10.3.2 Local Anaesthesia
Incorporating nanoparticles in anaesthesia effectively draws the anaesthetic agent to
the area, which is targeted by magnets, in order to block the nerves. The
nanotechnology-based formulation of liposome has found wide clinical acceptance
due to its capacity to encapsulate several drugs (Allen and Cullis 2013). Apart from
liposomes, biopolymers, cyclodextrins, lipid nanoparticles and hydrogels are other
formulations that exert an anaesthetic effect with an added benefit of lower toxicity
of the local anaesthetic agent (de Paula et al. 2012). Even though in vitro studies on
the effect of these formulations have demonstrated promising results, there is a
paucity of clinical trials that can confirm their efficacy. The current research focuses
on using computer-controlled nanorobots added to the colloidal suspension and
applied to the patient’s gingiva from where it can reach the periodontal ligament
and dental pulp. The clinician shall have control over the nerve-impulse traffic and
monitor the release of the anaesthetic agent until the completion of the treatment,
after which the sensation can be immediately restored. Nanoanaesthesia is thus an
emerging concept that is expected to make dental procedures painless and atraumatic
in its real sense.
10.3.3 Dentin Hypersensitivity
Dentin hypersensitivity is caused by a larger number and increased diameter of the
dentinal tubules. Thus, dentin tubule occlusion via precipitation or blocking into the
tubules is the most commonly used mechanism to relieve dentin hypersensitivity.
The use of nanorobots to block the exposed dentinal tubules is implicated in
effectively preventing the stimuli from inducing a pain response (Zandparsa 2014).
Moreover, the effectiveness of polyethylene-glycol-coated maghemite nanoparticles
and nano-carbonate apatite containing dentifrices in dentin hypersensitivity treat-
ment is also being explored.
10.3.4 Diagnosis and Treatment of Oral Cancer
Early detection of cancer is a critical factor that decides the prognosis of its
treatment. Due to the nanoparticle’s small size, the functional surface area that can
bind to the cancer cells is vastly increased. The use of a wide range of nanomaterials
like silver, gold and quantum dots is being explored for the early diagnosis and
treatment of oral cancer. Quantum dots are inorganic semiconductor nanocrystals
(<10 nm) of cadmium selenide. These are used as probes for the diagnosis of oral
cancer. When used as an adjunct to MRI, these quantum dots that travel through the
blood help improve the visualisation of tumour sites (Chen et al. 2018). Gold
nanoparticles that can provide localised surface plasmon resonances at near-infrared
wavelengths are promising contrast agents for optical coherence tomography (Chen
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