszki et al. 2014PETROVSZKI Z, ADAM G, KEKESI G, TUBOLY G, MORVAY Z, NAGY E, BENEDEK G and HORVATH G. 2014. The effects of juvenile capsaicin desensitization in rats: Behavioral impairments. Physiol Behav 125: 38-44., Sharma et al. 2013SHARMA SK, VIJ AS and SHARMA M. 2013. Mechanisms and clinical uses of capsaicin. Eur J Pharmacol 720: 55-62.).

This compound has been widely employed to treat urinary incontinence, a pathological condition characterized by the involuntary loss of urine that usually affects postmenopausal women (Tu et al. 2011TU FF, HELLMAN KM and BACKONJA MM. 2011. Gynecologic management of neuropathic pain. Am J Obsted Gynecol 205: 435-443., Thüroff et al. 2011THÜROFF JW, ABRAMS P, ANDERSSON KE, ARTIBANI W, CHAPPLE CR, DRAKE MJ, HAMPEL C, NEISIUS A, SCHRÖDER A and TUBARO A. 2011. EAU Guidelines on Urinary Incontinence. Eur Urol 59: 387-400.). Capsaicin is neurotoxic and disrupts conduction in type C unmyelinated sensory afferent fibers that coordinate urine excretion control. Although this sensory neuron blockage is long lasting, it is also reversible. The length and onset of action depend on the dosage and the length of exposure (Kaufman 2011KAUFMAN MR. 2011. Future Directions in Overactive Bladder Treatment. Curr Bladder Dysfunct Rep 6: 45-50. , Meel and Wyndaele 2012MEEL TDV and WYNDAELE JJ. 2012. Reproducibility of Electrical Sensory Testing in Lower Urinary Tract at Weekly Intervals in Healthy Volunteers and Women With Non-neurogenic Detrusor Overactivity. Urol 79: 526-531., Sharma et al. 2013SHARMA SK, VIJ AS and SHARMA M. 2013. Mechanisms and clinical uses of capsaicin. Eur J Pharmacol 720: 55-62.).

Intravesical capsaicin administration is an effective treatment for urinary incontinence; it minimizes systemic side effects and is not subject to first-pass metabolism. Bladder anatomy allows the drug solution to be directly instilled via a catheter (Barthelmes et al. 2011BARTHELMES J, PERERA G, HOMBACH J, DUNNHAUPT S and BERNKOP-SCHNURCH A. 2011. Development of a mucoadhesive nanoparticulate drug delivery system for a targeted drug release in the bladder. Int J Pharm 416: 339-345., Lee et al. 2011LEE WC, CHUANG YC and CHIANG P H. 2011. Safety and dose flexibility clinical evaluation of intravesical liposome in patients with interstitial cystitis or painful bladder syndrome. Kaohsiung J Med Sci 27: 437-440.). However, this treatment often causes local irritation and edema due to its effects on unmyelinated sensory afferent fibers, which are believed to signal pain and initiate inflammatory responses (Meel and Wyndaele 2012MEEL TDV and WYNDAELE JJ. 2012. Reproducibility of Electrical Sensory Testing in Lower Urinary Tract at Weekly Intervals in Healthy Volunteers and Women With Non-neurogenic Detrusor Overactivity. Urol 79: 526-531., Wyndaele et al. 2010, Cipullo et al. 2014CIPULLO LMA, COSIMATO C, FILIPPELLI A, CONTI V, IZZO V, ZULLO F and GUIDA M. 2014. Pharmacological approach to overactive bladder and urge urinary incontinence in women: an overview. Eur J Obstet Gyn R B 174: 27-34.). Alternative formulations have been proposed in order to minimize these side effects.

Capsaicin has nonpolar features; it has low solubility in biologically compatible solvents, such as buffers and saline solution. Capsaicin is usually dissolved in ethanol, vehicle that can also be irritating. Therefore, it is necessary to develop formulations that reduce adverse effects (Tyagi et al. 2004TYAGI P, CHANCELLOR MB, LI Z, GROAT WCD, YOSHOMURA N, FRASER MO and HUANG L. 2004. Urodynamic and immunhohistochemical evalution of intravesical capsaicin delivery using thermosensitive hydrogel and liposomes. J Urolology 171: 483-489.).

The development of alternative capsaicin delivery systems has received interest in recent years. One such option is the use of liposomes, which are spherical vesicles with a double lipid layer that are a popular vehicle because of their ability to encapsulate substances with varying polarity, biodegradability and biocompatibility (Peters et al. 2012PETERS KM, HASENAU DL, ANTHONY M, KAUFMAN J and KILLINGER KA. 2012. Novel Therapy with Intravesical Liposomes for Ulcerative Interstitial Cystitis/Painful Bladder Syndrome. Luts 4: 51-53.). Several studies have demonstrated the successful use of liposomes to deliver substances, including capsaicin (Rollyson et al. 2014ROLLYSON WD, STOVER CA, BROW KC, PERRY HE, STEVENSON CD, MCNEES CA, BALL JG, VALENTONIC MA and DASGUPTA P. 2014. Bioavailability of capsaicin and its implications for drug delivery. J Controll Rele 196: 96-105., GuhaSarkar and Banerjee 2010). Therefore, the aim of this work was to assess if delivering capsaicin via liposomes protected rodent bladder tissue against capsaicin-induced inflammation.

MATERIALS AND METHODS

PREPARATION OF Capsicum frutescens EXTRACT

Fresh samples from Capsicum frutescens pepper were sectioned to collect seeds and fruit skin. These products were dried at 55 °C for 24-30 h in a stove, ground and passed through a 60-mesh sieve. The obtained pepper powder was weighed and placed in separate tubes, each containing 3 g pepper powder and 10 mL acetonitrile, which were sonicated for 1 h. Finally, the material was filtered, and the solvent evaporated.

Capsaicinoids were quantified according to the method published by Karnka et al. (2002). A C-8 precolumn was conditioned with 0.5 mL MilliQ water, then with 0.5 mL methanol followed by 0.5 mL acetonitrile. Next, 0.5 mL aliquots were diluted in the conditioned precolumn and washed three consecutive times with 0.5 mL acetonitrile. The material obtained in this process was filtered through a membrane with 0.45 mm porosity (Millipore(r)) and placed in vials. The samples were then analyzed by HPLC using a C-8 column and 20 mL samples, which were eluted with acetonitrile as the mobile phase.

LIPOSOME PREPARATION

Liposomes were generated using phosphatidylcholine 75 % (Nanosolv/Lipoid GMBH/part 776095-1/Gerbras) as the phospholipid (PL). PL and capsaicin solution (4.6 mg.mL-1) were homogenized in a 1:10 molar ratio in ethanol. The final concentration of capsaicin was 3 mM. The ethanol was removed from the mixture by rotary evaporation to form thin lipid films on the flask wall. The dried lipid film was hydrated in 50 mL phosphate buffer (Avelino and Cruz 2000AVELINO A and CRUZ F. 2000. Peptide immunoreactivity and ultrastructure of rat urinary bladder nerve fibers after topical desensitization by capsaicin or resiniferatoxin. Auton Neurosci 86: 37-46., Frézard and Schettini 2005FRÉZARD F and SCHETTINI DA. 2005. Liposomes: physicochemical and pharmacological properties, applications in antimony-based chemotherapy. Quím Nova 28: 511-518.). The final dispersion (CAPLIP) was filtered through a nylon membrane with 0.22-mm pores (Millipore(r)). The same procedure was performed without capsaicin to prepare the control formulation (LIP).

LIPOSOME CHARACTERIZATION

The zeta potentials (Zetasizer Nanoseries, Malvern Instruments, UK) of LIP and CAPLIP were determined by measuring the electrophoretic mobility of the charged particles at 25 °C. The samples were diluted in distilled water at a ratio of 1:10, and the procedure was performed 24 h, 7 and 14 days after liposome preparation.

The size and polydispersity index of LIP and CAPLIP were assessed by dynamic light scattering (DLS) using a computerized system (Malvern Zetasizer Nanoseries (Nano-ZS - Malvern, UK). The samples were diluted at a ratio of 1:10 with distilled water and analyzed at 633 nm at room temperature (25 °C).

The morphological characterization of LIP and CAPLIP was performed by transmission electron microscopy. Liposome suspensions were imaged, using a transmission electron microscope (TEM) JEOL (JEM-2010) microscope at 200 kV. A few droplets of an ultrasonically dispersed suspension of lipossomes in water were deposited on a copper grid with lacey ultrathin carbon film (400 mesh) and then dried at ambient conditions for TEM characterization.

An in vitro drug delivery study was performed at 37 °C using dynamic dialysis (Zhu et al. 2014ZHU Y, PENG W, ZHANG J, WANG M, FIREMPONG CK, FENG C, LIU H, XU X and YU J. 2014. Enhanced oral bioavailability of capsaicin in mixed polymeric micelles: Preparation, in vitro and in vivo evaluation. J Fund Foods 8: 358-366.). Briefly, the CAPLIP dispersion (2 mL) was placed in a dialysis tubing cellulose membrane (33 mm; Sigma-Aldrich) immersed in 40 mL of pH 7.2 buffer solution. At a regular time intervals, 3.5 mL of receiver solution was withdrawn. The capsaicin released from the liposome was measured at each sampling time by UV spectrophotometry, using calibration curve of standard capsaicin (λ= 270 nm; linearity 20 to 100 µg/mL; y=0.0082x-0.0148; r=0.991).

The in vitro release study was carried out at 37 °C using dynamic dialysis technique ref. Briefly, the CAPLIP dispersion (2 mL) was kept in a dialysis membrane (MD34, 8000-14,000, Sigma-Aldrich) and this system was immersed in 40 mL of pH 7.2 buffer solution. At a regular time intervals, 3.5 mL of receiver solution was withdrawn. In order to calculate of capsaicin released from liposome, was measured at sampling time by spectrophotometry UV, using the same calibration curve.

BIOLOGICAL ASSAY

This study was approved by our Animal Care and Use Committee (register # 060208) the National Research Council prior to beginning the experiments. In accordance with the institution›s guidelines outlined in "Guide for the Care and Use of Laboratory Animals", all animals received humane care throughout the study.

The experiment utilized 24 female rats (Rattus norvegicus albinus, Wistar strain, weighing 190 ± 30 g, approximately 8 weeks of age) that were housed in clear plastic cages with loose hardwood chip bedding in a temperature and humidity-controlled environment and supplied with food and water ad libitum. The animals were divided into four groups (n=6): CTR (treated with saline solution), LIP (treated with liposomes only), CAP (treated with capsaicin only) and CAPLIP (treated with capsaicin-loaded liposomes).

The animals were subcutaneously anesthetized with ketamine (70 mg/kg) and midazolam (4 mg/kg). Intramuscular administration of ceftriaxone (57 mg/kg) was performed to prevent further cystitis due to manipulation of the urinary tract. After 30 min, the urethral meatus was disinfected with 5 % PVPI solution, and vesical catheterization was carried out using an intravenous catheter (22, Jelco), which was fully inserted in order to reach the bladder. Next, the formulations were instilled into the bladder according to experimental group: saline solution (CTR), 3 mM capsaicin solution (CAP), 30 mM liposomes only (LIP) and 30 mM capsaicin-loaded liposome solution (CAPLIP).

The animals were euthanized in a CO2 chamber 24 h later, and the bladder of each animal was removed and fixed in formalin for 24 h. The specimens were cleared with xylene, embedded in paraffin and cut in a longitudinal plane. Then, six semi-serial histological sections (3-µm thick) were prepared and stained in hematoxylin/eosin (HE) and Sirius Red (SR).

HE-stained histological sections were scored for inflammatory response as follows: 0 (absence of inflammatory response), 1 (inflammatory cells representing less than 10 % of the cell population observed within the wound area), 2 (inflammatory cells representing between 10 % and 50 % of the cell population observed within the wound area), and 3 (inflammatory cells representing more than 50 % of the cell population observed within the wound area). We also classified the inflammatory profile (IP) as acute (predominance of polymorphonuclear cells) or chronic (predominance of mononuclear cells).

SR-stained histological sections were viewed under polarized light to assess collagen fibers in the bladder wall connective tissue. Collagen fibers were evaluated according to their morphological appearance (wavy or stretched, thin or thick, short or long), spatial arrangement (reticular, parallel or interlaced) and birefringence pattern (type III, green/yellow-green fibers; or type I, orange/orange-red fibers).

STATISTICAL ANALYSIS

Statistical analysis was performed using one-way analysis of variance (ANOVA) and post-hoc Tukey's tests. Differences were regarded as significant when p<0.05.

RESULTS AND DISCUSSION

The capsaicinoids, such as capsaicin and dihydrocapsaicin, possess analgesic, anti-inflammatory, anti-tumor and antioxidant potential. Structural characteristics of capsaicinoids, termed also as vanilloids, are responsible for biological activity. The main active group is the vanillyl (4-hydroxy-3-methoxybenzyl) (Kuzma et al. 2015KUZMA M, FODOR K, MAÁZ P, AVAR P, MÒZSIC G, PAST T, FISCHER E and PERJÈSI P. 2015. A validated HPLC-FLD method for analysis of intestinal absorption and metabolism of capsaicin and dihydrocapsaicin in the rat. J Pharmaceut Biomed Anal 103: 59:66.). Capsaicin and dihydrocapsaicin, like other vanilloids, has a benzene ring and long hydrophobic carbon tail with a polar amide group.

These compounds have comparable pharmacodynamic and pharmacokinetic properties. Intravesicular application of capsaicin and analogs, like dihydrocapsaicin, increases bladder capacity and reduces urge incontinence in humans with detrusor hyper-reactivity (Cruz 2004CRUZ F. 2004. Mechanisms involved in new therapies for overactive bladder. Urology 63: 65-73.).

Liposome efficiency depends on physicochemical parameters, such as composition, size, polydispersity index and zeta potential (Zhu et al. 2014ZHU Y, PENG W, ZHANG J, WANG M, FIREMPONG CK, FENG C, LIU H, XU X and YU J. 2014. Enhanced oral bioavailability of capsaicin in mixed polymeric micelles: Preparation, in vitro and in vivo evaluation. J Fund Foods 8: 358-366., Zhao et al. 2011ZHAO L, XIONG H, PENG H, WANG Q, HAN D, BAI C, LIU Y, SHI S and DENG B. 2011. PEG-coated lyophilized proliposomes: preparation, characterizations and in vitro release evaluation of vitamin E. Eur Food Red Technol 232: 647-654.). Figure 1 shows the zeta potentials of LIP and CAPLIP. The LIP zeta potential was decreased after 7 days (-40.9 mV), which is suggestive of system stabilization. After 14 days, the zeta potential showed a slight increase (-36 mV). CAPLIP zeta potential values were constant (around -32 mV) throughout the 14-day experiment, which indicates s colloidal dispersion. According to Pham et al. (2012PHAM TT, JAAFAR-MAALEJ C, CHARCOSSET C and FESSI H. 2012. Liposome and niosome preparation using a membrane contactor for scale-up. Colloids Surf B-Biointerfaces 94: 15-21.), negative zeta potential values are usually recognized to indicate good suspension stability.

Figure 1
Zeta potentials of liposomes (LIP) and liposomes containing capsaicin (CAPLIP).

Vesicle size is another important parameter for colloidal system stability. Except for the LIP formulation, which showed a slight increase at 7 days, vesicle size was unchanged after 14 days. The CAPLIP formulation contained smaller vesicles (68-78 nm) than LIP (78-106 nm), but the average size for both was less than 100 nm (Figure 2), which is similar to published data (Pham et al. 2012PHAM TT, JAAFAR-MAALEJ C, CHARCOSSET C and FESSI H. 2012. Liposome and niosome preparation using a membrane contactor for scale-up. Colloids Surf B-Biointerfaces 94: 15-21., Zhu et al. 2014ZHU Y, PENG W, ZHANG J, WANG M, FIREMPONG CK, FENG C, LIU H, XU X and YU J. 2014. Enhanced oral bioavailability of capsaicin in mixed polymeric micelles: Preparation, in vitro and in vivo evaluation. J Fund Foods 8: 358-366.).

Figure 2
Vesicles size of liposomes LIP (a) and liposomes containing capsaicin CAPLIP (b).

The polydispersity index (PdI) determines the homogeneity profile of vesicles with regard to size. Values lower than 0.2 indicate homogeneously sized vesicles, and those higher than 0.3 suggest size heterogeneity (Zhu et al. 2014ZHU Y, PENG W, ZHANG J, WANG M, FIREMPONG CK, FENG C, LIU H, XU X and YU J. 2014. Enhanced oral bioavailability of capsaicin in mixed polymeric micelles: Preparation, in vitro and in vivo evaluation. J Fund Foods 8: 358-366.). The PdI values of LIP and CAPLIP remained constant (minimal variation from 0.257 to 0.279), indicating stable homogeneity of vesicle size over 14 days.

The TEM images of LIP and CAPLIP showed the formation of nanometer-sized, oligo and multi-lamellar vesicles of spherical shape (Figure 3).

Figure 3
Transmission electron microscopy image of LIP (a) and LIPCAP (b).

The literature reported that the contractile tone for modulation of detrusor smooth muscle activity was reached by cumulative application of capsaicin at doses between 10−8 and 10−6 M in rats models. Subsequent doses of capsaicin are necessary after the contractile response had reached steady plateau. In our experiments, we used a high concentration of capsaicin (10-3M), considering that the drug delivery would be retarded. We can observe in in drug delivery study that this slow release occurred, delivering 26.6 % of capsaicin after 24 hours and 33.8 % after one week. The slow delivery guaranteed the effective doses to biological action, spreading the drug among the tissue, avoiding the adverse effect for drug accumulation in specific local.

In regard to the biological assay, we did not observe any changes in the histological architecture or cytological features of the transitional epithelium and connective tissue in CTR- or LIP-treated bladders, except for very mild lymphocyte infiltration observed in one specimen, which was likely due to mechanical irritation caused by catheter insertion. These findings suggest that the phospholipids do not trigger inflammatory or degenerative processes in bladder tissues. Conversely, we found intense infiltrate composed of polymorphonuclear neutrophils and lymphocytes in the CAP group, especially near the epithelial lining, as well as intense exudative changes, hyperemia and interstitial edema. Extensive areas of ulceration of the transitional epithelium were also noted (Figure 4). The intensity of the inflammatory response was significantly increased in CAP compared to the other groups (p<0.05). Intense bladder tissue aggravation following intravesical capsaicin administration was previously reported by Hsu et al. (2013HSU CC, CHUANG YC and CHANCELLOR MB. 2013. Intravesical drug delivery for dysfunctional bladder. Int J Urol 20: 552-562.), suggesting that capsaicin has remarkable irritative properties. However, only minor vascular changes were observed in tissues treated with liposome-loaded capsaicin (CALIP). Likewise, reduced toxic effects of capsaicin released by liposomal systems within bladder tissue were described by Tyagi et al. (2004TYAGI P, CHANCELLOR MB, LI Z, GROAT WCD, YOSHOMURA N, FRASER MO and HUANG L. 2004. Urodynamic and immunhohistochemical evalution of intravesical capsaicin delivery using thermosensitive hydrogel and liposomes. J Urolology 171: 483-489.), and such protective properties were related to the slow incorporation of liposomes into the cell phospholipid bilayer, resulting in gradual release of the active chemical compound. Moreover, liposomes seem to protect the vesical epithelium; they enhance the phospholipid urothelial barrier, improving the resistance to aggravating substances (Chuang et al. 2009CHUANG YC, LEE WC, LEE WC and CHIANG PH. 2009. Intravesical Liposome Versus Oral Pentosan Polysulfate for Interstitial Cystitis/Painful Bladder Syndrome. J Urology 182: 1393-1400.).

Figure 4
Histological sections of the bladders 24 h after the instillation of the different formulations. CTR and LIP show no change in the usual features of the transitional epithelium (TE) and connective tissue. Intense hyperemia (arrows) is showed in CAPLIP, but the normal architecture of the tissue is sustained. In CAP, replacement of the transitional epithelium by extensive ulceration (U), recovered by polymorphonuclear neutrophils, as well as marked exsudative changes (EC) of the connective tissue are observed (HE, 200x).

Collagen molecules play a fundamental role in maintaining the architecture, resistance, and cell-cell/cell-extracellular matrix interactions of different organs and tissues (Yuan et al. 2014 YUAN T, ZHANG LI, LI K, FAN H, FAN Y, LIANG J and ZHANG X. 2014. Collagen hydrogel as an immunomodulatory scaffold in cartilage tissue engineering. J Biomed Mater Res B Appl Biomater 102: 337-244.). Suitable post-injury collagenization is considered one of the most relevant biological factors for successful tissue recovery (Franz et al. 2011FRANZ S, RAMMELT S, SCHARNWEBER D and SIMON JC. 2011. Immune responses to implants e A review of the implications for the design of immunomodulatory biomaterials. Biomat 32: 6692-6709.). As seen in Figure 5, CTR, LIP and CAPLIP induced similar patterns of collagenization, comprised mostly of type-I collagen fibers, which were shortened and interlaced in sub-epithelial areas but long and outstretched in the bladder periphery. CAP, on the other hand, induced mostly short and irregularly arranged type-III collagen fibers that were associated with larger interfibrillar spaces throughout the specimens.

Figure 5
Histological sections of the bladders 24 h after the instillation of the different formulations. CTR, LIP and CAPLIP show predominance of type I collagen fibers, whereas CAP presents predominance of type III collagen (SR, 200x).

Wound healing studies carried out in experimental rodent models have demonstrated that type-III collagen fibers are initially deposited and are supposed to orientate proliferating and migrating endothelial cells to form granulation tissue as the first step of connective tissue repair (Albuquerque-Júnior et al. 2009Albuquerque-Júnior RLC, BARRETO ALS, PIRES JA, REIS FP, LIMA SO, RIBEIRO MAG and CARDOSO JC. 2009. Effect of bovine type-I collagen-based films containing red propolis on dermal wound healing in rodent model. Int S Morphol (Print) 27: 1105-1110., Ribeiro et al. 2009RIBEIRO MA, ALBUQUERQUE-JUNIOR RL, RAMALHO JM, PINHEIRO AL, BONJARDIM LR and DA CUNHA SS. 2009. Immunohistochemical assessment of myofibroblasts and lymphoid cells during wound healing in rats subjected to laser photobiomodulation at 660 nm. Photomed Laser Surg 27: 49-55.). These fibers are gradually replaced by type-I collagen, which gives the newly repaired tissue mechanical resistance and tensile strength (Nunes et al. 2011NUNES PS et al. 2011. Collagen-based films containing liposome-loaded usnic acid as dressing for dermal burn healing. J Biomed Biotechnol 2011: 1-9., Dantas et al. 2011DANTAS MDM et al. 2011. Improvement of dermal burn healing by associating sodium alginate/chitosan-based films and low level laser therapy. J Photochem Photobiol B 6: 1-9.). Therefore, the high level of sparsely arranged type-III collagen fibers observed in CAP, as opposed to the bimodal pattern of dense type-I collagen deposition observed in CTR, suggests that free capsaicin disrupted normal collagen disposition and that granulation tissue formation had yet to occur at the time the bladders were harvested. Nevertheless, the histological similarity observed in the collagen fiber disposition seen in CTR and CAP supports the hypothesis that the irritative properties of capsaicin were attenuated by loading the substance into liposomes.

In conclusion, we demonstrated that the liposomal formulation remained stable for 14 days after sample preparation and contained vesicles smaller than 100 nm. We also provided histological evidence that encapsulating capsaicin into liposome vesicles prevents bladder irritation 24 h after catheter administration.

ACKNOWLEDGMENTS

Authors are grateful to the National Laboratory of Nanotechnology (LNNano - TEM-MSC-18537), Foundation for Research, Institute of Technology and Research (ITP), and University Tiradentes, Brazil, for the viability of the experiments. Financial assistance was provided to Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and Fundação de Apoio à Pesquisa e Inovação de Sergipe (FAPITEC).

REFERENCES

  • Albuquerque-Júnior RLC, BARRETO ALS, PIRES JA, REIS FP, LIMA SO, RIBEIRO MAG and CARDOSO JC. 2009. Effect of bovine type-I collagen-based films containing red propolis on dermal wound healing in rodent model. Int S Morphol (Print) 27: 1105-1110.
  • AVELINO A and CRUZ F. 2000. Peptide immunoreactivity and ultrastructure of rat urinary bladder nerve fibers after topical desensitization by capsaicin or resiniferatoxin. Auton Neurosci 86: 37-46.
  • BARBERO GF, LIAZID A, PALMA M and BARROSO CG. 2008. Fast determination of capsaicinoids from peppers by high-performance liquid chromatography using a reversed phase monolithic column. Food Chem 107: 1276-1282.
  • BARTHELMES J, PERERA G, HOMBACH J, DUNNHAUPT S and BERNKOP-SCHNURCH A. 2011. Development of a mucoadhesive nanoparticulate drug delivery system for a targeted drug release in the bladder. Int J Pharm 416: 339-345.
  • CHUANG YC, LEE WC, LEE WC and CHIANG PH. 2009. Intravesical Liposome Versus Oral Pentosan Polysulfate for Interstitial Cystitis/Painful Bladder Syndrome. J Urology 182: 1393-1400.
  • CIPULLO LMA, COSIMATO C, FILIPPELLI A, CONTI V, IZZO V, ZULLO F and GUIDA M. 2014. Pharmacological approach to overactive bladder and urge urinary incontinence in women: an overview. Eur J Obstet Gyn R B 174: 27-34.
  • CRUZ F. 2004. Mechanisms involved in new therapies for overactive bladder. Urology 63: 65-73.
  • DANTAS MDM et al. 2011. Improvement of dermal burn healing by associating sodium alginate/chitosan-based films and low level laser therapy. J Photochem Photobiol B 6: 1-9.
  • FRANZ S, RAMMELT S, SCHARNWEBER D and SIMON JC. 2011. Immune responses to implants e A review of the implications for the design of immunomodulatory biomaterials. Biomat 32: 6692-6709.
  • FRÉZARD F and SCHETTINI DA. 2005. Liposomes: physicochemical and pharmacological properties, applications in antimony-based chemotherapy. Quím Nova 28: 511-518.
  • GUHASARKAR S and BANERJEE R. 2010. Intravesical drug delivery: Challenges, current status, opportunities and novel strategies. J Control Release 148: 147-159.
  • HSU CC, CHUANG YC and CHANCELLOR MB. 2013. Intravesical drug delivery for dysfunctional bladder. Int J Urol 20: 552-562.
  • KAUFMAN MR. 2011. Future Directions in Overactive Bladder Treatment. Curr Bladder Dysfunct Rep 6: 45-50.
  • KUZMA M, FODOR K, MAÁZ P, AVAR P, MÒZSIC G, PAST T, FISCHER E and PERJÈSI P. 2015. A validated HPLC-FLD method for analysis of intestinal absorption and metabolism of capsaicin and dihydrocapsaicin in the rat. J Pharmaceut Biomed Anal 103: 59:66.
  • LEE WC, CHUANG YC and CHIANG P H. 2011. Safety and dose flexibility clinical evaluation of intravesical liposome in patients with interstitial cystitis or painful bladder syndrome. Kaohsiung J Med Sci 27: 437-440.
  • MEEL TDV and WYNDAELE JJ. 2012. Reproducibility of Electrical Sensory Testing in Lower Urinary Tract at Weekly Intervals in Healthy Volunteers and Women With Non-neurogenic Detrusor Overactivity. Urol 79: 526-531.
  • NIRMAL J, CHUANG YC , TYAGI P, MICHAEL B and CHANCELLOR MB. 2012. Intravesical therapy for lower urinary tract symptoms. Urol Sci 23: 70-77.
  • NUNES PS et al. 2011. Collagen-based films containing liposome-loaded usnic acid as dressing for dermal burn healing. J Biomed Biotechnol 2011: 1-9.
  • PETERS KM, HASENAU DL, ANTHONY M, KAUFMAN J and KILLINGER KA. 2012. Novel Therapy with Intravesical Liposomes for Ulcerative Interstitial Cystitis/Painful Bladder Syndrome. Luts 4: 51-53.
  • PETROVSZKI Z, ADAM G, KEKESI G, TUBOLY G, MORVAY Z, NAGY E, BENEDEK G and HORVATH G. 2014. The effects of juvenile capsaicin desensitization in rats: Behavioral impairments. Physiol Behav 125: 38-44.
  • PHAM TT, JAAFAR-MAALEJ C, CHARCOSSET C and FESSI H. 2012. Liposome and niosome preparation using a membrane contactor for scale-up. Colloids Surf B-Biointerfaces 94: 15-21.
  • RIBEIRO MA, ALBUQUERQUE-JUNIOR RL, RAMALHO JM, PINHEIRO AL, BONJARDIM LR and DA CUNHA SS. 2009. Immunohistochemical assessment of myofibroblasts and lymphoid cells during wound healing in rats subjected to laser photobiomodulation at 660 nm. Photomed Laser Surg 27: 49-55.
  • ROLLYSON WD, STOVER CA, BROW KC, PERRY HE, STEVENSON CD, MCNEES CA, BALL JG, VALENTONIC MA and DASGUPTA P. 2014. Bioavailability of capsaicin and its implications for drug delivery. J Controll Rele 196: 96-105.
  • SHARMA SK, VIJ AS and SHARMA M. 2013. Mechanisms and clinical uses of capsaicin. Eur J Pharmacol 720: 55-62.
  • THÜROFF JW, ABRAMS P, ANDERSSON KE, ARTIBANI W, CHAPPLE CR, DRAKE MJ, HAMPEL C, NEISIUS A, SCHRÖDER A and TUBARO A. 2011. EAU Guidelines on Urinary Incontinence. Eur Urol 59: 387-400.
  • TU FF, HELLMAN KM and BACKONJA MM. 2011. Gynecologic management of neuropathic pain. Am J Obsted Gynecol 205: 435-443.
  • TYAGI P, CHANCELLOR MB, LI Z, GROAT WCD, YOSHOMURA N, FRASER MO and HUANG L. 2004. Urodynamic and immunhohistochemical evalution of intravesical capsaicin delivery using thermosensitive hydrogel and liposomes. J Urolology 171: 483-489.
  • WYNDAELE JJ, KOVINDHA A, MADERSBACHER H, RADZISZEWSKI P, RUFFION A, SCHURCH B, CASTRO D, IGAWA Y, SAKAKIBARA R and WEIN A. 2010. Neurologic Urinary Incontinence. Neurourol Urodynam 29: 159-164.
  • YUAN T, ZHANG LI, LI K, FAN H, FAN Y, LIANG J and ZHANG X. 2014. Collagen hydrogel as an immunomodulatory scaffold in cartilage tissue engineering. J Biomed Mater Res B Appl Biomater 102: 337-244.
  • ZHANG Q, HU J, SHENG L and LI Y. 2010. Simultaneous quantification of capsaicin and dihydrocapsaicin in rat plasma using HPLC coupled with tandem mass spectrometry. J Chromatogr 878: 2292-2297.
  • ZHAO L, XIONG H, PENG H, WANG Q, HAN D, BAI C, LIU Y, SHI S and DENG B. 2011. PEG-coated lyophilized proliposomes: preparation, characterizations and in vitro release evaluation of vitamin E. Eur Food Red Technol 232: 647-654.
  • ZHU Y, PENG W, ZHANG J, WANG M, FIREMPONG CK, FENG C, LIU H, XU X and YU J. 2014. Enhanced oral bioavailability of capsaicin in mixed polymeric micelles: Preparation, in vitro and in vivo evaluation. J Fund Foods 8: 358-366.

Publication Dates

  • Publication in this collection
    01 Sept 2016
  • Date of issue
    Sept 2016

History

  • Received
    22 May 2015
  • Accepted
    27 Nov 2015
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