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Polymers and Self Assembly: From Biology to Nanomaterials

Thursday Speaker Abstracts

Inorganic Silica and Rare Earth Phosphate Polymerization at Cellular Interfaces

C Jeffrey Brinker

1,2

.

1

Sandia National Labs, Albuquerque, NM, USA,

2

Univeristy of New Mexico, Albuquerque, NM,

USA.

Our work explores the cellular processing of nanoscale materials to form new bio/nano interfaces

and organisms. We have shown that yeast, bacterial, and mammalian cells introduced into self-

assembling solutions of phospholipids and soluble silica, direct the formation of unique

silica@cell interfaces and architectures through cellular response pathways. The association of

silica with cellular interfaces has been further explored in recent work, where we have

discovered a process, Silica-Cell-Replication, wherein mammalian cells direct their exact

replication in silica. The silica cell replicas preserve nm-to-macro-scale cellular features on both

the cell surface and interior after drying at room temperature - and largely after calcination to

600 ̊C. The process is self-limiting and self-healing, and remarkably generalizable to any cells of

interest—from red blood cells to neurons. Our current hypothesis is that, due to comparable

hydrogen bonding strengths, silicic acid molecules replace bound water at cellular interfaces and

are amphoterically catalyzed by proximal proteins and other membrane bound components to

form a self-limiting, defect-free, nm-thick silica encasement that resists drying stress and

preserves key features of biofunctionality. We recently reported the exceptional ability of rare

earth oxide nanoparticles to desphosphorylate mammalian endosomal compartments following

non-specific internalization by macropinocytosis or phagocytosis. The dephosphorylation

pathway, which is shared by all trivalent rare earth oxides, involves the irreversible formation of

highly insoluble rare earth phosphates from any bio-available phosphorous source. Questioning

whether rare earth oxides (REO) would desphosphorylate bacterial cell membranes, we tested a

library of REO nanoparticles against Gram negative Escherichia coli and Salmonella enterica

and Gram positive Staphylococcus aureus and found in all cases the formation of rare earth

phosphates with needle or urchin-like structures and retained viability for exposure levels up to

100µg/ml. These rare earth phosphate modified bacteria represent a new living biotic/abiotic

material/phenotype.