1 ibutable to slower microbial processes (t1/2,
bio =
74 and 120 h, respectively).
2 The combination of
bio- and "photociphers" along with controlled timed-rele
3 may allow for highly sensitive detection of
bio- and chemical molecules with weak chirality.
4 or silver, are widely used in point-of-care
bio- and chemical sensing due to their role in enhancing
5 tical development of plasmonic circuitry for
bio- and chemical sensing, nanoscale optical information
6 Other
bio- and chemical surfactants tested had similar effects
7 For example,
bio- and chemo-catalysts can be combined in 'one pot' to
8 To implement new one-pot
bio- and chemo-catalytic processes, issues of incompatib
9 It depicts for researchers in
bio- and chemocatalysis a road map of challenges and opp
10 duce the global CO(2) footprint of plastics,
bio- and CO(2)-based feedstock are considered the most i
11 bility of a family of novel fully renewable (
bio- and CO(2)-based) poly(isosorbide-co-diol) oxalate (
12 scent technologies in the emerging fields of
bio- and composite-printing.
13 The gaps between
bio- and conventional plastics in food packaging are elu
14 ocyte (HaCaT) cell line was employed for the
bio- and cyto-compatibility testing prior to the hemolys
15 In this work, a route that combines
bio- and electrocatalysis to convert glucose into bio-ba
16 e of condensate-ion interactions in cellular
bio- and electrochemistry and may aid the design of cond
17 k is a step forward in this direction, where
bio- and electronic materials co-exist on one platform w
18 ofoundly affected today's composition of our
bio- and geosphere.
19 prediction of contaminants' behavior in the
bio- and geosphere.
20 amental problem of cell-membrane-penetrating
bio- and macro-molecules.
21 elf-assembled beta-helix as a self-contained
bio- and multi-functional motif for exploring and exploi
22 armaceutical and cosmetic products, and even
bio- and nano-technologies.
23 ipated that bPoNAs will have utility in both
bio- and nanotechnology.
24 interference, fundamental biochemistry, and
bio- and nanotechnology.
25 The production and turnover of EMM
bio- and necromass and total C were estimated by modelli
26 lysis of ergosterol (biomass), chitin (total
bio- and necromass) and total organic C (TOC) of sand-fi
27 mbining fundamental knowledge gained in both
bio- and organo-catalysis for asymmetric biocatalysis.
28 lease, production of pharmaceutics and food,
bio- and photocatalysis, thin-film solar cells and antib
29 the processes controlling Fe behavior during
bio- and photodegradation of colloids in boreal Fe- and
30 Altogether,
bio- and photodegradation of organoferric colloids, occu
31 ased relative to the parent HFO, likely from
bio- and photodegradation.
32 We compare the molecular composition of
bio- and photodegraded water-soluble organic (WSO) acids
33 itabine, lamivudine and zidovudine) via both
bio- and phototransformation processes, was investigated
34 ion of transformation products revealed that
bio- and phototransformation reactions took place at dif
35 Bio- and physicochemical analysis of the bks testa deter
36 A wide range of
bio- and physicochemical techniques, such as a new capil
37 allergen exposure due to the newly proposed
bio- and plant-based sustainable food contact materials
38 patterns that appear in several established
bio- and sensory-active peptides from independent source
39 cannot be achieved using other commonly used
bio- and synthetic polymers.
40 , giving rise to crystals with potential new
bio- and technological applications.
41 hols occupy a unique role in the structural,
bio-,
and geochemistry of silicon.
42 n coasts of PNG are contextualized with new (
bio-)
archaeological data.
43 In conjunction with
bio- chemical and physical parameters, such as gene expr
44 n can pave the way to new on-chip ultrafast (
bio-)
chemical spectroscopy devices.
45 ures in all branches of catalysis, including
bio-,
electro-, and photocatalysis.
46 s, and various important nanoceramics (e.g.,
bio-,
electro-, magnetic), are discussed.
47 or bearing thiol groups for the subsequent (
bio-)
functionalization via maleimide-thiol chemistry.
48 eochemistry and remains extensively used in (
bio-)
geoscience.
49 This study presents HITS-
Bio (
High-throughput Integrated Tissue Fabrication Syste
50 This provides nontargeted multi-element (
bio-)
imaging capabilities and the unique possibility to
51 ll lung cancer were used as part of the LACE-
Bio (
Lung Adjuvant Cisplatin Evaluation Biomarker) study
52 of photochromic molecules for task-specific
bio-,
material-, and medical-driven applications.
53 e assessment of muscle or polymer materials (
bio-)
mechanics.
54 In dynamic force spectroscopy, a (
bio-)
molecular complex is subjected to a steadily increa
55 crucial mediator of the interactions at the
bio -
nano -materials interface but is not well understo
56 t for the control of geometric parameters in
bio- nanotechnology.
57 miconducting/metallic core encapsulated in a
bio- or bio-derived materials are promising for applicat
58 ently occurs in nature and is often used by (
bio-)
organic chemists(7), enables a predetermined and si
59 ract rare gases as well as (129)Xe NMR-based
bio-,
pH, and temperature sensors.
60 rbon nanotubes (SWCNTs) functionalized with (
bio-)
polymers such as DNA are soluble in water and sense
61 the sensitive and selective readings of the
bio (
sensing) imprinted film.
62 r electronics, nanophotonics, and molecular (
bio-)
sensing.
63 cs and theranostics, as well as specialised (
bio-)
sensoring techniques.
64 Such SWCNT-based (
bio-)
sensors translate the binding of a molecule (molecu
65 cing eggplant growth parameters, followed by
bio- silver nanoparticles synthesized by B. cereus Nem 2
66 s-1 and is dimeric (hence two-headed); K365-
BIO (
vmax = 200 nm s-1) and K340-BIO (vmax = 90 nm s-1)
67 aded); K365-BIO (vmax = 200 nm s-1) and K340-
BIO (
vmax = 90 nm s-1) are monomeric.