Clinical targets
Research activities include prototype development of biomaterials from nano- to micro-scale to deliver therapeutics and diagnostics platforms. Biomaterial platforms at NFB include: scaffolds with instructive biophysical signals, functionalIntervertebral disc regeneration
Degeneration ofTendon and ligament regeneration
Over 17 million tendon operations are performed annually in US alone. Tendon incidents are associated with pain and poor quality of life leading to healthcare costs exceeding US$150 billion in Europe annually. Non-invasive pharmacological strategies show little success, even for small injuries. Intervening replacement is therefore necessary, especially in severe injuries or in cases of large defects. Tendon repair therapies rely heavily on tissue grafts and synthetic biomaterials. However, the limited supply of autografts in severe injuries and in degenerative conditions restricts their use. The use of allografts/xenografts has also been questioned due to poor success rate. Long-term implantation studies have also revealed several drawbacks (e.g. fibrotic encapsulation of the implant) in the use of synthetic materials. To this end, NFB has developed collagen-based nano-textured scaffolds with structural, physical and biological properties similar to those obtained from nativeSoft tissue repair
Wound repair results from a complex and highly orchestrated cellular and biochemical response to tissue injury. Given that the wound repair constitutes a major issue in clinical practice with enormous healthcare costs, NFB is developing several scaffold-based platforms to induce wound healing and to restore function. For example, in cases of chronic healing (e.g. diabetic patients), a fibrin-based scaffold has been used to target a vector encoding eNOS to the wound site. This enhances transfection efficiency of the vector resulting in greater eNOS expression, greater production of NO and better healing in an impaired wound model.Hernia repair
Hernia operations are among the most common surgical procedures performed today with over 20 million cases annually worldwide. Hernia incidents rates are 27% for males and 3% for females over their lifespan, with complications ranging from associated with mild pain, poor quality-of-life for the patient and in rare causes potentially fatal. According to USA healthcare vital statistics between 2000 and 2009 16438 people died due to hernia related complications. Thus, leading to enormous healthcare costs, exceeding US$48 billion in the US annually. At present, hernia operations rely heavily on non-degradable polypropylene,Ophthalmics
Corneal diseases are the major cause of vision loss worldwide. Every year approximately 10,000,000 people are affected by various eye disorders and require corneal transplantation. Tissue grafts, including amniotic membranes, constitute the gold standard in clinical practice. However, their use is restricted because they are subject to drawbacks such as immune rejection, possibility of infections and donor shortages, especially after the wide spread of laser operation. Although synthetic materials have been shown to achieve cell infiltration and nerve regeneration, preclinical data demonstrate that such materials are positive for smooth muscle actin staining, which indicates activated myofibroblasts and the potential for scarring. NFB develops scaffolds and scaffold-free approaches for cornea regeneration.Regenerative functional neural constructs
Treatment of peripheral nerve injury and spinal cord injury is another important clinical target for NFB. The peripheral nerve system has an intrinsic ability to regenerate itself and does so naturally for small nerve injuries (<5mm in length). Treatments of peripheral nerve injuries that are larger than this relatively short nerve gap require microsurgical intervention. Large gaps require the use of donar nerve (autograft) or regenerative constructs for repair. Current clinically available constructs (hollow nerve guidance conduits) are failing to adequately repair these injuries. Research in the NFB focuses on devising new strategies for repair of peripheral nerve injuries using a combination of biomaterials and tissue engineering methodologies. Regeneration of the central nervous system is much poorer than the peripheral nervous system and does not show the same capacity to regenerate itself. This is primarily due to the multifaceted nature of spinal cord injury. The multifaceted nature of spinal cord injuries presents a major challenge to therapeutic development however, as primary mechanical trauma to the cord induces secondary injury consisting of a complex cascade of molecular events that lead to the loss of the conductive myelin sheath (myelin degeneration) and the formation of an inhibitory glial scar. Transplantation of peripheral nerve grafts and/or the introduction of a variety of cell types has resulted in axon regeneration with limited functional improvement after spinal cord injury in animal models, while structural constructs have been shown to aid and direct neurite growth. Molecular therapies that either promote regeneration, such as administration of neurotrophic factors (NGF, NT-3, GDNF), or target deleterious inhibition of regeneration, such as chondroitinase ABC, have also yielded favourable results. Despite significant progress in the laboratory limited demonstration of functional improvement in in vivo models has prevented regenerative therapies reaching the clinic to date. In order to devise viable treatment for clinical applications, current work in the NFB is combining the positive aspects of various therapeutic approaches.Drug delivery systems for treatment of pain
The prevalence of chronic pain in Ireland is estimated at 13% of the total population. Pain impacts negatively on quality of life and ability to conduct everyday activities, with economic implications through loss of time from work. Therapeutic intervention using current pharmaceuticals achieves satisfactory pain relief in less than 50% of chronic pain patients. There is a need to develop novel treatments for pain and to examine the potential for novel drug delivery systems to improve the efficacy of drugs currently available. Appropriate design of drug delivery systems may reduce adverse side-effect profiles, reduce drug degradation and loss, increase bioavailability and target the therapy to the site of interest. Current research at NFB involves the development of drug delivery platforms that facilitates the targeting of analgesic therapies to peripheral sites of action.Neurodegenerative disease
Parkinson's disease occurs in a variety of forms and with a largely unknown etiology. However, this disease is characterised by the loss of the dopaminergic neurons in the basal ganglia, leading to the familiar symptoms such as a resting tremor, bradykinesia (slowness of movement) and rigidity. Current therapies, although very effective at treating the symptoms, do not halt the dopaminergic neuron loss. Research at NFB is aimed at using polymeric gene therapy systems to halt the progression of neuron loss through neuroprotective routes.Regenerative strategies for cardiovascular treatments
Preclinical studies and preliminary data derived from clinical trials indicate the potential for the use of gene therapy or stem cell therapy for cardiovascular applications. At the NFB, the goal is to take gene or stem cell therapy and combine it with biomaterial delivery systems to enhance efficacy and improve control. The clinical targets are both ischemic muscle injuries, the first in the myocardium itself ( myocardial infarction), and the second is in the lower limb (lower limb ischemia). The choice of gene in the case of biomaterial-mediated gene therapy is also a major focus of the NFB, as novel gene therapy modalities such as miRNA and siRNA knock-down of genes are untested options. The ultimate goal of the NFB cardiovascular group is clinically relevant regeneration or repair after ischemic injury using biomaterial-based therapies.Industry
While NFB's core service centres on academic research and development within the University, much of the work carried out at NFB facilitates the development of collaborations with the medical device, pharmaceuticals and biotechnology industry both nationally and internationally. The main services NFB offers to industry include: development of unique biomaterial platform technologies, adding value to existing platforms, development of custom-made biomaterials, trouble-shooting biomaterial-based issues in medical devices, in vitro/in vivo studies and developing biomaterials for drug delivery. The NFB technology platforms that are currently available for licensing are as follows: #Porous titanium construct for orthopaedic applications #Collagen based multi-channel neural conduit #Extracellular matrix scaffold for wound closure #Hollow core nano-spheres in a range of biodegradable materials #PEG-based polymeric linkage systems for linking biomolecules and drugs #Injectable PEG based hydrogel system #Smart/responsive PEG based dendritic/hyperbranched polymers #Degradable pH and reducible responsive non-viral transfection vectors #High grade PLGA and PCL #Cell-sheet technologies #Various ECM moleculesReferences
External links
*Official website