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RIVM report 265001001/2005 Nanotechnologyinmedical applications: state-of-the-art inmaterialsanddevices B. Roszek 1 , W.H. de Jong 2 and R.E. Geertsma 1 This investigation has been performed by order and for the account ofthe Department of Pharmaceutical Affairs andMedical Technology ofthe Dutch Ministry of Health, Welfare and Sports, within the framework of project V/265001, Support for Policy on Medical Technology. RIVM, P.O. Box 1, 3720 BA Bilthoven, telephone: 31 - 30 - 274 91 11; telefax: 31 - 30 - 274 29 71 Contact: Dr. B. Roszek, Boris.Roszek@rivm.nl 1 Centre for Biological Medicines andMedical Technology, RIVM 2 Laboratory for Toxicology, Pathology and Genetics, RIVM page 2 of 123 RIVM report 265001001 RIVM report 265001001 page 3 of 123 Abstract Nanotechnologyinmedical applications: state-of-the-art inmaterialsanddevicesNanotechnology is an extremely powerful emerging technology, which is expected to have a substantial impact on medical technology now andinthe future. The potential impact of novel nanomedical applications on disease diagnosis, therapy, and prevention is foreseen to change health care in a fundamental way. Furthermore, therapeutic selection can increasingly be tailored to each patient’s profile. This report presents the state-of-the-art inthe area of promising nanotechnology approaches for medical technology. In particular, relevant applications are reported in surgery, cancer diagnosis and therapy, biodetection of disease markers, molecular imaging, implant technology, tissue engineering, anddevices for drug, protein, gene and radionuclide delivery. Many medicalnanotechnologyapplications are still in their infancy. However, an increasing number of products is currently under clinical investigation and some products are already commercially available, such as surgical blades and suture needles, contrast-enhancing agents for magnetic resonance imaging, bone replacement materials, wound dressings, anti-microbial textiles, chips for in vitro molecular diagnostics, microcantilevers, and microneedles. Keywords: nanotechnology; medical technology; biosensors; molecular imaging; implants; cancer diagnostics; cancer therapy; in vitro diagnostics page 4 of 123 RIVM report 265001001 RIVM report 265001001 page 5 of 123 Rapport in het kort Nanotechnologie in medische toepassingen: stand der wetenschap in materialen en producten Nanotechnologie is een uitermate krachtige, opkomende technologie die op dit moment al toegepast wordt en in de toekomst een aanzienlijke invloed zal hebben op de medische technologie. Innovatieve nanomedische toepassingen kunnen de gezondheidszorg op fundamentele wijze veranderen, omdat er nieuwe mogelijkheden beschikbaar komen voor diagnose, behandeling en preventie van ziekte. Verder kunnen behandelmethodes in toenemende mate precies op maat worden gemaakt gebruikmakend van het profiel van de patiënt. Dit rapport geeft een overzicht van de “state-of-the-art” op het gebied van veelbelovende nanotechnologische ontwikkelingen in de medische technologie. Met name worden relevante toepassingen besproken in chirurgie, diagnose en behandeling van kanker, bepaling van ziekte-specifieke stoffen in het lichaam, beeldvormende technieken, implantaten, tissue engineering en toediening van geneesmiddelen, eiwitten, genen en radionucliden. Veel toepassingen van nanotechnologie in de medische technologie staan nog in de kinderschoenen. Een toenemend aantal producten wordt echter momenteel onderzocht in klinische studies en sommige zijn al commercieel verkrijgbaar, waaronder chirurgische mesjes en hechtnaalden, contrastmiddelen voor beeldvorming met magnetische resonantie, botvervangende materialen, wondbehandelingsproducten, antimicrobieel textiel, chips voor in vitro moleculaire diagnostiek, “microcantilevers” en micronaalden. Trefwoorden: nanotechnologie; medische technologie; biosensoren; moleculaire beeldvorming; implantaten; kankerdiagnostiek; kankertherapie; in vitro diagnostiek page 6 of 123 RIVM report 265001001 RIVM report 265001001 page 7 of 123 Summary Nanotechnology is an emerging technology seeking to exploit distinct technological advances of controlling the structure ofmaterials at a reduced dimensional scale approaching individual molecules and their organised aggregates or supramolecular structures. Basically, the nanometre-length scale is creating possibilities for novel materials that can be used for the construction ofdevicesand systems. Nanotechnology must be distinguished from the nanoscience enabling such technology. Basically, nanoscience is the study of phenomena and material properties at nanoscale, while nanotechnology is applying the resulting knowledge to create novel materialsand structures. Knowledge in nanoscience andnanotechnology is increasing worldwide, leading to great scientific advances. In turn, this is expected to lead to fundamental changes inthe way that materials, devices, and systems are understood and created. Application in life sciences research, particularly at the cell level sets the stage for an exciting role ofnanotechnologyin healthcare. In this report a general overview ofthe state-of-the-art in novel nanomaterials and recent advances ofnanotechnologyapplications are presented, focussing on promising medical applications. Relevant medical areas are surgery, therapy, diagnostics, imaging, implant technology, bionics, bio-active surfaces, tissue engineering, textiles, actuators, and delivery systems. Products which are either commercially available or currently being developed at several companies are also included, illustrating the significant progress and challenges in nanotechnology. Novel nanomaterials are envisaged to have a major impact on a number of different relevant areas. Materials with high performance and unique properties can be produced that traditional synthesis/manufacturing methods could not create. Carbon nanotubes and inorganic nanowires exhibit extraordinary mechanical, electric, electronic, thermal, and optical properties offering especially the electronic industry properties that few materials platforms could ever hope to match. Although nanotube/wire electronics has been speculated about for well over a decade, the first products are now about to reach the market or are beginning to appear inthe form of field emission displays, sensors, and non-volatile memory. Quantum dots (semiconductor nanocrystals) possess remarkable optical and electronic properties that can be precisely tuned by changing their size and composition. Due to their relatively inexpensive and simple synthesis quantum dots have already entered the market for experimental biomedical imaging applications. Dendrimers (complex spherical macromolecules) have improved physical, chemical, and biological properties compared to traditional polymers. Some unique properties are related to their globular shape andthe presence of internal cavities offering the possibility as medical nanovehicles. In addition to these examples of individual nanoparticles, new or enhanced materials can be constructed using structural surface modifications of macro-, micro- as well as nanomaterials. Essentially, an increase in surface area and roughness attributes to an enhancement of absorbent, adsorbent, and catalytic properties. Control of surface properties at nanolevel was shown to increase the biocompatibility ofthe materials. It is difficult to accurately predict the timescale of developments, but it is anticipated that within the next few years the application of nanomaterials and nanotechnology-based manufacturing will have an established role inmedical technology. Some surgical aids already benefit from nano-structured material, such as surgical blades with nanometre-thick diamond coating and surface roughness inthe same order of magnitude, and suture needles incorporating nano-sized stainless steel particles. Other nanotechnological approaches might allow for nanosurgery, a minimally invasive alternative to traditional surgery, based on nanoneedles and laser technologies such as optical tweezers and “nanoscissors”. page 8 of 123 RIVM report 265001001 Biomedical nanotechnology presents revolutionary opportunities inthe fight against many diseases. An area with near-term potential is detecting molecules associated with diseases such as cancer, diabetes mellitus, neurodegenerative diseases, as well as detecting microorganisms and viruses associated with infections, such as pathogenic bacteria, fungi, and HIV viruses. Macroscale devices constructed from exquisitely sensitive nanoscale components, such as micro-/nanocantilevers, nanotubes, and nanowires, can detect even the rarest biomolecular signals at a very early stage ofthe disease. Development of these devices is inthe proof-of-concept phase, though entering the market may be sooner than expected. However, a different approach of molecular sensing in vivo involves the use of implantable sensors which is still hampered by unwanted biofouling impairing long-term stability of continuous sensors caused by blood components and factors ofthe immune system. Nanotechnology might yield nano-structured surfaces preventing this non-specific protein adsorption. Molecular imaging is providing increasing power to studies of animal models of disease and is beginning to be used in clinical investigations as a non-invasive means of monitoring disease progress and response to therapeutics. Molecular imaging agents will allow clinicians to detect diseases in its earliest, most treatable, presymptomatic stage. Combination of precise targeting using specific antibodies and imaging enhancement properties of nanoparticles are the key to greatly enhance the power of magnetic resonance imaging, optical imaging, nuclear imaging and ultrasonic imaging. One ofthe great achievements foreseen is the ability to identify tumours that are far smaller than those detectable with today’s technology, before they are even visible with the human eye. The above described advances inmedical diagnostics are rivalled by the progress made in therapeutics enabled by nanotechnology. Especially inthe field of cancer therapy promising applications are being developed. Several novel nanoparticles will respond to externally applied physical stimuli in ways that make them suitable therapeutics or therapeutic delivery systems. For example, magnetic iron oxide nanoparticles, gold-coated silica nanoshells, and carbon nanotubes can transform electro-magnetic energy into heat causing a temperature increase lethal to cancer cells merely by increasing the magnetic field or by irradiation with an external laser source of near-infra red light at the very location where these nanoparticles are bound to or internalised within tumour cells. Moreover, the delivery of chemotherapy and photosensitisers to tumours, and activating them in situ is possible. Also in other areas, drug delivery is one ofthe major application fields for nanotechnology. Nanoparticle-mediated transport across the blood-brain barrier could not only provide an effective treatment for brain tumours, but also for other central nervous system related-diseases such as Alzheimer’s and Parkinson’s. Furthermore, non-viral gene delivery systems for gene therapy, nanoneedles for cell surgery and delivery of molecules into the cell nucleus, nanocrystalline silver particles with antimicrobial activity or haemostatic agents on wound care products, microchip-based drug delivery systems for programmable drug release, and nanoporous drug eluting coatings on stents are examples of new nanotechnologymaterialsanddevicesin drug delivery applications. Inthe future, a modular approach to construct delivery systems which combine targeting, imaging and therapeutic functionalities into multifunctional nanoplatforms may allow for new refined non-invasive procedures. These nanoplatforms would localise to target cells, enable diagnostics and subsequently deliver therapeutics with great precision. Such modular approaches to nanodevice construction can potentially be more powerful than current treatment modalities, but are inherently more complex than existing small molecule or protein therapeutics. Another important field of application for nanotechnology are biomaterials used for example in orthopaedic or dental implants or as scaffolds for tissue engineered products. If the design RIVM report 265001001 page 9 of 123 of for example a hip implant is carried out at nanolevel, it might become possible to construct an implant which closely mimicks the mechanical properties of human bone, preventing stress-shielding andthe subsequent loss of surrounding bone tissue. Furthermore, surface modifications at nanolevel of biomaterials or their coatings might greatly enhance the biocompatibility by favouring the interaction of living cells with the biomaterial, especially by their beneficial effect on cell adhesion and proliferation. Together with the control of nanoporosity allowing vascularisation andthe growth of cells inside the biomaterial, the nano-structured surfaces of biomaterials also allow the creation of novel types of scaffolds for tissue-engineered products. A promising approach for the latter application are nanofibres produced using self-assembling peptides with engineering functionality and biodegradability. Medicaldevices for in vitro diagnostics, such as gene-, protein- or lab-on-a-chip devices, do not have any ofthe safety concerns associated with nanoparticles introduced into the body. Numerous devicesand systems for sequencing single molecules of DNA are feasible. Nanopores are finding use as new nanoscale technology for cancer detection enabling ultrarapid and real-time DNA sequencers. In general, developments in protein-chips and lab- on-a-chip devices are more challenging compared to gene-chips and these devices are anticipated to play an important role in medicine ofthe future, which will be personalised and will combine diagnostics with therapeutics into a new emerging medical area called theranostics. Nanomedicine is now within the realm of reality, though there is some concern about the safety of nanoparticles introduced inthe human body. Research is in progress to address this issue. Examples ofmedicaldevices utilising nanotechnology, which are already on the market are surgical tools with enhanced properties, nano-sized contrast agents for molecular imaging, bone replacement materials constructed from nanostructured materials, pacemakers and hearing aids of reduced size and increased power, lab-on-a-chip devices for in vitro diagnostics, wound dressings containing nanocrystalline silver particles, microcantilevers, and microneedle-based systems for minimally invasive drug administration. Over the next ten to twenty years nanotechnology may fundamentally transform science, technology, and society offering a significant opportunity to enhance human health in novel ways, especially by enabling early disease detection and diagnosis, as well as precise and effective therapy tailored to the patient. page 10 of 123 RIVM report 265001001 [...]... page 11 of 123 Preface This report describes the state- of- the- artofmaterialsanddevicesinthe area ofnanotechnologyinmedicalapplicationsThe review was performed on the request ofthe Department of Pharmaceutical Affairs andMedical Technology ofthe Ministry of Health, Welfare and Sports inthe Netherlands The information gathered here is presented as basic information to staff of this department... technology inthe right perspective, it is necessary to have a basic understanding ofthe origin ofthe unique properties of nanomaterials Therefore this report starts with a short section explaining the definitions and features of nanoscience and nanotechnology, followed by a more elaborate overview ofthe novel nanomaterials and their specific properties which have opened the horizon for theapplications in. .. advances ofnanotechnologyapplicationsinmedical technology An overview of the state- of- the- artin nanomaterials and (medical) devices is given Relevant medical areas are surgery, therapy, diagnostics, imaging, implant technology, bio-active surfaces, tissue engineering, textiles, actuators, and drug/gene delivery materialsand systems Products that are already on the market or are currently being developed... properties determined by the size, folding, and patterns at nanoscale The genetic material desoxyribonucleic acid (DNA) is composed of four nucleotide bases in sizes ranging inthe sub-nanometre scale, andthe diameter of the doublehelix structure of DNA is inthe nanometre range The same is true for proteins and cell membranes which consist of lipids and proteins Manufacturing “non-natural” nanomaterials... applicationsinmedical technology which are described inthe main part ofthe report Furthermore, in this report greater emphasis is given on highlighting promising nanotechnology- based approaches inmedical technology than on consensus taxonomies of scientific/engineering disciplines RIVM report 265001001 page 17 of 123 2 Nanoscience andnanotechnology 2.1 Definitions In a recently published report of The Royal... biology/physiology is one ofthe exciting new page 16 of 123 RIVM report 265001001 frontiers ofnanotechnologyinthe field ofmedicalapplicationsNanotechnology will definitely be a strategic branch for science and engineering during the coming century It will fundamentally restructure the technologies currently used for manufacturing, medicine, communication, computation, transportation and many other application... blocks for the construction of complex integrated circuits Next to the concept of construction of nanowire-based electronic devices is the development of a feasible method for integration, reliable mass production, effective assembly techniques, and quality-control methods In order to maintain the growing rate of device density and functionality inthe existing electronics industry, new kinds of complementary... illustrate the significant progress innanotechnology 1.2 Methodology The state- of- the- artin nanomaterials anddevices was based on literature searches, internet searches, and proceedings of conferences Literature was identified from several sources including electronic databases and cross-checking of reference lists Electronic databases consulted were Scopus™ (Elsevier BV) and PubMed (US National Library of. .. research and industrial use In 1991, a new method of fullerene production was invented, providing basic engineering knowledge critical to scale up the process (Howard et al., 1991) This synthesis method involves the combustion of hydrocarbon fuel under sub-atmospheric pressure and makes economical production of higher fullerenes possible Refining and improving the production process is still continuing... focused on nanotechnology companies It should be noted that applicationsofnanotechnologyin drug discovery research, providing tools for a fast screening of large arrays of candidate substances, were not included inthe report Furthermore, applications on liposome-based drug delivery and viruses as delivery vehicle were excluded In order to be able to place thenanotechnologyapplicationsinmedical . basic understanding of the origin of the unique properties of nanomaterials. Therefore this report starts with a short section explaining the definitions and features of nanoscience and nanotechnology, . area of nanotechnology in medical applications. The review was performed on the request of the Department of Pharmaceutical Affairs and Medical Technology of the Ministry of Health, Welfare and. healthcare. In this report a general overview of the state- of- the- art in novel nanomaterials and recent advances of nanotechnology applications are presented, focussing on promising medical applications.