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1 otal and volatile suspended solids, chemical oxygen demand).
2 posive sample selected according to greatest oxygen demands).
3 myocardial perfusion and reducing myocardial oxygen demand.
4 t worsening major determinants of myocardial oxygen demand.
5 ontractility to balance oxygen delivery with oxygen demand.
6 rictor nerve activity and reductions in limb oxygen demand.
7 is the major contributor to the increase in oxygen demand.
8 e root tip, likely due to enhanced microbial oxygen demand.
9 well-established regulatory methods based on oxygen demand.
10 nd is prone to dysregulation because of high oxygen demand.
11 ion in which O2 supply is inadequate to meet oxygen demand.
12 ar tone to match local tissue perfusion with oxygen demand.
13 ally at the expense of increasing myocardial oxygen demand.
14 rcise-induced increases in muscle energy and oxygen demand.
15 ssure product, dP/dt, -dP/dt, and myocardial oxygen demand.
16 ncreased right ventricular (RV) workload and oxygen demand.
17 ell with high removal efficiency of chemical oxygen demand.
18 lature to match oxygen delivery to increased oxygen demand.
19 F response is mediated by factors other than oxygen demand.
20 n of large predatory fish, animals with high oxygen demand.
21 ft ventricular (LV) afterload and myocardial oxygen demand.
22 , including motile skeletal benthos, had low oxygen demands.
23 increases red blood cell mass to meet tissue oxygen demands.
24 like flying insects that have high metabolic oxygen demands.
25 rized by elevated concentrations of chemical oxygen demand (13.1-59.6 mg/L), biochemical oxygen deman
26 oxygen demand (13.1-59.6 mg/L), biochemical oxygen demand (7.67-36.5 mg/L), total suspended solids (
27 s as well as the maximum removal of chemical oxygen demand (94.8%), linear alkylbenzenesulfonates (LA
28 with removals of 97% of the soluble chemical oxygen demand, 97% NH3-N, and 91% of total bacteria (bas
29 IPB system removed more than 92% of chemical oxygen demand, 98% of ammonium nitrogen, and 82% of phos
31 more likely to result from preventing excess oxygen demand after surgery rather than from deciding wh
32 n agricultural pollution emissions (Chemical Oxygen Demand, ammonia nitrogen, and agricultural carbon
33 n concentrated centrate, 95% of the chemical oxygen demand and 93% of total PFAS were removed after 2
34 h the alternation of the influent biological oxygen demand and ammonium nitrogen load to the aerated
35 when added to leachate; five-day biochemical oxygen demand and biochemical methane potential results
37 leads to increased inflammation, myocardial oxygen demand and dehydration, predisposing people to my
38 approaches that address the balance between oxygen demand and delivery; the manipulation of cardiopu
39 d the potential for mismatch between tubular oxygen demand and delivery; the self-sustained oscillati
41 changes decrease LV afterload and myocardial oxygen demand and reduce the number of angina episodes,
43 contributes to a mismatch between myocardial oxygen demand and supply, a mechanistic basis for disrup
44 s occur in the setting of a mismatch between oxygen demand and supply, as with severe hypotension.
45 al oxygen delivery to active skeletal muscle oxygen demand and therefore inadvertently impair exercis
47 irculation that combine to reduce myocardial oxygen demand and to increase supply, thereby attenuatin
48 ion (MI) can occur from increased myocardial oxygen demand and/or reduced supply in the absence of ac
50 wastewater temperature, influent biological oxygen demand, and ammonium nitrogen load, was investiga
51 ndex, global longitudinal strain, myocardial oxygen demand, and left atrial emptying fraction were im
52 (NTG) improves myocardial perfusion, reduces oxygen demand, and may enhance low-dose dobutamine to im
54 ocities than did still-water fish, had lower oxygen demands, and responded less vigorously to small c
57 astal DO, rain event sampling of biochemical oxygen demand (BOD) in samples collected from the outfal
58 well as a detector for measuring biochemical oxygen demand (BOD) using Rhodotorula mucilaginosa UICC
59 (Chemical Oxygen Demand (COD) and Biological Oxygen Demand (BOD)) significantly overestimated populat
60 aracterize phosphorus, nitrogen, biochemical oxygen demand (BOD), and fecal coliform pollution from h
61 dissolved oxygen (DO), salinity, biological oxygen demand (BOD), chemical oxygen demand (COD), elect
62 ee critical pollutants including biochemical oxygen demand (BOD), total nitrogen (TN) and total suspe
63 TSS (total suspended solids), COD (chemical oxygen demand), BOD (biochemical oxygen demand), and COL
64 apability to rotate and determine biological oxygen demand, BOD), that uniquely enables automated oxy
65 10(-2) g CH(4) (g influent 5 day biochemical oxygen demand; BOD(5))(-1) [0.6-9.9 x 10(-2) g CH(4) (g
66 mical oxygen demand (COD) 90-95%, biological oxygen demand (BOD5) 94-98%, total nitrogen (TN) 70-80%,
68 of dicarboxylates induces not only a higher oxygen demand but also a higher NADH/NAD(+) ratio than s
69 ng with a local hypoxia induced by increased oxygen demands by proliferating cells which supports chr
70 e extent to which apnoea-induced extremes of oxygen demand/carbon dioxide production impact redox reg
71 ly been associated with increased myocardial oxygen demand, cardiac arrhythmias, and mortality in a v
72 DNA degradation rate declined as biochemical oxygen demand, chlorophyll, and total eDNA (i.e., from a
73 g in large values of chemical and biological oxygen demand (COD and BOD) in the aquatic systems into
74 ecedent determinations, theoretical chemical oxygen demand (COD(th)) as well as theoretical and stoic
76 high biological elimination rates (chemical oxygen demand (COD) 90-95%, biological oxygen demand (BO
77 er ratio (R(2) = 0.87), and between chemical oxygen demand (COD) and AA concentrations (R(2) = 0.87).
80 Traditional load-based indicators (Chemical Oxygen Demand (COD) and Biological Oxygen Demand (BOD))
81 d the 24-h and 7-day Pb toxicity to chemical oxygen demand (COD) and NH3-N removal, bacterial viabili
82 ystem oxidized only 10% of influent chemical oxygen demand (COD) and recovered up to 55% of incoming
84 average removal rate of 94.23% for Chemical Oxygen Demand (COD) compared to 88.76% for standard syst
86 method for the determination of the chemical oxygen demand (COD) in heterogeneous solid or semisolid
92 retention time (SRT), matching the chemical oxygen demand (COD) loading rate to the removal rate in
93 weeks, with a mass balance based on chemical oxygen demand (COD) of 100 +/- 2% (COD(out)/COD(in)).
95 The model was able to predict the chemical oxygen demand (COD) removal efficiency and methane produ
98 of initial pH (pH 4, 5, and 7) and chemical oxygen demand (COD) to nitrogen (COD/N) ratio of 3.6:1,
99 time and EO time, on the removal of chemical oxygen demand (COD), colour, turbidity, and total organi
100 ty, biological oxygen demand (BOD), chemical oxygen demand (COD), electrical conductivity (EC), nitra
101 ir impact on key indicators such as Chemical Oxygen Demand (COD), NH(4)(+)-N, Total Phosphorus (TP),
102 ed as total organic carbon (TOC) or chemical oxygen demand (COD), though these parameters do not prov
103 tified accounted for only 2.1 mg of chemical oxygen demand (COD)/L (16% of total SMP as COD) because
104 the highest solubilization (0.16 mg chemical oxygen demand (COD)/mg volatile solids (VS), at 2.13 mg
105 ter column features arising from respiratory oxygen demand during organic matter degradation in strat
110 idation result in reduced economy (increased oxygen demand for a given speed) at velocities that tran
113 VFA yield of 0.55 +/- 0.12 g VFA as chemical oxygen demand g volatile solids (VS)(fed)(-1) were obser
114 explained by its ability to reduce cerebral oxygen demand has been replaced by an increasingly docum
115 mperatures, low oxygen supply and increasing oxygen demand, high and rising exposure to ultraviolet r
116 tion extends the ability to sustain elevated oxygen demand, implying a buffering role for myelin agai
117 western basin bloom growth and central basin oxygen demand in distinct ways that merit further invest
118 the diaphragm to augment blood flow to match oxygen demand in response to contractile activity and co
119 The importance of increase in myocardial oxygen demand in the genesis of ischemia in both men and
123 ater consumption, discharge of COD (chemical oxygen demand) in effluent water, cumulative COD and dil
125 oals of treatment are to decrease myocardial oxygen demand, increase coronary blood flow and oxygen s
127 h the influent total phosphorus and chemical oxygen demand instead of geographical factors (e.g. lati
128 -shivering thermogenesis the increase in BAT oxygen demand is met by a local and specific increase in
130 forms, E. coli, enterococci, and biochemical oxygen demand (Kendall's tau = 0.348 to 0.605, p < 0.05)
131 ischemia induced by a sustained increase in oxygen demand may not progress to necrosis but may inste
132 n muscle glucose metabolism during increased oxygen demand may promote central fatigue and thereby di
133 logy similar to that of a modern sponge, its oxygen demands may have been met well before the enhance
134 e COD method with an optode-based biological oxygen demand method to accurately and efficiently asses
135 to reductases, we tested the hypothesis that oxygen demand modifies arterial [NAD(H)](i), and that re
136 ncreases in these determinants of myocardial oxygen demand, myocardial perfusion decreased by 30% (10
138 ggest that a fine-tuning on CO(2) uptake and oxygen demand of the cells is essential to reach a highe
139 carbon-paste matrix is shown to satisfy the oxygen demand of the enzymatic reaction and to provide c
141 ue and specialized trait associated with the oxygen demands of flying, their endothermic metabolism a
142 However, the effects of remote increases in oxygen demand on a circulation with limited ability to r
144 e observed the effect of remote increases in oxygen demand on splanchnic and renal blood flow in hemo
145 ion was related to a reduction in myocardial oxygen demand or preservation of myocardial oxygen suppl
146 d disease-associated hypoxia (where cellular oxygen demand outstrips supply) for immune cell function
148 r NAD(P)(H) redox ratios reflecting elevated oxygen demand potentiate native coronary Kv1 activity in
150 DO level was attributable to biofilm-induced oxygen demand rather than changes in oxygen diffusivity.
151 between cerebral vascular geometry and local oxygen demand, recent experiments have reported that mic
153 We hypothesized that increased myocardial oxygen demand resulting from hypotension and reflex tach
155 tized, hemorrhaged dog, increased peripheral oxygen demand results in further redistribution of blood
156 ons significantly decreased soluble chemical oxygen demand (S(COD)) removal efficiency (11% to 31%) a
157 nse variables analyzed were soluble chemical oxygen demand (sCOD) and volatile suspended solids (VSS)
158 ch aims to predict effluent soluble chemical oxygen demand (SCOD) in anaerobic digestion (AD) process
159 isioned cyber-physical system with real-time oxygen demand sensing and delivery for improved patient
160 f MFCs were proposed earlier (as biochemical oxygen demand sensing) only lately a myriad of new uses
161 Besides, the use of MFCs as biochemical oxygen demand sensors (perhaps the main analytical appli
162 on rate, renal oxygen consumption, and renal oxygen demand/supply relationship, i.e., renal oxygen ex
164 Secondary-treated PPM effluent has lower oxygen demand than primary-treated effluent, but ASB acc
165 ations and functions for estimating sediment oxygen demand that are linked to settled organic carbon
168 A2 class of adenosine receptors and reducing oxygen demand through A1 adenosine receptors (A1AR).
171 investigation illustrated that the chemical oxygen demand, total nitrogen, and total phosphorus remo
172 ciencies of total suspended solids, chemical oxygen demand, total phosphorus, and total nitrogen were
173 d minor effect on determinants of myocardial oxygen demand, vasodilator stress myocardial perfusion i
174 ine oxygen extraction fraction and regulated oxygen demand via oxygen extraction fraction changes, wh
176 Statistical analysis indicated that cerebral oxygen demand was maintained to an Hct of 0.14, 0.11, an
177 iency of total suspended solids and chemical oxygen demand was observed for recovered aluminum (85-60
180 ad (aortic pressure, P=0.030) and myocardial oxygen demand were seen (tension-time index, P=0.024; ra
181 r side, high heart rates increase myocardial oxygen demand, which can be a problem in patients with f
182 ulation was used to increase lower extremity oxygen demand while lower extremity, splanchnic, renal b
184 ormal pigs, there is no change in myocardial oxygen demand with CPAP, whatever the change in cardiac
185 al oxygen supply or unmet need in myocardial oxygen demand, without atherothrombosis, usually in the
186 calized vascular damage and increased tissue oxygen demand, wound healing occurs in a relatively hypo