Although mentions of nanoparticles in relation to biomedicine appeared in the late 1970s and are now the subject of over 10,000 publications per year, the term Nanomedicine only appeared at the turn of this century, and less than 30 papers including this term were published up to 2005. Ten years later, Web of Science indicates the publication of more than 1000 Nanomedicine articles in 2015 among more than ten times more articles involving nanoparticles for biomedical usage. Nanomedicine has been defined by the European Science Fundations forward Look Nanomedicine as follows: Nanomedicine uses nano-sized tools for the diagnosis, prevention and treatment of disease and to gain increased understanding of the complex underlying patho-physiology of disease. The ultimate goal is to improve quality of life. [1]. It involves the three nanotechnology areas of diagnosis, imaging agents and drug delivery with nanoparticles in the 11000 nm range, bioships (from both top-down and bottom-up sources) and polymer therapeutics [2,3]. A relevant more recent terminology is that of theranostics [4,5] involving both diagnostics and therapy with the same nanopharmaceutics.
In fact, Nanomedicine can be traced back to the use of colloidal gold in ancient times [6,7], but Metchnikov and Ehrlich (Nobel Prize for Medicine in 1908) are the modern pioneers of nanomedicine for their works on phagocytosis [8] resp. cell-specific diagnostic and therapy [9]. Seminal works on nanoparticles for nanomedicine were increasingly developed in the last 30 years of the 20th century and included liposomes [10,11], DNA-drug complexes [12], polymer-drug conjugates [13], antibody-drug conjugates [14], polymer nanocapsules [15,16,17], polymer-protein conjugates [18], albumin-drug conjugates [19], block-copolymer micelles [20], anti-arthritis gold nanoparticles [21] and anti-microbial silver nanoparticles [22]. These nanomedicines have various size ranges that are often not strictly within the standard definition of the nanoworld that is 1100 nm [23]. Clinical toxicities including side effects have been broadly studied and sometimes point toward patient individualization.
Problems that need be overcome are that most drugs are neither specific nor water-soluble. The above nanocarriers have been designed to first solubilize drugs in aqueous media, then serve as nanovectors toward specific targets and control drug release. A majority of nanocarriers used now allow oral drug delivery. Although these nanovectors are designed to translocate across the gastro-intestinal tract, lung, and blood-brain barriers, the amount of drug transferred to the organ is lower than 1%, therefore improvements are challenging [24,25]. Nanovector-drug assemblies are designed to maximize the benefit/risk ratio, and their toxicity must be evaluated not only by sufficiently long term in vitro and in vivo studies, but also pass multiple clinical studies. For biological assays, these nanomaterials must be characterized very strictly in a fully reproducible way [26,27]. Suitable nanocarriers (including metabolites) must be subjected to research of their antigenicity, immunotoxicity and possible activation of complements (that are a group of serum proteins that activates inflammation, destroys cells and participates in opsonization), pharmacokinetics, biodistribution, and drug release rates [28].
Tumor targeting drugs are a major focus in this context, and they use liposomes, polymers, micelles, conjugates, nanoparticles and conjugates of these nanopharmaceutics [29]. Two main routes are passive targeting using the enhanced permeation and retention (EPR) effect [30,31] and active targeting involving covalent drug attachment using linkers to a receptor that should be specifically recognized by the cancer cells [32]. Drug release rates and stability until the targeted cells are reached are key factors. Imaging using gamma cameras, magnetic resonance (MRI), position emission tomography (PET) and near infrared (NIR) luminescence and fluorescence are major techniques allowing one to quantize drugs in biological fluids and tissues. Active targeting using drug attachment to a receptor is a powerful concept that has been probed for several decades, but progress remains very slow, and positive in vitro results are only too rarely confirmed in vivo. For instance antibody-targeted radiotherapy was shown to localize less than 0.01% of the administrated dose to the tumor [32]. Evaluation of dose-dependent targeting is essential for pharmacological evaluation, and receptor saturation often occurs at low dose. Biomarkers are required in various nanomedicine technologies to measure the efficacy and safety of these drugs, because only a few % of drugs entering clinical investigation reach marketing approval [33]. Several families of new nanomaterials have attracted increased attention as nanovectors and theranostics in nanomedicine, in particular during the last decade:
Carbon materials that include fullerene (mainly C60), single-wall and multi-wall carbon nanotubes (SWCNTs and MWCTs respectively) [34], graphene oxide (GO) and nanodiamond (ND) [35]. Although these materials are insoluble in most solvents, including aqueous media, they can be polyfunctionalized with solubilizing groups such as polyethylene glycol, etc. The carbon cores of the functionalized carbon materials are essentially used as a scaffold, and tumor targeting and imaging using Raman signatures have potential. Although the problem of safety concerning these cores must be addressed, the functional groups ensure protection and penetration into organs. Long-term toxicity remains an issue, however, and clinical tests should be crucial.
Gold nanoparticles have a many centuries of historic tradition in therapeutics, but nanosciences has brought about novel theranostic concepts based on the medium-sensitive plasmonic absorption resulting from the visible and infrared light-induced collective oscillation of the surface electrons when the nanoparticle size is much smaller than the light wavelength [36,37]. Gold nanoparticle plasmons can be applied in various ways to nanomedicine [38,39,40], in particular photothermal therapy with gold nanorods and hollow gold nanoshells with plasmon bands in the near infrared region and various imaging techniques [37,40]. Gold nanoparticles indeed provide versatile scaffolds for cell surface sensing with the use of both specific recognition and array-based chemical nose approaches [41,42,43]. Passive tumor targeting with PEG for EPR effect and active targeting upon covalent linking to rhTNFa (CYT-6091) have reached anticancer clinical trials [44]. The preparation of gold nanoparticles and their functionalization are well controlled and reproducible, which is important for patenting, and the small size of these particles (<10 nm) represents an advantage compared with other nanoparticles that are probed for nanomedicine [36,45]. Although safety studies in vitro and in vivo are often contradictory, gold nanoparticles are considered as a standard for safety issues [46,47]. Silver and copper nanoparticles also present plasmonic properties, but the gold nanotechnology appears much superior to those of the lighter the group 11 elements. Nethertheless, nanocrystalline silver is well known for its established antimicrobial properties [48], although it is also cytotoxic [49].
Super Paramagnetic Iron Oxide Nanoparticles (SPIONs), usually magnetite, Fe3O4, are widely explored [50], despite their toxicity [51], in combination with a magnet for magnetic resonance imaging (MRI) and tumor ablation by hyperthermia. This technique has reached clinical use and phase II investigation in brain cancer (multiform glioblastoma) and also clinical study of non-metastatic prostate cancer [52]. Other oxide nanoparticles include silica (usually mesostructured silica) that is used to encapsulate drugs or SPIONs [53,54].
Quantum Dots (QD), binary semiconductor nanoparticles, are most often CdSe particles coated with ZnS or CdS. They are 210 nm dimension fluorescent imaging labels that are frequently used in nanomedicine [55,56] in spite of the toxicity of heavy metals [57].
Polymers and other macromolecules including co-polymers, antibodies, proteins, aptamers and dendrimers are intensively studied as drug nanovectors in nanomedicine [58,59,60,61,62]. A number of successful polymers are biodegradable and used in pre-clinical and clinical studies [63]. Major advances have been published, but important obstacles still remain concerning the use of encapsulated drugs in polymer nanoparticles including burst release, poor drug loading, and poor miscibility of some drugs with the polymer carrier [64]. Dendrimers that are cauliflower-shaped nano-scale macromolecules bearing many functional branch termini [65,66] have considerable capacity to encapsulate drugs and traverse biological barriers [67,68,69,70,71]. The dendritic microbiocide Vivagel was evaluated clinically [72]. Other commercial dendrimers [73] include Ocuseal, a microbial barrier [74], gadomer-17, a dendritic MRI [75], Stratus CS, a cardiac biomarker [76], Alert Ticket for anthrax detection, and Qiagen for in vitro DNA transfection [77]. Clinical trials are slow, however. Challenging problems remaining are purity, reproducibility, biodegradability and biocompatibility [78].
Various forms of liposomes have long been and remain among the most successful drug careers [79]. They include lipids, proteins, albumin, vesicles and related biopolymers and can involve combined drugs such as anti-cancer agents. Combination of imaging agents for diagnostics and drugs for therapy are examples called theranostics.
Many reviews cited in this introduction discuss the various clinical trials of these nano-drugs. Research in nanomedicine is exploding, but multi-phase clinical trials are very demanding. In the end, only a few nanodrug candidates successfully pass regulatory authority requirements. No doubt that interdisciplinary collaborations between biomedical scientists, chemists and biophysicists will in the future favor the arrival of more nanoengineered drugs on the market [80,81,82,83,84].
The author declares no conflict of interest.
Articles from Molecules are provided here courtesy of Multidisciplinary Digital Publishing Institute (MDPI)
Read the rest here:
Introduction to Nanomedicine - PMC
- Intratumoral self-assembly of renal-clearable gold nanoparticles as precise photothermal nanomedicine for liver tumor therapy - Science | AAAS - April 24th, 2025
- Design, Characterization, and Evaluation of Solid-Self-Nano-Emulsifying Drug Delivery of Benidipine with Telmisartan: Quality by Design Approach - ACS... - April 24th, 2025
- Ayurveda, green nanotech to usher in new medicine era - Times of India - April 5th, 2025
- Radioactive gold nanoparticles could track drug distribution in the body - Physics World - April 5th, 2025
- KIIT hosts international conference on recent advances in nanomedicine - Kalinga TV - February 24th, 2025
- Preclinical and First-in-Human Study of a Compact Radionuclide Labeled Self-Assembly Nanomedicine for Chemo-Radio-Theranostics of Cancer - ACS... - January 19th, 2025
- Post-doctoral Fellow in Drug Delivery, Nanomedicine & Advanced Therapeutics - Times Higher Education - January 6th, 2025
- Enhancing localized chemotherapy with anti-angiogenesis and nanomedicine synergy for improved tumor penetration in well-vascularized tumors -... - November 27th, 2024
- what is nanomedicine The British Society for Nanomedicine - November 16th, 2024
- Nanomedicine: Principles, Properties, and Regulatory Issues - October 6th, 2024
- Center for Nanomedicine - Johns Hopkins Medicine - October 6th, 2024
- Delivering the power of nanomedicine to patients today - October 6th, 2024
- Emerging Applications of Nanotechnology in Healthcare and Medicine - October 6th, 2024
- Tiny skin-stabbing stars designed to get meds through the epidermis - October 6th, 2024
- Inhibition of HIV-1 infection with curcumin conjugated PEG-citrate ... - October 6th, 2024
- Montgomery County, Kansas - Kansas Historical Society - October 6th, 2024
- The Nanomedicine Revolution - PMC - National Center for Biotechnology ... - October 6th, 2024
- Fawn Creek township, Montgomery County, Kansas (KS) detailed profile - October 6th, 2024
- Fawn Creek, Montgomery County, Kansas Population and Demographics - October 6th, 2024
- An Introduction to Nanomedicine - AZoNano - October 6th, 2024
- Nanomedicine Market is expected to show growth from 2024 to 2030, reported by Maximize Market Research - openPR - October 6th, 2024
- Oro Rx Healthcare LLP Unveils Oroceuticals: The Next-Gen Nutrition Delivery Tech - Hindustan Times - October 27th, 2023
- Leapfrogging as pharma leader of the worldNational Policy on Research and Development and Innovation in Pharma-MedTech Sector in India - The Sangai... - October 27th, 2023
- What will Indian healthcare look like in 2047? Robotics, AI, biotech will shape the future - The Economic Times - February 16th, 2023
- Going Beyond Target Or Mechanism Of Disease: Disruptive Innovation In Drug Delivery Systems - Forbes - September 12th, 2022
- Nanomedicine Market Size, Share, Types, Products, Trends, Growth, Applications and Forecast 2022 to 2028 - Digital Journal - September 12th, 2022
- Nano-preterm infants may not benefit from noninvasive versus invasive ventilation at birth - University of Alabama at Birmingham - September 12th, 2022
- Juan De Borbon - Introducing Cutting-Edge Techniques To The Healthcare Industry - CEOWORLD magazine - September 12th, 2022
- Organic thin-film sensors for light-source analysis and anti-counterfeiting applications - Nanowerk - September 12th, 2022
- Whole Exome Sequencing Market Projected to Reach CAGR of 19.0% Forecast by 2029, Global Trends, Size, Share, Growth, Future Scope and Key Player... - September 12th, 2022
- Another 'Dr. Copper' - MINING.COM - MINING.com - September 12th, 2022
- Artemisinin Combination Therapy Market Insights and Emerging Trends by 2027 - BioSpace - August 19th, 2022
- NASEM Recommends That EPA Conduct Ecological Risk Assessment of UV Filters Found in Sunscreen, Including Titanium Oxide and Zinc Oxide - JD Supra - August 19th, 2022
- Fast and noninvasive electronic nose for sniffing out COVID-19 based on exhaled breath-print recognition | npj Digital Medicine - Nature.com - August 19th, 2022
- Applications in Chronic Wound Healing | IJN - Dove Medical Press - July 25th, 2022
- Fundamental Knowledge on Nanobots - Bio-IT World - July 25th, 2022
- How different cancer cells respond to drug-delivering nanoparticles - MIT News - July 25th, 2022
- Nanorobots Market to close to USD 19576.43 million with CAGR of 12.23% during the forecast period to 2029 - Digital Journal - July 25th, 2022
- Microscopic Robots Made from White Blood Cells Could Treat and Prevent Life-Threatening Illnesses - Good News Network - July 25th, 2022
- Nano Therapy Market 2022 Growth Is Expected To See Development Trends and Challenges to 2030 This Is Ardee - This Is Ardee - July 25th, 2022
- Artificial Intelligence (AI), Cloud Computing, 5G, And Nanotech In Healthcare: How Organizations Are Preparing Best For The Future - Inventiva - July 25th, 2022
- Potassium Channels as a Target for Cancer Therapy & Research | OTT - Dove Medical Press - July 25th, 2022
- How can Nanotechnology be Used to Reverse Skin Aging? - AZoNano - May 20th, 2022
- Should Nanomaterial Synthesis Rely on Automation? - AZoNano - May 20th, 2022
- Fabrication Methods of Ceramic Nanoparticles - AZoNano - May 20th, 2022
- Explained: What are nanobots and how they can be used to help clean teeth? - Firstpost - May 20th, 2022
- Understanding the Health Risks of Graphene - AZoNano - May 20th, 2022
- Prevalence and predictors of SARS-CoV-2 | IDR - Dove Medical Press - May 20th, 2022
- Patches and robotic pills may one day replace injections - Science News for Students - May 20th, 2022
- Nanotechnology in the Nutricosmetics Industry - AZoNano - May 20th, 2022
- Nanomedicine: Nanotechnology, Biology and Medicine ... - December 22nd, 2021
- Frontiers | Nanomedicine: Principles, Properties, and ... - December 22nd, 2021
- Nanotechnology In Medicine: Huge Potential, But What Are ... - December 22nd, 2021
- Verseon Praised for Disruptive Approach to Physics- and AI-Based Drug Discovery - Digital Journal - December 22nd, 2021
- Nanotech opens up job options in variety of industries - BL on Campus - August 17th, 2021
- Homeopathic remedies that cattle farmers can use - Thats Farming - August 17th, 2021
- Healthcare Nanotechnology (Nanomedicine) Market Trend, Technology Innovations and Growth Prediction 2021-2027 The Manomet Current - The Manomet... - August 17th, 2021
- Regenerative Medicine Market Size Worth $57.08 Billion By 2027: Grand View Research, Inc. - PRNewswire - August 17th, 2021
- Nanotechnology Market Share, Industry Size, Leading Companies Outlook, Upcoming Challenges and Opportunities till 2028 - The Market Writeuo - The... - August 17th, 2021
- Global Nanomedicine Market is Expected to Grow at an Impressive CAGR by 2028 The Manomet Current - The Manomet Current - August 17th, 2021
- Complementary Protection May Be at Hand With a COVID-19-Preventing Nasal Spray - Newsweek - August 17th, 2021
- Nanorobotics Market By Player, Region, Type, Application And Sales Channel, Regions, Type and Application, Revenue Market Forecast to 2028 - Digital... - August 17th, 2021
- MagForce AG announces results of 2021 Annual General Meeting and changes to the Supervisory Board - Yahoo Eurosport UK - August 17th, 2021
- McMaster University researchers awarded more than $3M in Federal funds for projects - insauga.com - August 17th, 2021
- Global NANOTECHNOLOGY IN MEDICAL APPLICATIONS Statistics, CAGR, Outlook, and Covid-19 Impact 2016 The Bisouv Network - The Bisouv Network - February 14th, 2021
- Nanotechnology in Medical Market Demand Analysis To 2026 Lead By-Smith and Nephew, Novartis, Merck, Mitsui Chemicals, Amgen, Cytimmune KSU | The... - February 14th, 2021
- NanoViricides's Broad-Spectrum Antiviral Drug Candidate for the Treatment of COVID-19 Infections was Well Tolerated in GLP and non-GLP Animal Safety... - February 9th, 2021
- Nanorobots In Blood Market Top-Vendor And Industry Analysis By End-User Segments Till 2028 | Aries Chemical, GE Water & Process Technologies KSU... - February 9th, 2021
- Precision NanoSystems Receives Contribution from the Government of Canada to Build RNA Medicine Biomanufacturing Centre - PRNewswire - February 3rd, 2021
- Vaccine Production in BC's Future - AM 1150 (iHeartRadio) - February 3rd, 2021
- New facility to be built in Vancouver will produce 240 million vaccine doses annually | Urbanized - Daily Hive - February 3rd, 2021
- Faster tracking of treatment responses - MIT News - February 3rd, 2021
- NANOBIOTIX Announces First Patient Injected With NBTXR3 in Esophageal Cancer - Business Wire - February 3rd, 2021
- New Instrument Will Uncover Structure and Chemical Composition on Sub-Cell Scale - Georgia Tech News Center - January 12th, 2021
- Johns Hopkins Department of Otolaryngology-Head and Neck Surgery receives $15M contribution - The Hub at Johns Hopkins - January 9th, 2021
- COVID-19 Impact on Nanomedicine Market Size, Latest Trends, Growth and Share 2020 to 2026| Clinical Cardiology, Urology, Genetics, Orthopedics -... - January 9th, 2021
- Nanomedicine Market: Industry Analysis and forecast 2026: By Modality, Diseases, Application and Region - LionLowdown - January 9th, 2021
- Clene Nanomedicine Presents Blinded Interim Results from RESCUE-ALS Phase 2 Study at the 31st International Symposium on ALS/MNDResults provide... - December 16th, 2020
- Global Nanomedicine market 2020- Industry Overview, Global Trends, Market Analysis, CAGR Values and Country Level Demand To Forecast by 2027 -... - December 16th, 2020
- NHMRC awards Griffith University $4.5 million in research funding - Griffith News - December 16th, 2020
Tags: