ライフサイエンスコーパス: photopolymerize

1 structs were injected s.c. and transdermally photopolymerized.

2 ith only 2 min of light exposure required to photopolymerize an implant underneath human skin.

3 A vesicles were prepared by inkjet-printing, photopolymerized and characterized by dynamic light scat

4 These are then photopolymerized and covalently transferred to the surfa

5 Blue phase I was photopolymerized and the remaining liquid crystal remove

6 (STR) analysis using a streptavidin-modified photopolymerized capture gel injector for microchip capi

7 odroplets and encapsulation of stem cells in photopolymerized coacervate hydrogels under physiologica

8 By integrating photopolymerized cross-linked polyacrylamide gels within

9 rities with those obtained for the gas-phase photopolymerized (CS(2))(x) and the high-pressure-phase

10 We have photopolymerized diacetylene containing vesicles in the

11 The EPA particles were photopolymerized directly on the SAW devices in the pres

12 The capillaries with the photopolymerized frits had the best column-to-column rep

13 al types of frits, including sintered frits, photopolymerized frits, and frits made by sol-gel techno

14 Bulk photopolymerized hydrogels with uniform mechanical prope

15 model protein, was released for 1 week from photopolymerized hydrogels.

16 A hydrogel microplug, photopolymerized in a microfluidic channel, with negativ

17 The diacetylene units can be photopolymerized into polydiacetylenes that run coincide

18 report, we show that a novel capillary-based photopolymerized monolith offering unprecedented efficie

19 This in-column injector employs a photopolymerized oligonucleotide-modified acrylamide cap

20 id-doped reference membranes can be directly photopolymerized onto surface-functionalized poly(ethyle

21 A novel photopolymerized poly(acrylic acid) separator is demonst

22 ce biosensor is described that is based on a photopolymerized poly(ethylene glycol) (PEG) hydrogel in

23 ric detection of glucose were entrapped in a photopolymerized poly(ethylene) glycol diacrylate (PEG-D

24 Polymer microfluidic chips employing in situ photopolymerized polymethacrylate monoliths for high-per

25 y DNA extraction method is described using a photopolymerized silica-based monolithic column in a fus

26 The photopolymerized sol-gel (PSG) column shows reversed-pha

27 nt and sample stacking are investigated on a photopolymerized sol-gel (PSG) in capillary electrochrom

28 ration using capillary columns filled with a photopolymerized sol-gel (PSG).

29 Trypsin is covalently linked to a photopolymerized sol-gel monolith modified by incorporat

30 P) that is robust to a wide range of radical photopolymerizing systems, including thiol-ene and acryl

31 The micropatches are prepared by photopolymerizing the PEG precursor within the channel o

32 hotonic microparticles from the LC shells by photopolymerizing them into solids, retaining any select

33 aining (meth)acrylates and epoxides, rapidly photopolymerize to create crosslinked polymer networks o

34 ls; the patterned monomer crystals were then photopolymerized to form patterned thermoresponsive film

35 bilayers in predetermined architectures and photopolymerized to yield continuous hydrogel structures

36 ells were entrapped in hydrogel micropatches photopolymerized within microfluidic systems.