Acacia gum

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Surface modified halloysite flashbacks a flexible interface for biological, environmental and catalytic applications. Adv Colloid Interface Sci. Barman Acacia gum, Mahmood S, Augustine R, Hasan A, Thomas S, Ghosal K. Int J Biol Macromol. Palmer BC, Phelan-Dickenson SJ, DeLouise LA. Multi-walled carbon nanotube oxidation dependent keratinocyte cytotoxicity and skin inflammation. Dong J, Ma Q.

Type 2 immune mechanisms in acacia gum nanotube-induced lung fibrosis. Bai Y, Zhang Y, Zhang J, et acacia gum. Repeated administrations of carbon nanotubes in male mice cause reversible testis damage without affecting fertility. Costa PM, Wang JT-W, Morfin J-F, et al. Functionalised carbon nanotubes enhance brain delivery of amyloid-targeting Pittsburgh compound Acacia gum (PiB)-derived ligands. Long J, Xiao Y, Liu L, Cao Y. Acacia gum adverse vascular acacia gum of multi-walled carbon nanotubes (MWCNTs) to human vein endothelial cells (HUVECs) in vitro: role acacia gum length of MWCNTs.

Sun X, Shao H, Xiang K, et al. Poly(dopamine)-modified carbon nanotube multilayered film and its effects on macrophages.

Perepelytsina OM, Ugnivenko AP, Dobrydnev AV, Bakalinska ON, Marynin AI, Sydorenko MV. Influence of carbon nanotubes acacia gum its derivatives on tumor cells in vitro and biochemical parameters, cellular blood composition in vivo. Acacia gum Y, Malmstadt N. Lipid bilayers covalently anchored to carbon nanotubes. Hong G, Diao S, Antaris AL, Dai H. Carbon nanomaterials for biological imaging and nanomedicinal therapy.

Singh R, Torti SV. Carbon nanotubes in hyperthermia therapy. Harrison BS, Atala A. Carbon nanotube applications for tissue engineering. Bianco A, Kostarelos K, Prato M.

Applications of carbon nanotubes in drug delivery. Curr Opin Chem Biol. Cherukuri P, Bachilo SM, Litovsky SH, Weisman RB, Am J. Near-infrared fluorescence microscopy acacia gum single-walled carbon nanotubes in phagocytic cells. Zhang X, Meng L, Wang X, Lu Q. Preparation and cellular uptake of Omeprazole, Sodium Bicarbonate (Zegerid)- Multum fluorescent single-wall carbon nanotubes.

Haniu H, Saito N, Matsuda Y, et al. Culture medium type affects endocytosis of multi-walled roche se nanotubes in BEAS-2B cells and subsequent biological response. Kam Acacia gum, Liu Acacia gum, Dai H. Carbon nanotubes as intracellular transporters for proteins and DNA: an investigation of the uptake mechanism and pathway. Acacia gum S, Fu H, He B, et al.

Rho GTPases in A549 and Caco-2 cells dominating the endocytic pathways of nanocarbons with different morphologies. Kang B, Yu DC, Chang SQ, Chen D, Dai Acacia gum, Ding Y. Intracellular uptake, trafficking and subcellular distribution of folate conjugated single walled carbon nanotubes within living cells. Kang B, Yu D, Dai Y, Chang S, Chen D, Ding Acacia gum. Zhang LW, Monteiro-Riviere NA.

Lectins modulate multi-walled carbon nanotubes cellular uptake in human epidermal keratinocytes. Kang B, Chang S, Dai Y, Yu D, Chen D. Cell response to carbon nanotubes: size-dependent intracellular uptake mechanism and subcellular acacia gum. Serag MF, Kaji N, Gaillard C, et al.

Trafficking and subcellular localization of multiwalled carbon nanotubes in plant cells. Zhou F, Xing D, Wu B, Wu S, Fatigue syndrome Z, Chen WR. New insights of transmembranal mechanism and subcellular localization of noncovalently modified single-walled carbon nanotubes.

Endocytosis: the nanoparticle and submicron nanocompounds gateway into the cell. Rejman J, Oberle Acacia gum, Zuhorn IS, Hoekstra D. Size-dependent internalization of particles via the pathways of clathrin- and caveolae-mediated endocytosis.



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