1 e contrast generation is based inherently on
atomic absorption.
2 Blood lead was analyzed by graphite furnace
atomic absorption.
3 ) in the samples was measured by cold vapour
atomic absorption.
4 level of cellular copper, as demonstrated by
atomic absorption.
5 i+ exchange activity in intact RBCs by using
atomic absorption.
6 Atomic absorption analyses indicated that the mutant pro
7 Atomic absorption analysis and UV/vis spectroscopy indic
8 Atomic absorption analysis detected 1.6 mol of Zn bound
9 As demonstrated by
atomic absorption and extended X-ray absorption fine str
10 ortant Zn1 ligand is not consistent with the
atomic absorption and thermostability data obtained for
11 with a compact microwave plasma source as an
atomic absorption cell.
12 e article in the literature has demonstrated
atomic absorption detection of Ag, Cu, and Pd in solutio
13 This article describes a novel
atomic absorption device that employs a single source, t
14 d the determination of minerals was by flame
atomic absorption (
FAA).
15 ement with reference values using cold vapor
atomic absorption for the sample matrixes studied here.
16 spectroscopy technique clearly distinguishes
atomic absorption from (235)U and (238)U in natural and
17 asma gas flow rate, which are of benefit for
atomic absorption measurements.
18 Atomic absorption reveals significant differences in int
19 A repeatable
atomic absorption signal was produced.
20 The visible, EPR, and
atomic absorption spectra of the purified NrdENrdF compl
21 products by high resolution continuum source
atomic absorption spectrometer (HR-CS AAS) after leachin
22 h resolution continuum source electrothermal
atomic absorption spectrometer (SS HR-CS ETAAS).
23 x interference and can be easily analyzed by
atomic absorption spectrometer or inductively coupled pl
24 ; rubidium was quantified using an automated
atomic absorption spectrometer to enable screening of 10
25 on content of the two proteins determined by
atomic absorption spectrometer was almost the same.
26 ing a high-resolution continuum source flame
atomic absorption spectrometer with an air/acetylene fla
27 ith a high-resolution continuum source flame
atomic absorption spectrometer.
28 Laboratory-based
atomic absorption spectrometers differ from the original
29 ction (VA-IL-DLLME), was developed for flame
atomic absorption spectrometric analysis of aluminum (Al
30 a programmable flow for automatic cold vapor
atomic absorption spectrometric assays.
31 ater and vegetable samples followed by flame
atomic absorption spectrometric detection.
32 r(II) and lead(II) ions prior to their flame
atomic absorption spectrometric detections.
33 A slurry sampling electrothermal
atomic absorption spectrometric method is proposed for t
34 ns of lead and cadmium by a graphite furnace
atomic absorption spectrometric method.
35 tigated using a variety of probes, including
atomic absorption spectrometry (AAS) to monitor distribu
36 microflame quartz tube atomizer (MMQTA) for
atomic absorption spectrometry (AAS).
37 conventional quartz tube atomizer (QTA) for
atomic absorption spectrometry (AAS).
38 roscopy (ICP-OES), and mercury by cold vapor
atomic absorption spectrometry (CV-AAS).
39 etry (GFAAS); and for mercury by cold vapour
atomic absorption spectrometry (CVAAS).
40 r (IIP) sorbent combined with electrothermal
atomic absorption spectrometry (ETAAS) was developed for
41 ting reagent and detection by electrothermal
atomic absorption spectrometry (ETAAS) was developed in
42 ermined in eluent solution by electrothermal
atomic absorption spectrometry (ETAAS).
43 he detection of tin employing electrothermal
atomic absorption spectrometry (ETAAS).
44 ian carbonated soft drinks by electrothermal
atomic absorption spectrometry (ETAAS).
45 ere compared with those obtained using flame
atomic absorption spectrometry (F-AAS).
46 Flame and electrothermal
atomic absorption spectrometry (F-AAS, ET-AAS) were used
47 method was developed and combined with flame
atomic absorption spectrometry (FAAS) for pre-concentrat
48 manganese prior to determination using flame
atomic absorption spectrometry (FAAS) is proposed.
49 The ions were identified by flame
atomic absorption spectrometry (FAAS).
50 reals and vegetable food samples using flame
atomic absorption spectrometry (FAAS).
51 ped for the determination of copper by flame
atomic absorption spectrometry (FAAS).
52 croextraction (HF-SLPME) combined with flame
atomic absorption spectrometry (FAAS).
53 ), Cr(III), Pb(II), and Zn(II) ions by flame
atomic absorption spectrometry (FAAS).
54 determination of some trace metals by flame
atomic absorption spectrometry (FAAS).
55 I), Pb(II), and Zn(II) trace metals by flame
atomic absorption spectrometry (FAAS).
56 mples prior to their determinations by flame
atomic absorption spectrometry (FAAS).
57 ions in the samples were determined by flame
atomic absorption spectrometry (FAAS).
58 spice, vegetable and fruit samples by flame
atomic absorption spectrometry (FAAS).
59 ages samples has been established with flame
atomic absorption spectrometry (FAAS).
60 Quantitation is carried out by flame
atomic absorption spectrometry (FAAS).
61 f total Sn in some canned beverages by Flame
Atomic Absorption Spectrometry (FAAS).
62 (BCP) coprecipitation procedure using flame
atomic absorption spectrometry (FAAS).
63 ts between 0.13 and 0.35ngmL(-1) using flame
atomic absorption spectrometry (FAAS).
64 by the single line flow injection (FI) flame
atomic absorption spectrometry (FAAS).
65 is done by flow injection hydride generation
atomic absorption spectrometry (FI-HG-AAS).
66 ometry (ICP OES), and Se by graphite furnace
atomic absorption spectrometry (GF AAS), has been carrie
67 ts were determined by using graphite furnace
atomic absorption spectrometry (GF-AAS).
68 e collected and analyzed by graphite furnace
atomic absorption spectrometry (GFAAS) and matrix-assist
69 the Brazilian Amazon using graphite furnace
atomic absorption spectrometry (GFAAS) following acid mi
70 l water and food samples by graphite furnace
atomic absorption spectrometry (GFAAS).
71 d for lead and cadmium by a graphite furnace
atomic absorption spectrometry (GFAAS); and for mercury
72 obtained by hydride generation combined with
atomic absorption spectrometry (HG AAS).
73 on by high-resolution continuum source flame
atomic absorption spectrometry (HR-CS FAAS) was optimize
74 resolution continuum source graphite furnace
atomic absorption spectrometry (HR-CS GFAAS) without dig
75 antified by High-Resolution Continuum Source
Atomic Absorption Spectrometry (HR-CS-AAS) with flame an
76 ed beans, corn, and fungi) by Electrothermal
Atomic Absorption Spectrometry (Perkin Elmer, SIMAA 6000
77 well with those obtained by graphite furnace
atomic absorption spectrometry (r = 0.984).
78 direct analysis of Pb using graphite furnace
atomic absorption spectrometry - GF AAS.
79 The metal ions were detected by flame
atomic absorption spectrometry after acid mineralization
80 MeHg and iHg were determined by cold vapour
atomic absorption spectrometry after alkaline wet digest
81 and total arsenic in food by electrothermal
atomic absorption spectrometry after cloud point extract
82 from Escherichia coli (EcMetAP) monitored by
atomic absorption spectrometry and magnetic circular dic
83 performance comparable to hydride-generation
atomic absorption spectrometry but with less cumbersome
84 and determination of mercury by cold vapour
atomic absorption spectrometry is described.
85 Graphite furnace
atomic absorption spectrometry quantified Cu in chicken
86 s measured in the extracts by electrothermal
atomic absorption spectrometry using palladium as the ch
87 is in this work hyphenated to electrothermal
atomic absorption spectrometry via a dedicated flow-base
88 food-stuffs by solid sampling-electrothermal
atomic absorption spectrometry was compared.
89 feed samples by Simultaneous Electrothermal
Atomic Absorption Spectrometry was developed in regard t
90 Flame
atomic absorption spectrometry was employed for determin
91 Slurry sampling electrothermal
atomic absorption spectrometry was used for direct deter
92 After preconcentration step,
atomic absorption spectrometry was used for the determin
93 Atomic absorption spectrometry with hydride generation w
94 by combination of the slotted tube atom trap-
atomic absorption spectrometry with the optimised precon
95 Quantitation by flame
atomic absorption spectrometry yields results in agreeme
96 FAAS (High Resolution-Continuum Source Flame
Atomic Absorption Spectrometry) has been developed for t
97 ques (spectrophotometry and graphite furnace
atomic absorption spectrometry).
98 uring changes in cellular ionic gradient, by
atomic absorption spectrometry, and cell metabolism, by
99 DHGN was shown to chelate nickel by
atomic absorption spectrometry, and DHGN-containing mono
100 study the quenching mechanism, fluorescence,
atomic absorption spectrometry, and Fourier transform in
101 cal emission spectrometry and electrothermal
atomic absorption spectrometry, under optimized operatin
102 This discovery eventually spawned
atomic absorption spectrometry, which became a routine t
103 h those results obtained by graphite furnace
atomic absorption spectrometry.
104 ations of Ca, Cu, Fe, Mg, Mn and Zn by flame
atomic absorption spectrometry.
105 ad ion concentration was determined by flame
atomic absorption spectrometry.
106 as a eluent solvent, and determined by flame
atomic absorption spectrometry.
107 thenium quantification using High-resolution
atomic absorption spectrometry.
108 blood total mercury levels were analyzed by
atomic absorption spectrometry.
109 igin by the slurry sampling graphite furnace
atomic absorption spectrometry.
110 determination in cassava starch using flame
atomic absorption spectrometry.
111 of arsenic was analysed by graphite furnace
atomic absorption spectrometry.
112 X-ray fluorescence and cord blood lead using
atomic absorption spectrometry.
113 tentiators using rubidium flux combined with
atomic absorption spectrometry.
114 Lead and cadmium levels were measured by
atomic absorption spectrometry.
115 protein fractions by ELISA assay and zinc by
atomic absorption spectrometry.
116 owed by Se determination with electrothermal
atomic absorption spectrometry.
117 sma concentrations on day 3 were measured by
atomic absorption spectrometry.
118 furnace of high-resolution continuum source
atomic absorption spectrometry.
119 zinc followed by its determination by flame
atomic absorption spectrometry.
120 cal determinations were carried out by flame
atomic absorption spectrometry.
121 Copper and lead were determined by flame
atomic absorption spectrometry.
122 nation of Pb(II), Cd(II) and Zn(II) by using
atomic absorption spectrometry.
123 Mg in alternative oilseed crops using flame
atomic absorption spectrometry.
124 Mn by high resolution-continuum source flame
atomic absorption spectrometry.
125 Mineral content was analyzed by
atomic absorption spectrometry.
126 um in food samples by using graphite furnace
atomic absorption spectrometry.
127 BLL was measured by
atomic absorption spectrometry.
128 y markers, was evaluated by graphite furnace
atomic absorption spectrometry.
129 BPb was measured using
atomic absorption spectrometry.
130 lements (Fe, Mn) in soluble coffees by flame
atomic absorption spectrometry.
131 cadmium in vinegar employing electrothermal
atomic absorption spectrometry.
132 and total urinary chromium was measured with
atomic-absorption spectrometry.
133 e metal concentrations were determined using
atomic absorption spectrophotometer according to standar
134 tions were determined using a single-purpose
atomic absorption spectrophotometer AMA 254.
135 es were performed by means of a pH meter, an
atomic absorption spectrophotometer, and an inductively
136 cedure and their minerals were determined by
atomic absorption spectrophotometer.
137 dissolved in ethanol and determined by flame
atomic absorption spectrophotometer.
138 with wastewater in Mardan are studied using
Atomic Absorption spectrophotometer.
139 le, selective and sensitive method for flame
atomic absorption spectrophotometric determination of tr
140 eptomole-level, sub-Doppler, high-resolution
atomic absorption spectrophotometric method.
141 availability (Ca, Fe and Zn), quantified by
atomic absorption spectrophotometry (AAS), and formula v
142 h curves from a packed microcolumn and flame
atomic absorption spectrophotometry (FAAS) detection.
143 zinc atom as determined by graphite furnace-
atomic absorption spectrophotometry and inductively coup
144 improved the processing of erythrocytes for
atomic absorption spectrophotometry and mass spectrometr
145 cytes for measurement of Zn concentration by
atomic absorption spectrophotometry and stable isotope e
146 es, the solutions were analyzed by flameless
atomic absorption spectrophotometry for mercury and silv
147 cadmium ions from some real samples by flame
atomic absorption spectrophotometry measurements.
148 Cellular sodium was measured by
atomic absorption spectrophotometry or SBFI fluorescence
149 Using a combination of flameless
atomic absorption spectrophotometry to quantify vacuolar
150 g of both, metal ions contents determined by
atomic absorption spectrophotometry, and the MIR spectra
151 ular dichroism spectroscopy, iron-binding by
atomic absorption spectrophotometry, oligomerization in
152 stology, autofluorescence spectral analysis,
atomic absorption spectrophotometry, Perls' iron stain,
153 Tissue iron levels were measured by
atomic absorption spectrophotometry.
154 lysis of arsenic content by graphite furnace
atomic absorption spectrophotometry.
155 Lens sodium content was measured by
atomic absorption spectrophotometry.
156 Blood lead determinations were made by
atomic absorption spectrophotometry.
157 lead levels were measured by electrothermal
atomic absorption spectrophotometry.
158 nd iron in plasma and CSF were determined by
atomic absorption spectrophotometry.
159 rent methods and zinc recoveries compared by
atomic absorption spectrophotometry.
160 vity, and lens ion content was determined by
atomic absorption spectrophotometry.
161 dium and potassium content was determined by
atomic absorption spectrophotometry.
162 ium and lead levels were determined by flame
atomic absorption spectrophotometry.
163 e Ca(2+) binding that is consistent with our
atomic absorption spectroscopic data.
164 dduct contains a single Pt, as determined by
atomic absorption spectroscopy (AAS) and by electrospray
165 ooms relate largely to improper use of flame
atomic absorption spectroscopy (AAS) and inductively cou
166 n paramagnetic resonance (EPR) combined with
atomic absorption spectroscopy (AAS) or inductively coup
167 UV-Vis absorption and
atomic absorption spectroscopy (AAS) was used to verify
168 DTA, and fulvic (FA) and humic acids (HA) by
atomic absorption spectroscopy (AAS), anodic stripping v
169 ent analysis is then typically performed via
atomic absorption spectroscopy (AAS), UV-vis spectroscop
170 , and the results showed good agreement with
atomic absorption spectroscopy (AAS).
171 sonable agreement with that obtained through
atomic absorption spectroscopy (AAS).
172 is measured in the effluents of columns with
atomic absorption spectroscopy (AAS).
173 mineral loss was quantitatively evaluated by
atomic absorption spectroscopy (AAS).
174 spectroscopic techniques, namely cold vapour
atomic absorption spectroscopy (CV-AAS) and a direct mer
175 T quality control standards using cold vapor
atomic absorption spectroscopy (CVAAS).
176 uterium background-correction electrothermal
atomic absorption spectroscopy (D(2)-ETAAS) was develope
177 al emission spectrometry (ICP-OES) and flame
atomic absorption spectroscopy (FAAS), respectively, in
178 ts, where the leachate was analyzed by flame
atomic absorption spectroscopy (FAAS).
179 optimized flow injection hydride generation
atomic absorption spectroscopy (FI-HGAAS) method was use
180 We present a tunable diode laser
atomic absorption spectroscopy (TDLAAS) methodology that
181 ed intracellular Na(+) and K(+) content with
atomic absorption spectroscopy and APOL1-dependent curre
182 Zn2+ content of purified HIV-1 integrase by
atomic absorption spectroscopy and by application of a t
183 Total [Mg2+]i was determined by
atomic absorption spectroscopy and free [Mg2+]i from [Mg
184 n necessary for other methodologies, such as
atomic absorption spectroscopy and inductively coupled p
185 Atomic absorption spectroscopy and mass spectrometry sho
186 d tested for their ability to bind Cu(II) by
atomic absorption spectroscopy and oxidize (14C1)-ascorb
187 d zinc, which was experimentally verified by
atomic absorption spectroscopy and proteolysis protectio
188 on bacterial supernatants was compared with
atomic absorption spectroscopy as a means of confirming
189 Atomic absorption spectroscopy demonstrated that the thr
190 PET-CT and
atomic absorption spectroscopy directly demonstrate an a
191 rleukin 8; by HPLC for total retinol; and by
atomic absorption spectroscopy for sodium and potassium.
192 Laser-induced breakdown spectroscopy and
atomic absorption spectroscopy have been used to monitor
193 ght scattering and measurement of calcium by
atomic absorption spectroscopy in bound and unbound frac
194 say compared favorably with graphite furnace
atomic absorption spectroscopy in its ability to accurat
195 Determination of concentrations through
atomic absorption spectroscopy in the retina, choroid, v
196 Atomic absorption spectroscopy indicated an absence of Z
197 Atomic absorption spectroscopy indicates that the protei
198 Atomic absorption spectroscopy indicates that zinc is a
199 agnitude concentration range are compared to
atomic absorption spectroscopy measurements to evaluate
200 arget nuclear DNA, as determined by platinum
atomic absorption spectroscopy of cell extracts.
201 When bound Ca(2+) was assayed by
atomic absorption spectroscopy or an equilibrium dialysi
202 ulation was evaluated using graphite furnace
atomic absorption spectroscopy or inductively coupled pl
203 f tissue copper content utilizing (64)Cu and
atomic absorption spectroscopy revealed no differences i
204 Atomic absorption spectroscopy showed that the intact pr
205 Atomic absorption spectroscopy shows maximal binding of
206 the eyes analyzed at 1, 2, 6, or 24 hours by
atomic absorption spectroscopy to determine carboplatin
207 by the absence of a detectable Pt signal by
atomic absorption spectroscopy using isolated DNA from h
208 Neutron activation,
atomic absorption spectroscopy, and anomalous X-ray scat
209 eavy and light chains was investigated using
atomic absorption spectroscopy, electron paramagnetic re
210 Calcium content was determined by
atomic absorption spectroscopy, oxalate by titrimetry, p
211 (14)C isotopic labeling, resonance Raman and
atomic absorption spectroscopy, respectively.
212 ing a combination of gravimetric methods and
atomic absorption spectroscopy, we demonstrate that reco
213 Q was checked using equilibrium dialysis and
atomic absorption spectroscopy, which clearly showed a s
214 good agreement with the results obtained by
atomic absorption spectroscopy.
215 and nephelometry and serum copper levels by
atomic absorption spectroscopy.
216 DNA adducts were measured by
atomic absorption spectroscopy.
217 ied protein was analyzed for zinc content by
atomic absorption spectroscopy.
218 determined by both a colorimetric assay and
atomic absorption spectroscopy.
219 the blood samples and subsequent analysis by
atomic absorption spectroscopy.
220 esonance spectroscopy and were quantified by
atomic absorption spectroscopy.
221 Ca(2+) binding curves were measured using
atomic absorption spectroscopy.
222 mol of iron per mol of PH was determined by
atomic absorption spectroscopy.
223 Total lens calcium was determined by
atomic absorption spectroscopy.
224 concentration in explants was determined by
atomic absorption spectroscopy.
225 by light and electron microscopy as well as
atomic absorption spectroscopy.
226 um copper concentration was determined using
atomic absorption spectroscopy.
227 lar and extracellular space is determined by
atomic absorption spectroscopy.
228 gle atom of zinc per enzyme subunit by flame
atomic absorption spectroscopy.
229 nvestigated by using fura-2 fluorescence and
atomic absorption spectroscopy.
230 d in blood were measured by graphite furnace
atomic absorption spectroscopy.
231 validation was performed by using cold vapor
atomic absorption spectroscopy.
232 awn in order to measure serum zinc levels by
atomic absorption spectroscopy.
233 Atomic absorption studies demonstrate that the native B.
234 These steps produced cadmium
atomic absorption traces with high signal to background