1 measured by observing the movement of marker latex spheres added to colonies.

2 ked the cell movements and ability to propel latex spheres along their surfaces that are characterist

3                Cells of F. johnsoniae propel latex spheres along their surfaces, which is thought to

4                  Submicron particles such as latex spheres and viruses can be manipulated and charact

5       They also lacked the ability to propel latex spheres and were resistant to bacteriophages that

6 odified by choosing different mold patterns, latex spheres, and block copolymers.

7 mutants restored motility, ability to propel latex spheres, and sensitivity to bacteriophage infectio

8 amples of monodisperse 7-nm and 15-nm radius latex spheres, and then with B phycoerythrin.

9 rom the corresponding metal alkoxides, using latex spheres as templates.

10 od lengths from hydrodynamic models based on latex sphere calibrations.

11 t is shown that different types of submicron latex spheres can be spatially separated.

12 M(w)= 65000 Daltons, diameter = 8 nm) and to Latex spheres (diameter = 900 nm).

13 f PEG surface packing on monodisperse 200 nm latex spheres indicates that the size of the hydrophobic

14 hlights the report by Terray et al., who use latex spheres manipulated by optical traps to pump fluid

15  when tethered cells or cells carrying small latex spheres on flagellar stubs were shifted from H(2)O

16 preading, cell motility, the ability to move latex spheres, phage sensitivity, and the ability to dig

17                                  Polystyrene latex spheres (PSL) with aerodynamic diameters ranging f

18                                        Small latex spheres were attached to flagellar stubs on cells

19                                       We use latex spheres with diameters ranging from 190 to 780 nm

20     It was further found that precoating the latex spheres with nanoparticles (40-nm silica or 12-nm