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The current pandemic of coronavirus disease 2019 (COVID-19), caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has had catastrophic effects on human society in several aspects, including social, economic, and public health.(,) Severe cases of the disease are often associated with respiratory, renal, and cardiovascular complications, as well as with other related risks.(,)
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COVID-19 and the increased risk of myopia and digital eye strain
DesideriLF, Tovani-PaloneMR. COVID-19 and the increased risk of myopia and digital eye strain. Einstein (Sao Paulo). 2021;19:eCE6491. https://doi.org/10.31744/einstein_journal/2021CE6491
Desideri,Lorenzo Ferro; Tovani-Palone,Marcos Roberto. COVID-19 and the increased risk of myopia and digital eye strain. Einstein (Sao Paulo)., v. 19, eCE6491, May. 2021. https://doi.org/10.31744/einstein_journal/2021CE6491
Desideri,L.F., & Tovani-Palone,M.R. (2021). COVID-19 and the increased risk of myopia and digital eye strain. Einstein (Sao Paulo).,19, eCE6491. https://doi.org/10.31744/einstein_journal/2021CE6491
Desideri,Lorenzo Ferro and Tovani-Palone,Marcos Roberto. COVID-19 and the increased risk of myopia and digital eye strain. Einstein (Sao Paulo). [online]. 2021, vol. 19, [cited 2026-06-28], eCE6491. Available from: <https://journal.einstein.br/article/covid-19-and-the-increased-risk-of-myopia-and-digital-eye-strain/>. ISSN 1679-4508. https://doi.org/10.31744/einstein_journal/2021CE6491
Figure 5
DNA triple helix (triplex) structures. A) Three-dimensional view of an intramolecular DNA triplex solved by solution-state nuclear magnetic resonance (PDB ID: 1BCB). The structure was deposited by Asensio et al. (1998) and classified as DNA without mutations.(20) This triple helical arrangement illustrates the association of a third strand with the canonical duplex, stabilized by Hoogsteen interactions. B) Simplified schematic (adapted from Brazda et al., 2020; and Holder et al., 2015) illustrating the principle of triplex formation.(22,23) The canonical duplex is stabilized by Watson–Crick base pairs, while the third strand binds in the major groove via Hoogsteen hydrogen bonds. The chemical structure shown in green corresponds to adenine from the third strand, forming a representative T·A·T triad with a Watson–Crick A·T base pair. Such alternative base-pairing interactions enable an additional strand to associate with duplex DNA through Hoogsteen hydrogen bonding, generating a triple-helical structure capable of modulating essential processes such as replication and transcription