Guarini, S. et al. Various cholinergic routes participate in an improvement caused by CCK-8, and ActH- (1–24) in a massive acute hemorrhage in rats. Harmac. Reserve Communication 19511–516 (1987).
Google Scholar
Fu, X. et al. Synthetic genomics: re -profiling of biological systems for use in engineering biology. ACS Synth. Biol. 131394–1399 (2024).
Google Scholar
Palluk, S. et al. DNA synthesis De Novo using conjugates of polymerase-nucleotide. NAT Biotechnology. 36645–650 (2018).
Google Scholar
McBride, LJ et al. The study of several deoxinucleoside phosphoraditis, useful for the synthesis of deoxyoligonucleotides. Tetrahedron Lett. 24245–248 (1983).
Google Scholar
Kosuri, S. et al. Large -scale DNA synthesis De Novo: technology and applications. Nat methods 11499–507 (2014).
Google Scholar
PEASE, AC et al. Svetrogenerated oligonucleotide arrays for a quick analysis of the DNA sequence. Prosecutor Natl Acad. Science of the United States 915022–5026 (1994).
Google Scholar
Singh-gasson, S. et al. The manufacture without a mask of light -filled oligonucleotide microchips using a digital micro -world massif. NAT Biotechnology. 17974–978 (1999).
Google Scholar
Hughes, tr et al. Expression profiling using microchips made using an synthesizer with oligonucleotide ink. NAT Biotechnology. 19342–347 (2001).
Google Scholar
Ghindilis, al et al. Combimatrix oligonucleotide arrays: genotyping and expression of genes using electrochemical detection. Biosena. Bioelectron. 221853–1860 (2007).
Google Scholar
Tian, ​​J. et al. An accurate multiplex gene synthesis from programmable DNA micromyp. Nature 4321050–1054 (2004).
Google Scholar
Kosuri, S. et al. Scaling genet synthesis by selective amplification of DNA basins from high -tech micromies. NAT Biotechnology. 281295–1299 (2010).
Google Scholar
QUAN, J. et al. Parallel synthesis of genes on the chip and use to optimize protein expression. NAT Biotechnology. 29449–452 (2011).
Google Scholar
Egeland, RD et al. Electrochemically directed synthesis of oligonucleotides for the manufacture of DNA microchips. Nucleic acids res 33E125 (2005).
Google Scholar
Moorcroft, Mj et al. Oligonucleotide synthesis In Situ on Paul (dimethylsigsan): a flexible substrate for the manufacture of microchips. Nucleic acids res 33E75 (2005).
Google Scholar
Sandahl, Af et al. On demand, the synthesis of phosphoraditis. NAT is common. 122760 (2021).
Google Scholar
Fodor, S. et al. Light, spatially addressed parallel chemical synthesis. Science 251767–773 (1991).
Google Scholar
Fodor, sp et al. Multiplexed biochemical tests with biological chips. Nature 364555–556 (1993).
Google Scholar
Roy, S. et al. The network of dissipative reaction leads to a transition bicycle with a solid and liquid -living phase cycle of nanoparticles. Angv. Chemical int. Editors 62E202217613 (2023).
Google Scholar
Qing, X. et al. Cation-coordinated internal spheres2 Au -water interfacing electrical inspection. J. am. Chemical social 1451897–1905 (2023).
Google Scholar
Pon, RT solid -phase support for the synthesis of oligonucleotide. Cards Prolk. Nucleic acid chem. 531-3 (2013).
Google Scholar
She, X. et al. Review of silicone carbide power devices and their use. IEEE TRANS. Ind. Electron. 648193–8205 (2017).
Google Scholar
Caruthers, MH et al. Chemical synthesis of deoxyoligonucleotides by phosphoradite. Fermol methods. 154287–313 (1987).
Google Scholar
Zhao, W. et al. A complete sequence of the genome Thermococcus EuryThermalis A501, conditionally perzophilic hyperthermophilic archeon with a wide temperature range isolated from a hydrothermal chimney in a deep-sea chimney, in the gouim basin. J. BIOTECHNOL. 19314–15 (2015).
Google Scholar
Leng, H. et al. Identification of deep -breaking thermophilic masonry sheds light into early bacterial evolution. NAT is common. 144354 (2023).
Google Scholar
Halper, SM et al. Synthesis success calculator: forecasting the rapid synthesis of DNA fragments using machine learning. ACS Synth. Biol. 91563–1571 (2020).
Google Scholar
Beltran, A. et al. Mutagenesis of saturation of the site 500 protein domains of a person reveals the contribution of the destabilization of protein to a genetic disease. Nature 625885–894 (2025).
Google Scholar
Yin, Yu. Et al. Long oligo: direct chemical synthesis of genes with nucleotides until 1728. Chemical science 161966–1973 (2025).
Google Scholar
Brook, ma et al. Strategies for improving the stability of silicone polymers. Macromolecules 583742–3763 (2025).
Google Scholar
Ding, G. et al. The manufacture of controlled separately standing ultratin porous defella membranes. Nanotechnology 161285 (2005).
Google Scholar
Topolska, M. et al. Deep indemed mutagenesis reveals the influence of inserts and delections on the stability and function of protein. NAT is common. 162617 (2025).
Google Scholar
Zhang. X. et al. The scaling of DNA synthesis using a massive parallel synthesis based on a microchip. Data sets. Chinese National Archive of the Genebank sequence https://doi.org/10.26036/cnp0007102 (2025).
