Nanotechnology in Oral Cancer Prevention and Therapeutics: A Literature Review

Ritwika Kumar; Kunal Jha; Diplina Barman

doi:10.1055/s-0041-1732856

Indian Journal of Medical and Paediatric Oncology, Inhaltsverzeichnis

CC BY-NC-ND 4.0 · Indian J Med Paediatr Oncol 2021; 42(02): 146-152
DOI: 10.1055/s-0041-1732856

Review Article

Nanotechnology in Oral Cancer Prevention and Therapeutics: A Literature Review

Authors

Ritwika Kumar

¹School of Materials Science and Nano Technology, Jadavpur University, Kolkata, West Bengal, India
Kunal Jha

²Department of Public Health Dentistry, Kalinga Institute of Dental Sciences, KIIT University, BBSR, Bhubaneswar, Odisha, India
Diplina Barman

³Private Dental Practitioner, Hooghly, West Bengal, India

Abstract

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Keywords

oral cancer - nanotechnology - nanoparticles - cancer therapy - cancer prevention

Introduction

Since time immemorial, the word “nano” has improved its applications and has made way into the world’s daily performances. It has fabricated assumption about the tremulous shift in various aspects of engineering and medical sciences. This is a Greek word meaning “dwarf.” A nanometer (nm) measures one thousand millionth of a meter.[1] The American Chemical Society defined nanotechnology as the design (at the atomic, molecule, and supra molecular levels) characterization, production, and utilization of constitutions, equipment, and systems by controlling shape and size at a nanometer scale.[2]

Types of Nanoparticles

➤ Nanosuspensions are colloidal dispersions of nano-sized drug particles that are produced and synthesized by a suitable stabilizer. The size ranges from 30 to 100 nm.

➤ Nanoparticles (NPs) are of two types namely, nanospheres and nanocapsules.

Nanospheres are polymer matrices in which the drug is dissolved and dispersed.
Nanocapsules consist of polymer walls entrapping oil in the core where the drug is diffused. They have advantages of improved efficiency, reduction in toxicity levels, improved distribution, and observance.[3]

The different categories of NP include polymeric, solid lipid, magnetic, nanopores, quantum dots, polymeric micelles, ceramic NPs, nanowires, liposomes, dendrimers, nanoshells coated with gold, and ferrofluids.

NPs operate on innate immune systems and activate anticancer immune reaction. Innate immunity helps in maintaining the integrity of the body, by detecting and eliminating damaged cells, proteins, and immediate defense against foreign invading agents. Interaction of NPs with monocytes and macrophages has been widely studied in a range of cellular models in vitro and in vivo experimental animals. This depends on the route of entry into the body and on the consequent “coating” of the reactive NP surface with microenvironmental proteins. The ability of NPs to adsorb different types of molecules in a particular tissue microenvironment makes a huge difference in innate immunity to recognize them as foreign entities and to mount an inflammatory response.[4] [5]

Properties of Nanoparticles

Three layers are present in the NPs: the core, the surface layer, and the shell layer. Surface layer consists of metal ions, surfactants, and polymers. There are metallic NPs, nonmetal, ceramic, lipid, polymeric, and semiconductor NPs. The properties vary according to the available sizes and type of material.[6]

Super hard NPs are those which are sized below 50 nm. The malleability and ductility also vary. Magnetic materials show super para magnetism properties in some while quantum confinement Q-particles and surface plasmon resonance in some. Some show solar radiation in photovoltaic cells and enhanced diffusion at elevated temperatures owing to high surface area to volume ratio. Improved image resolution and contrast is another property of NPs because the NPs at approximating infrared wavelengths initiate localized surface plasmon resonances.[7]

Applications of Nanotechnology

NPs are used in targeted drug delivery and the controlled release of curative agents and the entire system of nanotechnology is an engineered technology with multiple applications. Recent and newer materials could be fabricated to impersonate the human bone crystal mineral structure and could also be used as dental restorative resin. Nanomaterials have been used in dentifrices and mouth rinses for improved oral healthcare. They are also used as dental adhesives, anticariogenic enamel polishing agent, and implant materials much more successfully than the conventional materials. They act as antimicrobial agents by preventing bacterial proliferation. Various nanosized carriers are efficiently involved in improving pharmacokinetics and accumulation reduces the adverse effect of antibiotics. The NPs are retained in our body for a longer time for achieving sustained therapeutic effects.[8] Commercial applications have tailored gold NPs as tools to detect targeted sequences of nucleic acids that are clinically scrutinized as potential curatives for malignant conditions along with other diseases[9] and to diagnose and follow up oral malignant conditions.[10]

Advantages of Nanotechnology

➤ Cost-effectiveness, appropriate time management, reduced patient anxiety as it is noninvasive.

➤ Biocompatible, easily synthesized, and has the potential to reach specific target molecules.

➤ Reduction in drug resistance, tumor recurrence, and metastasis prevention.

With increased dependency on the evidence-based-medicine, reviewing literature pertaining to diagnostic and therapeutic improvements in the application of nanotechnology is gaining importance. Thus, the aim of this literature review is to critically appraise the various researches that have been reported around the globe over the past few decades.[3] [11]

Disadvantage of Nanotechnology

There are certain health effects of NPs that should be considered. Various levels of toxicity have been reported for various nanomaterials. Toxicity of ferric NPs has been reported. There are reports showing prevalence of cardiovascular disease with the increased presence of particular matter in the air. Some of the NPs have been reported to cross blood–brain barrier, thereby challenging its application in the field of drug delivery.[11]

Background

Maxillofacial malignancies (oral cavity and oropharynx) are the sixth most common type of cancer globally. It invades local tissue, metastasizes, and has a high mortality rate. Although there have been improvements in the medical therapeutics, not much improvement in the survival rate has been observed over the past two decades. Oral cancer is often diagnosed at progressed stages when the malignant cells become aggressive and immune to curative medications. In India, five lives are lost hourly to oral cancer. The prevalence is higher in males as compared with females. Oral cancer incidence is 8.4 times higher in patients with smoking and tobacco chewing habits.[12]

Preventive measures are on a rise to restrict the increasing incidence and mortality of oral cancer. The prognosis of malignant lesions is dependent on the time of detection. Use of nanodetection systems is increasing, and has emerged as potential noninvasive systems bringing the detection sensitivity of biomarkers to nanoscale.[13] Early diagnosis of potentially malignant oral disorders like leucoplakia, discoid lupus erythematosus, erythroplakia, actinic keratosis, oral lichen planus, and oral submucous fibrosis would help in improving the prognosis of the lesion.[14]

Thus, recent diagnostic methods should be researched on with better clinical benefits that would accurately predict the risk of oral potentially malignant disorders, malignant transformation, diagnose oral cancer based on molecular targeting, provide ultrasensitive diagnosis strategies at nanoscale, created real-time markings for the extent of surgical resection margins, and evaluate oral cancer prognosis in an expedient way posttreatment.

Methodology

Article Selection for the Review

Original studies and review articles related to nanotechnology, history of development, clinical implications of nanotechnology in oral cancer prevention, and therapeutics published between 1990 and 2020 were considered for the study. A total of 200 articles were searched using various databases: SCOPUS, PUBMED, PUBMED CENTRAL, MEDLINE, and WEB OF SCIENCE database.

Nanotechnology-Based Therapeutic Approaches in the Treatment of Oral Carcinoma

Photodynamic therapy (PDT)
Stem cell therapy
Nanotechnology-based radiation immunotherapy
Ultrasound nanotheranostics
Drug-delivery systems based on nanotechnology in oral cancer therapy

Photodynamic Therapy

Ceron Jayme et al developed DNA polymer films (PFs), which she used as a drug delivery method for treating oral carcinoma. DNA-PFs integrated with a photoactive compound: chlorine aluminum phthalocyanine (DNA-PFs-AlClPc) were used to cram the growth prototype of oral squamous cell carcinoma (OSCC) cells. The cell viability was measured using flow cytometry post-application of DNA-PFs-AlClPc during PDT. A positive response was noted toward photostimulation with the light dosage including 300, 600, and 1200 mJ/cm². Reduced viability (30% at the highest dose [1200 mJ/cm]) and increased apoptosis were noted with escalating doses as compared with controls. Apoptosis was the main mechanism of cell death. This system recommends the application of DNA-PFs-AlClPc as a drug delivery system for active molecules in treating pathologies. This also indicates the potency of using nanostructure in novel ways to treat malignancies. DNA nanostructured films could also be made to use as a “curative material.”[15]

Eka-Putra et al conducted a study using PDT mixed to lipid platinum chloride NPs to inhibit the multiplication of OSCC. Lipid-platinum-chloride nanoparticles (LPC NPS) were formed by encapsulating cisplatin (CDDP) into liposomes and anticancer effects in lesions like: liver cancer, bladder and melanoma models. A xenograft model of OSCC was used to revise the therapeutic effect of PDT+LPC and a significant decrease in the lesion volume was noted (~112%). Minimal side effects were noted in PDT+LPC or LPC treatment. PDT+LPC protracted inhibition of the growth of tumor cells that resulted in minimal chemotherapy curatives. A potential synergistic activity of chemotherapeutic efficacy resulted.[16]

Zhu et al put forward a proposal where he used ferroptosis-promoted PDT based on biochemical characteristics of cellular ferroptosis, which resulted in enhanced PDT efficacy due to them by generation of reactive oxygen species and O₂ feasibly via Fenton reaction.[17] Xue at al developed Trojan-Horse nanoparticle (pPhD NP) that was in dual size/charge—transformable for delivering ultra-small, fully active pharmaceutical ingredients nanotheranostics with incorporated dual-modal imaging and trimodal therapeutic activities.[18] Gupta et al reported the multitasking potencies of Ag-embedded ZnO nanocomposites (Ag-ZnO NCs). The improved photocatalytic and antibacterial activity of Ag-ZnO NCs is because of Ag NC anchorage onto ZnO along with minor substitution of Ag ions in the lattice of ZnO.

Number of studies have reported that Ag₅-ZnO NCs destroys oral carcinoma cells under visible light irradiation, by working as photosensitizers toward PDT of malignancy due to the outstanding photocatalytic activity.[19] Chu et al used both the photothermal and photodynamic inactivation of cancer cells using surface plasmon resonance of Au nanoring.[20]

Stem Cell Therapy

Studies have established stem cell markers to cooperate a prominent role in improving the efficiency of chemotherapy and as a salient agent for targeted anticancer therapy. The efficiency of targeted cell therapy directs the need to investigate for novel biomarkers in rare orofacial cancers including oral malignancies and salivary gland malignancies and to detect the commonest malignant stem cell markers potent as indicators for premalignant lesions, progression, and the treatment of the malignant lesions. Stem cell markers are gene expression agents that are exceptionally related to stem cells. The distinctive stem cell markers are suggestive of being components of a core regulatory system in embryological mechanisms that are superintended for self-renewal, maintaining an undifferentiated state, and reorganizing adult cells. Similarly, the cancer stem cells (CSCs) present in the oral cavity cancer articulate couple of these core regulatory network proteins.

There are various techniques to isolate the CSCs and identify stemness related genes include:

Flow cytometry
Sphere formation-based techniques
Side population cells[21]

The stemness-related markers include:

C OCT4
NANOG
SOX2

Stem cells' surface markers include:

CD44
CD133
ALDH
CD117
CD24
CD147
Musahi-1
c-MET
BMI1
LGR5
Renin-angiotensin markers[22]

CSCs are measured as significant targets for cancer therapy. Ma et al and Benezra et al coated CSCs with polyethylene glycol (PEG). Their size (< 10 nm) provided better biodistribution in a melanoma model and a prominent brightness was achieved by using NP-infused fluorescent dye. Pan et al proved that magnetic NPs are a suitable magnetic resonance imaging agent as they respond well to external magnetic fields.

Vitamin C donates electron and indulges in various biochemical activities in stem cell, synthesis of collagen, and in regulating hypoxia-inducible factor synthesis, affecting extracellular matrix remodeling and metastasis. Metered vitamin C dosages inhibit glycolysis of malignant cells and wedges synthesis of nitroso compounds indicating the impending of vitamin C in cancer therapy. Studies revealed vitamin C to enhance cancer's immune response to anti-PD-L1 treatment through various indirect methods.[23]

Nanotechnology-Based Radiation Immunotherapy

Localized radiotherapeutic techniques could utilize α NPs in targeting tumor cells, which could help in identifying epitopes to improve immune responses. Min et al at North Carolina University reexperimented with a melanoma model with absolutely no cure. They used NPs that captured antigen to deliver tumor-specific epitopes toward antigen-presenting cells. An improved T cell response with a cure rate of 20% resulted after delivering them to the lymphocytes.

Lower growth rates were observed in the cells present in the center of the spheroid due to hypoxia (usually compensated by angiogenesis) and reduced exposure to growth factors. Tumor geometry is important to nanotechnology in delivering antigenic NPs and for local treatment effects of NPs, including radioactive AuNPor from Au NP used in hyperthermia.

Ultrasound Nanotheranostics

Ultrasound imaging and therapy are growing in demand in present times with the use of various organic nanomaterials like acoustic protein nanostructures,[24] polymer-based nanomaterials,[25] porphyrin- and cyanine-based dyes,[26] [27] and inorganic nanomaterials including carbon-based nanomaterials,[28] metallic nanomaterials,[29] and perfluorocarbon (PFC) nanodroplets.[30] NPs enhance precision ultrasound imaging, including TME responsive ultrasound imaging, photoacoustic imaging, and phase-change imaging. It also plays a synergistic role in ultrasound therapy, in sonodynamic therapy (SDT),[31] high intensity focused ultrasound (HIFU) ablation,[32] and on-demand drug release controlled by ultrasound.[33]

Cancer treatment today includes newer, noninvasive, deeper tissue-penetration, and promising therapeutic techniques such as SDT. It activates sonosensitizers to produce huge amounts of high energy oxygen-containing molecules thereby inducing necrosis or cancer cell death under low-intensity ultrasound irradiation.[34] [35] The inorganic semiconductor TiO2 NPs can be efficiently used in SDT because it can penetrate deep into tissues thereby achieving a satisfactory therapeutic outcome.[36]

HIFU ablation efficiency is increased by using multifunctional silica nanocapsules with coencapsulated superparamagnetic magnetite NPs and liquid PFC simultaneously improved cancer diagnostic efficacy.[37] Mesoporous silica materials are used for ultrasound-assisted drug delivery due to its high loading capacity, robustness, suitability for surface modification, and biocompatibility.[38] Newer developments include phase-changeable, folate-targeted perfluoro hexane (PFH) nanodroplets which are infused with 10-hydroxycamptothecin (HCPT) and superparamagnetic iron oxide (Fe3O4) (designed as FA-HCPT-Fe3O4-PFP) for tumor-targeted curatives.[39] Ultrasound-enhanced immunotherapy is a promising and effective therapeutic approach for cancer.[40]

Nanotechnology-Based Drug-Delivery Systems in Oral Cancer Therapy

Polymer-based, lipid-based, and metal-based nanocarriers are few of the preclinical models of NPs that have been enveloped to evaluate the treatment of oral cancer. PH-sensitive PDPA (poly (2-[methacryloyloxy] ethyl phosphorylcholine) and PMPC (poly [2-diisopropylamino] ethyl methacrylate) polymersomes were used to summarize and distribute chemotherapeutic agent to the tumor cells to study the improved collective anticancer therapy. PMPC-PDPA polymersomes increase the cytotoxic effect of chemotherapeutic agents when they encapsulate Dox and paclitaxel for either individual or combined drug-delivery systems.[41]

Endo et al used cisplatin to evaluate the safety and usefulness of loaded polymeric nanomicelles (NC-6004) in OSCC therapeutics. In OSCC therapeutics, polymeric nanomicelles developed by conjugating Dox, and an autophagy inhibitor, LY294002 (LY) exposed that LY-loaded HPAH-DOX nanomicelles repressed tumor-cell proliferation in a synergistic manner.[42] Gold–silica nanoshells infused with anti-HER2 nanobodies when applied as photothermal therapy (PTT) were found to be a potential OSCC therapeutic technique. Dox-loaded nanocarriers in the structure of silica-coated gold nanoflowers used in combination with near-infrared PTT in human tongue SCC Cal27 cells induced rapid drug release.[43] DOX–methotrexate NP systems were able to decrease expression levels significantly for vascular endothelial growth factor C (VEGF-C) in addition to promoting apoptosis. Chitosan NPs loaded with cupreous complexes provide promising results in the in vivo mouse model of KB tumor.[44]

Natural compounds possessing proapoptotic effects like ellagic acid, curcumin, and phenolic antioxidants loaded on chitosan biopolymeric nanocarrier could be used in oral cancer therapeutics.[45] [46] The biodegradable polymer poly(lactic-co-glycolic acid)–PEG is utilized for creating polymeric self-assembled NPs because of its high cellular uptake and superior apoptosis properties on oral cancer cells.[47] Nanodelivery of RNA could serve as a promising oral cancer therapeutic procedure.

Imai et al in his study reported that HIF1 decoy oligodeoxynucleotides caused hypoxia-mediated expression of VEGF in tumor angiogenesis.[48] NPs present in the proliferating basal layer help in the local delivery of chemotherapeutic agents.[49] HIF1α siRNA combined to anis amide-targeted lipid–calcium–phosphate NPs and combined PDT-PTT therapy is an emerging treatment approach for oral cancer that uses rose Bengal-conjugated graphene nanoribbons specific to oral cells.[50]

Scientists have been targeting boron neutron-capture therapy with the use of nanocarriers for selectively building tumor-targeting compounds including boron and neutron irradiation.[51] Tongue carcinoma patients were benefitted from the association of ultrasound and bubble liposome that introduced plasmid into the tongue tissue.[52] Cu liposomes added to head and neck squamous cell carcinoma visualization have been efficient in the early diagnosis and staging of oral cancer also.[53] Naringenin-loaded NPs possess an antitumor effect for the chemopreventive strategy for OSCC. Graphene NPs-coated cetuximab showed enhanced survival and reduced tumor size in an in vivo model due to prominent radiation absorption.[54] NPs get accumulated in the internal organs commonly and elimination is a difficult task.[55]

The biological effectiveness of epigallocatechin gallate (EGCG) was improved due to induced apoptosis and reduction in angiogenesis by 10-fold. Using EGCG was beneficial in nanochemo-prevention when used as a sustained bioactive food release.[56] Prabhu et al generated an aspirin, curcumin, and sulforaphane (ACS) combination in solid-liquid nanoparticles that were used to perform multimodal targeting of pancreatic cancer. It was observed that nanoencapsulated ACS regimens reduced tumor incidence by as high as 75% at doses 10 times lower than free drug combinations.[57]

In the near future, NPs-mediated drug delivery of RNAi in the diagnosis and cure of HPV as an increased risk factor for cervical or oral malignancies could prosper. Improvement in nanoencapsulation methods could enhance the RNAi release or anti-inflammatory agents. Eventually, it is our responsibility to import the best efforts in prevention and best utilize nanotechnology.

Conclusion

Nanotechnology is gaining recognition in its application in diagnostics of oral cancer. It could be used in various combinations in the therapeutics aspects of oral cancer also. The changing trends of diseases and improvements in science and technology have led the world to look toward various alternatives including nanotechnology and its increasing applicative sensitivity toward diagnosis and treatment of oral malignancies.

Referenzen

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