ABSTRACT
Systemic delivery of therapeutic proteins to the central nervous system (CNS) is challenging because of the blood-brain barrier restrictions. Direct intrathecal delivery is possible but does not produce stable concentrations. We are proposing an alternative approach for localized delivery into the CNS based on the Transduced Autologous Restorative Gene Therapy (TARGT) system. This system was previously developed using a gene therapy approach with dermal tissue implants. Lewis rat dermal tissue was transduced to secrete human EPO (hEPO). TARGT viability and function were retained following cryopreservation. Upon implantation into the rat cisterna magna, a mild inflammatory response was observed at the TARGT-brain interface throughout 21-day implantation. hEPO expression was verified immunohistochemically and by secreted levels in cerebrospinal fluid (CSF), serum, and in vitro post explant. Detectable CSF hEPO levels were maintained during the study. Serum hEPO levels were similar to rat and human basal serum levels. In vitro, the highest hEPO concentration was observed on day 1 post-explant culture and then remained constant for over 21days. Prolonged incubation within the cisterna magna had no negative impact on TARGT hEPO secretion. These promising results suggest that TARGTs could be utilized for targeted delivery of therapeutic proteins to the CNS.
Subject(s)
Delayed-Action Preparations/administration & dosage , Proteins/administration & dosage , Animals , Blood-Brain Barrier/metabolism , Central Nervous System/drug effects , Cerebrospinal Fluid/metabolism , Cryopreservation/methods , Erythropoietin/administration & dosage , Genetic Therapy/methods , Genetic Vectors/metabolism , Humans , Injections, Spinal/methods , Rats , Rats, Inbred Lew , Serum/metabolismABSTRACT
The tympanic membrane (TM), separating the external and middle ear, consists of fibrous connective tissue sandwiched between epithelial layers. To treat chronic ear infections, tympanostomy drainage tubes are placed in surgically created holes in TMs which can become chronic perforations upon extrusion. Perforations are repaired using a variety of techniques, but are limited by morbidity, unsatisfactory closure rates, or minimal regeneration of the connective tissue. A more effective, minimally-invasive therapy is necessary to enhance the perforation closure rate. Current research utilizing decellularized or alignate materials moderately enhance closure but the native TM architecture is not restored. Poly(glycerol sebacate) (PGS) is a biocompatible elastomer which supports cell migration and enzymatically degrades in contact with vascularized tissue. PGS spool-shaped plugs were manufactured using a novel process. Using minimally invasive procedures, these elastomeric plugs were inserted into chronic chinchilla TM perforations. As previously reported, effective perforation closure occurred as both flange surfaces were covered by confluent cell layers; >90% of perforations were closed at 6-week postimplantation. This unique in vivo environment has little vascularized tissue. Consequently, PGS degradation was minimal over 16-week implantation, hindering regeneration of the TM fibrous connective tissue. PGS degradation must be enhanced to promote complete TM regeneration.
Subject(s)
Decanoates , Glycerol/analogs & derivatives , Materials Testing , Polymers , Prostheses and Implants , Tympanic Membrane Perforation/therapy , Wound Healing , Animals , Chinchilla , Chronic Disease , Humans , Time Factors , Tympanic Membrane/pathology , Tympanic Membrane Perforation/pathologyABSTRACT
To determine whether cellular components of tissue-engineered cardiovascular structures are derived from cells harvested and seeded onto an acellular scaffold, or from cells originating from surrounding tissue (e.g., proximal and distal anastomosis), cellular retroviral transfection with green fluorescent protein (GFP) was used. Ovine endothelial cells (ECs) were transfected with a Moloney murine leukemia virus (Mo-MuLV)-based retroviral vector expressing GFP. Transfection was evaluated by fluorescence microscopy and fluorescence-activated cell sorting. The rate of transfection of the primary cells was 33.4% for ECs, 48 hours after transfection. Stable transfection could be observed for at least 25 subsequent passages. Retroviral transfection with GFP enables stable and reliable long-term labeling of ovine ECs. This approach might offer an attractive pathway to study tissue development, with emphasis on distinguishing between cellular components initially seeded onto a construct and those occurring as a result of cell ingrowth from surrounding tissue.
Subject(s)
Endothelium, Vascular/metabolism , Genetic Vectors , Luminescent Proteins/genetics , Retroviridae , Tissue Engineering , Transfection , Animals , Green Fluorescent Proteins , Luminescent Proteins/metabolism , Sheep/genetics , Sheep/metabolismABSTRACT
The loss or failure of an organ or tissue is one of the most frequent, devastating, and costly problems in healthcare. Current treatment modalities include transplantation of organs, surgical reconstruction, use of mechanical devices, or supplementation of metabolic products. A new field, tissue engineering, applies the principles and methods of engineering, material science, and cell and molecular biology toward the development of viable substitutes which restore, maintain, or improve the function of human tissues. In this review, we outline the opportunities and challenges of this emerging interdisciplinary field and its attempts to provide solutions to tissue creation and repair. Within this context, we present our experience using the basic tools of tissue engineering to guide regeneration of diverse tissues that include the liver, small intestine, cardiovascular structures, nerve, and cartilage. And in addition, we discuss the necessity of finding new strategies to achieve vascularization of complex tissues for transplant and present our approaches utilizing MicroElectroMechanical Systems (MEMS) technology and three-dimensional printing.
