20.4
Conclusion
Diabetic neuropathy is a well-established outcome of both types of diabetes. Typi-
cally, diabetic neuropathy affects the toes and distal foot but eventually advances to
include the legs. The toxic effects of hyperglycemia are accepted to be a major factor
in the creation of this complication. Usage of antidepressants, GABA analogues,
opioids, and topical agents to treat pain in PDN is recommended. Currently available
systemic medications provide adequate pain relief for approximately half of affected
patients and are limited by unwanted adverse reactions and multiple-dose regimens.
So, other treatment options need to be explored in need to treat this widespread
complication of diabetes. siRNA demonstrated symptomatic relief in allodynia and
hyperalgesia associated with the downregulation of the P2X3 receptor in the dorsal
root ganglion and many other models. siRNA can be used as potential therapeutics to
treat DPN but are limited by its unstable nature under normal physiology in the blood
wherein it undergoes digestion by nuclease enzymes. So, its encapsulation in novel
Fig. 20.2 Molecular mechanism of siRNA-based nanocarriers in relieving neuropathic pain.
(1) siRNA delivery device enters the cell either through passive or active targeting. Active targeting
is facilitated by the attachment of antibodies or aptamers which enhance the specificity of the
device. (2) The siRNA nanocarrier then enters the cell. (3) The endosome engulfs the delivery
device. (4) Consequently, the outer carrier is degraded to release free siRNA therapeutics. (5) The
siRNA leads to the formation of an RNA-induced silencing complex (RISC). (6) The mRNA and
siRNA interact with each other to progress the knockdown of the desired mRNA. (7) The mRNA is
cleaved through the RISC to silence proteins involved in the pathology of neuropathic pain. (8) The
expression of the P2X7 receptor in the dorsal root ganglion, GluN2B peptide, and the calcitonin
gene-related peptide residing in the spinal cord is inhibited, all of which contribute to alleviating
neuropathic pain and show promise of siRNA nanocarriers as novel therapeutics. siRNA delivery
device alleviates neuropathic pain by inhibition of excitation transmission due to the P2X3 receptor
in the dorsal root ganglion as well as inhibition of expressed calcitonin gene-related peptide housed
in the spinal cord which alters the calcium-augmented pathways in neuropathy pain
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