Sustained Intraperitoneal Chemotherapy via an Injectable Depot Delivery System for the Treatment of Ovarian Cancer

Zahedi, Payam

31 August 2012

Ovarian cancer has the highest mortality rate of all gynecological malignancies, due to inadequate treatment strategies and poor early diagnosis. Intraperitoneal (IP) chemotherapy administered on an intermittent schedule has been pursued for ovarian cancer treatment. However, local toxicities and complications associated with indwelling IP catheters required to deliver the chemotherapeutics have been documented. Furthermore, shortening or completely removing treatment-free periods between each chemotherapy cycle has shown improved efficacy compared to intermittent chemotherapy. The focus of this thesis was to develop and characterize a biocompatible and biodegradable IP injectable depot sustained drug delivery system as a new treatment strategy for ovarian cancer. A polymer-lipid injectable formulation (PoLigel) was developed and used for sustained docetaxel (DTX) delivery. The PoLigel resulted in homogeneous DTX peritoneal distribution and sustained plasma levels in healthy mice, which was in contrast to Taxotere®, the clinically used formulation of DTX. Sustained plasma, tissue, tumor and ascites DTX concentrations were observed in mice bearing IP SKOV3 tumors or ID8 ascites over a 3 week period following IP administration of the PoLigel. The intratumoral distribution and tumor penetration of DTX in subcutaneous (SC) and IP SKOV3 tumors were characterized. DTX distributed more towards the tumor core and diffused 1.5 fold further from blood vessels of the IP tumors compared to the SC tumors. The high efficacy observed in the IP SKOV3 and ID8 models and the SC SKOV3 model was attributed to favorable drug distribution at the whole-body, peritoneal and intratumoral levels in combination with local and systemic sustained drug exposure. Sustained chemotherapy with DTX alone and in combination with a drug efflux transporter inhibitor was investigated in multidrug resistant (MDR) ovarian cancer. In vitro, combination delivery via the PoLigel resulted in more apoptosis, greater intracellular accumulation of DTX, and lower DTX efflux in MDR ovarian cancer cells. Sustained combination chemotherapy was more than twice as efficacious as intermittent Taxotere® treatment in MDR ovarian cancer. Significant anti-tumor efficacy was also observed in the MDR model following sustained DTX chemotherapy compared to intermittent Taxotere®. Overall, results presented here encourage the clinical investigation of IP sustained chemotherapy for ovarian cancer treatment.

Ovarian cancer

Intraperitoneal chemotherapy

Localized drug delivery

Docetaxel

Injectable

Polymer-lipid

0572

0491

Sustained Intraperitoneal Chemotherapy via an Injectable Depot Delivery System for the Treatment of Ovarian Cancer

Zahedi, Payam

31 August 2012

Ovarian cancer has the highest mortality rate of all gynecological malignancies, due to inadequate treatment strategies and poor early diagnosis. Intraperitoneal (IP) chemotherapy administered on an intermittent schedule has been pursued for ovarian cancer treatment. However, local toxicities and complications associated with indwelling IP catheters required to deliver the chemotherapeutics have been documented. Furthermore, shortening or completely removing treatment-free periods between each chemotherapy cycle has shown improved efficacy compared to intermittent chemotherapy. The focus of this thesis was to develop and characterize a biocompatible and biodegradable IP injectable depot sustained drug delivery system as a new treatment strategy for ovarian cancer. A polymer-lipid injectable formulation (PoLigel) was developed and used for sustained docetaxel (DTX) delivery. The PoLigel resulted in homogeneous DTX peritoneal distribution and sustained plasma levels in healthy mice, which was in contrast to Taxotere®, the clinically used formulation of DTX. Sustained plasma, tissue, tumor and ascites DTX concentrations were observed in mice bearing IP SKOV3 tumors or ID8 ascites over a 3 week period following IP administration of the PoLigel. The intratumoral distribution and tumor penetration of DTX in subcutaneous (SC) and IP SKOV3 tumors were characterized. DTX distributed more towards the tumor core and diffused 1.5 fold further from blood vessels of the IP tumors compared to the SC tumors. The high efficacy observed in the IP SKOV3 and ID8 models and the SC SKOV3 model was attributed to favorable drug distribution at the whole-body, peritoneal and intratumoral levels in combination with local and systemic sustained drug exposure. Sustained chemotherapy with DTX alone and in combination with a drug efflux transporter inhibitor was investigated in multidrug resistant (MDR) ovarian cancer. In vitro, combination delivery via the PoLigel resulted in more apoptosis, greater intracellular accumulation of DTX, and lower DTX efflux in MDR ovarian cancer cells. Sustained combination chemotherapy was more than twice as efficacious as intermittent Taxotere® treatment in MDR ovarian cancer. Significant anti-tumor efficacy was also observed in the MDR model following sustained DTX chemotherapy compared to intermittent Taxotere®. Overall, results presented here encourage the clinical investigation of IP sustained chemotherapy for ovarian cancer treatment.

Ovarian cancer

Intraperitoneal chemotherapy

Localized drug delivery

Docetaxel

Injectable

Polymer-lipid

0572

0491

DEVELOPMENT OF CONTROLLED DRUG DELIVERY SYSTEMS OF POLYMERIC NANOMEDICINES ASSOCIATED TO SCAFFOLDS FOR TISSUE REGENERATION

Rodríguez Escalona, Gabriela de Jesús

02 May 2016

[EN] Nowadays, one of the biggest concerns that permanently keep the attention of main important sectors of human society is health. Modern medical science is compromised with not only providing good adequate treatments but also effective specific solutions for each type of disease or human pathology. In this direction, innovative approaches like tissue engineering or regenerative medicine, controlled drug delivery systems and nanomedicines emerge to bring alternatives to situations hard to solve with conventional treatment and strategies, including the replacement of damaged or diseases tissues and/or organs. Specifically, this research is mainly aimed to design a combined system for controlled, stable and localized release of therapeutic agents that are able to exert their effect selectively on the area that warrants treatment. This construct will have enough versatility to be adapted to almost any kind of treatment, from cancer to tissue regeneration, always that the key requirement of the treatment was the need to provide the treatment of localized, stable and controlled manner. With the purposes of making easier the understanding as well as the design of the system, I was decided, for the proof of concept, to use drugs and materials with known activity applied on tissue regeneration and for the treatment of chronic wounds. The system in question consists of three main elements: 1) The first element is the polymer conjugates of therapeutic agents, which contribute to increasing the selectivity of the therapeutic action of the drug, as well as improved stability, bioavailability and biocompatibility thereof. If the drug is hydrophobic, conjugation contributes to increase its solubility in water, and in the case of proteins used as therapeutic agents, the combination helps reduce the body's immune response, increasing the chance of successful of the treatment. 2) The second element are the biodegradable polymeric microparticles, which in this case act like encapsulation agents for polymeric conjugate , thus allowing to have a second control point in the release kinetics of the therapeutic agents . Simultaneously, the microparticles also play a role in modifying the texture of the final construct, ascribing mechanical and physicochemical properties that help to improve some biological properties of the final material, such as the affinity, adhesion and cell proliferation. 3) The third element consists of a nanoporous membrane made of a biodegradable polymer by electrospinning, which constitute the unifier element of the whole system. This membrane provides manageability to the construct and is itself the last point of control in the release kinetics of the therapeutic agent or agents. Besides, it must be biocompatible and stable at ambient conditions, since this probably is going to be exposed to the environment while protecting the wound, in the case of this kind of application. These three elements, which themselves are complex systems separately, are systematically combined to achieve a synergistic relationship between them so that each one power the qualities of the other two. The resulting construct was characterized and it demonstrated to have characteristic properties that can be used as a control parameter during manufacture of this new material. Also, preliminary biological studies developed "in vitro" indicated that the proposed system may be a good candidate for deeper studies as alternative treatment for chronic wounds and other pathologies that require localized administration for long periods of time. / [ES] Actualmente, una de las mayores preocupaciones que permanentemente laman la atención de los principales sectores de la sociedad humana es la salud. La ciencia médica moderna está comprometida no solo con suministrar tratamientos adecuados, sino más bien ofrecer soluciones efectivas y específicas para cada tipo de enfermedad o patología humana. En este sentido, estrategias innovadoras como la ingeniería de tejidos o la medicina regenerativa, los sistemas de liberación controlada de fármacos y las nanomedicinas, surgen como buenas alternativas para abordar situaciones difíciles de resolver aplicando los tratamientos y estrategias terapéuticas convencionales, como es el caso cuando se hace necesario reemplazar tejidos o incluso órganos dañados por algún traumatismo o enfermedad. Concretamente, el presente trabajo de investigación tiene por objetivo principal diseñar un sistema combinado para la liberación controlada, estable y localizada de agentes terapéuticos que sean capaces de ejercer su efecto de forma selectiva sobre la zona que amerita el tratamiento. Este constructo tendrá la versatilidad suficiente como para poder adaptarse a casi cualquier tipo de tratamiento, desde el cáncer hasta la regeneración de tejido, siempre que el requisito clave del tratamiento sea la necesidad de suministrar el tratamiento de manera localizada, estable y controlada. Para efectos de facilitar la compresión y el diseño del sistema se escogió para la prueba de concepto materiales y fármacos asociados a la regeneración de tejidos, como tratamiento para casos de heridas crónicas. El sistema en cuestión está constituido por tres elementos principales: 1) El primer elemento son los conjugados poliméricos de agentes terapéuticos que contribuirán a aumentar la selectividad de la acción terapéutica del fármaco, así como también a mejora la estabilidad, biodisponibilidad y biocompatibilidad de los mismos. En caso de que el fármaco sea hidrofóbico, la conjugación contribuye a aumentar su solubilidad en agua, y en el caso de usar proteínas como agentes terapéuticos, la conjugación contribuye a disminuir la respuesta inmunológica del cuerpo incrementando las posibilidad de éxito del tratamiento. 2) El segundo elemento son micropartículas poliméricas biodegradables, que en este caso actúan con agentes de encapsulación para los conjugados poliméricos, permitiendo así contar con un segundo punto de control en la cinética de liberación de los agentes terapéuticos. Simultáneamente, las micropartículas también cumplen un papel de modificador de la textura del constructo final, adjudicándole propiedades mecánica y fisicoquímicas que contribuyen a mejorar las propiedades biológicas del material final, como son la afinidad, la adhesión y la proliferación celular. 3) El tercer elemento consiste en una membrana polimérica biodegradable nanoporosa hecha por electrospinning, que constituyen el elemento unificados del sistema, aporta manejabilidad al constructo y es en sí mismo el último punto de control en la cinética de liberación del agente terapéutico. Este último debe ser biocompatible y estable en condiciones ambientales, puesto que probablemente este expuesto al ambiente mientras protege la herida, en el caso concreto de este tipo de aplicación. Estos tres elementos, que en sí mismos constituyen sistemas complejos por separado, se han combinado sistemáticamente para alcanzar una relación sinérgica entre ellos de manera que cada uno potencia las cualidades de los otros dos. El constructo resultante se caracterizó demostrando tener propiedades características que se pueden utilizar como parámetro de control durante la fabricación del mismo. Así mismo estudios in vitro del sistema desarrollado señalan que puede ser un buen candidato para el tratamiento de heridas crónicas entre otras patologías que requieran tratamientos localizados. / [CAT] Actualment, una de les majors preocupacions que permanentment llepen l'atenció dels principals sectors de la societat humana és la salut. La ciència mèdica moderna està compromesa no solament amb subministrar tractaments adequats, sinó més aviat oferir solucions efectives i específiques per a cada tipus de malaltia o patologia humana. En aquest sentit, estratègies innovadores com l'enginyeria de teixits o la medicina regenerativa, els sistemes d'alliberament controlat de fàrmacs i les nanomedicines, sorgeixen com a bones alternatives per a abordar situacions difícils de resoldre aplicant els tractaments i estratègies terapèutiques convencionals, com és el cas quan es fa necessari reemplaçar teixits o fins i tot òrgans danyats per algun traumatisme o malaltia. Concretament, el present treball de recerca té per objectiu principal dissenyar un sistema combinat per a l'alliberament controlat, estable i localitzada d'agents terapèutics que seguen capaços d'exercir el seu efecte de forma selectiva sobre la zona que amirita el tractament. Aquest constructe tindrà la versatilitat suficient com per a poder adaptar-se a quasi qualsevol tipus de tractament, des del càncer fins a la regeneració de teixit, sempre que el requisit clau del tractament sega la necessitat de subministrar el tractament de manera localitzada, estable i controlada. Per a efectes de facilitar la compressió i el disseny del sistema es va escollir per a la prova de concepte materials i fàrmacs associats a la regeneració de teixits, com a tractament per a casos de ferides cròniques. El sistema en qüestió està constituït per tres elements principals: 1) El primer element són els conjugats polimèrics d'agents terapèutics que contribuiran a augmentar la selectivitat de l'acció terapèutica del fàrmac, així com també a millora l'estabilitat, biodisponibilitat i biocompatibilitat dels mateixos. En cas que el fàrmac sega hidrofòbic, la conjugació contribueix a augmentar la seua solubilitat en aigua, i en el cas d'usar proteïnes com a agents terapèutics, la conjugació contribueix a disminuir la resposta immunològica del cos incrementant les possibilitat d'èxit del tractament. 2) El segon element són microparticles polimèriques biodegradables, que en aquest cas actuen amb agents d'encapsulació per als conjugats polimèrics, permetent així comptar amb un segon punt de control en la cinètica d'alliberament de l'agent terapèutics. Simultàniament, les microparticles també compleixen un paper de texturitzant del constructe final, adjudicant-li propietats mecànica i fisicoquímiques que contribueixen a millorar la propietats biològiques del material final, com són l'afinitat, l'adhesió i la proliferació cel·lular. 3) El tercer element consisteix en una membrana polimèrica biodegradable nanoporosa feta per electrospinning, que constitueixen el element unificats del sistema, aporta manejabilitat al constructe i és en si mateix el ultimi punt de control en la cinètica d'alliberament de l'agent terapèutic. Aquest últim ha de ser biocompatible i estable en condicions ambientals, ja que probablement aquest exposat a l'ambient mentre protegeix la ferida, en el cas concret d'aquest tipus d'aplicació. Aquests tres elements que en si mateixos constitueixen sistemes complexos per separat, s'han combinat sistemàticament per a aconseguir una relació sinergètica entre ells de manera que cadascun potencia les qualitats dels altres dos. El constructe resultant es va caracteritzar demostrant tenir propietats característiques que es poden utilitzar com a paràmetre de control durant la fabricació del mateix. Així mateix estudis in vitro del sistema desenvolupat assenyalen que pot ser un bon candidat per al tractament de ferides cròniques entre altres patologies que requeriren tractaments localitzats. / Rodríguez Escalona, GDJ. (2016). DEVELOPMENT OF CONTROLLED DRUG DELIVERY SYSTEMS OF POLYMERIC NANOMEDICINES ASSOCIATED TO SCAFFOLDS FOR TISSUE REGENERATION [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/63231 / TESIS

Ingeniería de tejidos

Polímeros terapéuticos

Administración localizada

Ácido hyalurónico

Enginyeria de teixits

Curcumina

Polímers terapèutics

Administració localitzada

Àcid hyalurònic

Tissue Engineering

Electrospinning-microparticle composite

Curcumin

PLLA

HA

MAQUINAS Y MOTORES TERMICOS