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1 oughtful study design to ensure maximal risk mitigation.
2 farmers, and we explore the implications for mitigation.
3  quality models for pollution prediction and mitigation.
4 gical gas treatment for a cost-effective GHG mitigation.
5 ervice include communication skills and risk mitigation.
6 t of projects contributing to global warming mitigation.
7 ication of management strategies for disease mitigation.
8 on interventions for disease and health-risk mitigation.
9 his complication, with implications for risk mitigation.
10 onomic biomass technology for climate-change mitigation.
11 ion cobenefits deliver only 21-40% of needed mitigation.
12 ased species conservation and climate change mitigation.
13 d help inform the policymaking on global GHG mitigation.
14  misuse or diversion, and risk assessment or mitigation.
15 l of structural vibrations, noise, and shock mitigation.
16 a challenge for environmental monitoring and mitigation.
17 r to agricultural production in terms of GHG mitigation.
18 roviding valuable guidance for local drought mitigation.
19 s of habitat conservation and climate change mitigation.
20 ts for pathway flux, as well as for toxicity mitigation.
21  CO2 utilization as a measure for global CO2 mitigation.
22 s and mandates novel approaches for toxicity mitigation.
23              To establish strategies for N2O mitigation, a better understanding of production mechani
24 ecological processes and propose appropriate mitigation action when needed.
25 nge effects on species and directing climate mitigation actions for biodiversity.
26  implementation of soil-based greenhouse gas mitigation activities are at an early stage and accurate
27 he role of forest dynamics in climate-change mitigation, adaptation, and carbon cycle feedbacks, ther
28 mechanisms, provide recommendations for risk mitigation, address the advantages and disadvantages of
29 ss of blanching and air-frying on acrylamide mitigation after gastrointestinal digestion.
30  questions that characterize leading climate mitigation alternatives.
31 of crop yield on agricultural greenhouse gas mitigation and accounting.
32 ems, whose understanding is key for devising mitigation and adaptation measures to ensure their susta
33 s caused by these warming levels for climate mitigation and adaptation measures.
34 distribution is critical yet lacking in most mitigation and adaptation strategies, including the Unit
35 ders development of effective strategies for mitigation and adaptation to projected heat stress incre
36 lustrates their importance in climate change mitigation and adaptation, acting as CO2 sinks and buffe
37 eral climate projections toward questions of mitigation and adaptation, the inclusion of land managem
38 or natural origin is of great importance for mitigation and adaption measures alike.
39 ons is essential to achieving climate change mitigation and advancing food security in China.
40 ill permits the assessment of catchment-wide mitigation and best management practice.
41 t such models may eventually allow proactive mitigation and conservation strategies.
42 ally important for the development of future mitigation and diagnosis strategies.
43 ts and policy-relevant insights for exposure mitigation and management.
44 d provides substantial potential for climate mitigation and other benefits.
45 ses to biodiversity is well established, but mitigation and planning are often hampered by a lack of
46   To better identify priorities for outbreak mitigation and prevention, we developed a cohesive frame
47 is an attractive strategy for global warming mitigation and resource utilization.
48 implementation of effective soil degradation mitigation and restoration strategies.
49  wave propagation are essential in vibration mitigation and sound attenuation.
50 of grasslands for carbon storage and climate mitigation, and for global carbon models which do not cu
51  important for eruption forecasting and risk mitigation, and have significant implications for the in
52 rovement, neuropathic pain and tissue damage mitigation, and myelin preservation.
53 sandstorm prevention, water retention, flood mitigation, and provision of habitat for biodiversity.
54                            Secondly, several mitigation approaches have been investigated.
55 r arsenic exposure and adverse health effect mitigation are being pursued, and future research is mov
56 as (GHG) mitigation: To achieve the same 73% mitigation as MEA-PCC, HS-DAC would increase nine other
57 are also important to environmental pressure mitigation as transmission centers.
58 O2e y(-1)) represents cost-effective climate mitigation, assuming the social cost of CO2 pollution is
59 g the most viable options for climate change mitigation, because using secondary (recycled) instead o
60 nservation practices conferred no additional mitigation benefit.
61 ulosic bioenergy concerns related to climate mitigation, biodiversity, reactive nitrogen loss, and cr
62  an important contribution to climate change mitigation, but are not systematically accounted for in
63 tical nuance to the debate on climate change mitigation by highlighting the responsibility of consume
64    However, the mechanisms of abiotic stress mitigation by isoprene are still under debate.
65 rvation technology for disaster response and mitigation by putting past and current developments into
66         One-third of this cost-effective NCS mitigation can be delivered at or below 10 USD MgCO2(-1)
67             There is an urgent need to build mitigation capacity where amphibians are at risk from ch
68 e solution for addressing the adaptation and mitigation challenges faced by multiple sectors in Calif
69 impacts of extreme weather(1-3), and without mitigation, climate change is likely to increase the sev
70 sible agricultural development pathways with mitigation cobenefits deliver only 21-40% of needed miti
71 omplied with more than three-quarters of the mitigation control measures listed in the survey.
72        Additionally, we estimate the avoided mitigation costs implied by plausible reductions in popu
73                               Climate change mitigation could prevent many climate-related deaths.
74                                     For risk mitigation, countries are introducing inactivated poliov
75  population is valued importantly determines mitigation decisions.
76 here high risk was correctly identified, the mitigation deployed did not avert the risk.
77 gy absorbing materials for shock wave energy mitigation due to their nanoporosity.
78 tation; health co-benefits of climate change mitigation; economics and finance; and political and bro
79 , while future simulations predict a warming mitigation effect of only 5-10% depending on the island.
80                                 However, the mitigation effectiveness of NT depends not only on its c
81 Cs) offer important potential climate change mitigation effects when combined with clean energy sourc
82                                     Emission mitigation efficiencies of sulfur dioxide (SO2), nitroge
83 evelopment period, despite aggressive onsite mitigation efforts (e.g. directional drilling and liquid
84 ctive land use, providing insight into where mitigation efforts can be most effective.
85 % respectively, highlighting the efficacy of mitigation efforts in reducing exposure to extreme heat.
86                                   Successful mitigation efforts in the Red Deer region will need to f
87                These data indicate that risk-mitigation efforts should focus on reducing neonicotinoi
88 tions of many endangered species at risk and mitigation efforts typically focus on reducing anthropog
89 adation contributes to global climate-change mitigation efforts, yet emissions and removals from fore
90 n the space and time scales of water quality mitigation efforts.
91 s a central role in ambitious climate change mitigation efforts.
92 g adults and may aid in sepsis prevention or mitigation efforts.
93 mains to better constrain uncertainty of NCS mitigation estimates.
94 nticipated consequence of this acidification mitigation experiment began to emerge a decade later, wi
95 nsible for the majority of freight emissions mitigation, followed by price-induced reduction in freig
96 vide effective soil improvement and ammonium mitigation for wind erosion control and other applicatio
97  the state achieve its 2030 and 2050 climate mitigation goals under alternative implementation scenar
98                Meeting global climate change mitigation goals will likely require that transportation
99 ices include drinking water provision, flood mitigation, habitat provision and carbon sequestration.
100 he potential of GO to be used for biofouling mitigation in FO.
101 he use of graphene oxide (GO) for biofouling mitigation in FO.
102  targets and plans will increase the cost of mitigation in other sectors or reduce the feasibility of
103 thods, as well as mechanism(s) of injury and mitigation in patients after radiotherapy or radiologica
104 ccessful approach to risk identification and mitigation in relation to the switch from trivalent to b
105  OsPCS2 gene during heavy metal(loid) stress mitigation in rice plant.
106 ories, ranging from ambitious climate-change mitigation-in line with the Paris agreement-to unabated
107 ns for flood susceptibility, forecasting and mitigation, including management of groundwater extracti
108                              Further, damage mitigation is associated with reduced apoptosis, preserv
109 gs suggest that biochar-induced N2O emission mitigation is based on the entrapment of N2O in water-sa
110 der present-day conditions and that exposure mitigation is enhanced in the more acidic conditions pre
111     Yet technical information about how much mitigation is needed in the sector vs. how much is feasi
112 mize carbon sequestration for climate change mitigation is widely recognized, with grasslands being i
113                Drawing upon results from the mitigation literature and the IPCC Working Group 3 (WG3)
114  for potential changes in manufacturing as a mitigation measure to reduce microfiber release during l
115                  Our work supports targeting mitigation measures at most infectious subjects to effic
116 ond this, several additional costcompetitive mitigation measures could reduce emissions further.
117  that human society must plan adaptation and mitigation measures for the full breadth of impacts in a
118 se ions is essential for designing effective mitigation measures for this problem.
119 the need for much improved implementation of mitigation measures in fisheries and better enforcement
120 ced with an urgent implementation of bycatch mitigation measures in the longline fleet.
121 sites across Canada, suggesting the need for mitigation measures prior to flooding.
122                          Therefore, applying mitigation measures such as advanced treatment technolog
123                      Despite regulations and mitigation measures to reduce PCB pollution, their bioma
124 ected governments negotiating climate-change mitigation measures, the decisions are made not by indiv
125 e further abated in the combination of these mitigation measures, the synergy of strategies fails to
126 the extent of the issue and propose concrete mitigation measures.
127 likely fitness consequences and the need for mitigation measures.
128 nsmission is relevant to designing effective mitigation measures.
129 tress can be drastically reduced via climate mitigation measures; with mitigation, the proportion of
130          Economy-wide environmental pressure mitigation might be achieved by improving production eff
131 utions can provide 37% of cost-effective CO2 mitigation needed through 2030 for a >66% chance of hold
132                                              Mitigation of a potential Ames and hERG liability ultima
133 em shifts greater regulatory priority to the mitigation of accumulating cellular stress.
134                                              Mitigation of acrylamide formation and the functional pr
135 e recognition, resulting in the reduction or mitigation of adverse cardiopulmonary distress associate
136 ship may prove pivotal for the detection and mitigation of amyloid diseases.
137                                              Mitigation of anthropogenic greenhouse gases with short
138 ostasis and favoring bone acquisition and/or mitigation of bone resorptionin vivo Thus, SFN is a memb
139                                              Mitigation of capital constraints may provide practicabl
140 mong promising options toward adaptation and mitigation of climate change.
141 l after intraportal islet transplantation by mitigation of coagulation in IBMIR and suppression of cy
142 fosters malignant transformation through the mitigation of critical oncosuppressive pathways and thro
143    These data implicate monocyte CD36 in the mitigation of early infarct size and transition to Mertk
144 formance of a fast- developing contender for mitigation of EE2 contamination of wastewater based upon
145 forecasting to help anticipate and guide the mitigation of epidemics.
146 tic ablation of Plin2 in Akita mice leads to mitigation of ER stress, forestalling beta cell apoptosi
147                                          The mitigation of fibre nonlinearities is an area of intense
148 ting the competition dynamics resulting in a mitigation of fitness advantages.
149  important role in continental N-cycling and mitigation of fixed nitrogen transfer from land to the s
150 enarios that apply a price to GHG emissions, mitigation of freight emissions (including the effects o
151 he stratigraphic record, leading to improved mitigation of future flooding disasters.
152 opical forest ecosystems is critical for the mitigation of future losses in global biodiversity.
153                                     Both the mitigation of GHG emissions and land use related reducti
154 ures, offering limited scope for dung beetle mitigation of GHG fluxes.
155 cting and restoring high grazing) to global (mitigation of greenhouse gas emissions) interventions fo
156 l stem both from the supply side-through the mitigation of greenhouse gases-and from the demand side-
157                                              Mitigation of growth impacts was not predictable on the
158 f natural regulatory T cells (nTregs) on the mitigation of GvHD by AzaC, instead focusing on the gene
159 ment efforts should focus on iAE prevention, mitigation of harm after iAEs occur, and risk/severity-a
160                                              Mitigation of haze pollution therefore provides a co-ben
161  well understood, hindering the forecast and mitigation of haze pollution.
162                                         This mitigation of hepatic damage was associated with a 54% d
163 urces, biomaterials with tunable properties, mitigation of host responses, and vascularization.
164 hibited endocytosis of Ab/SOD and diminished mitigation of inflammatory signaling of endothelial supe
165           Addressing possible mechanisms for mitigation of information loss, we focused on the ERK pa
166 temortem sampling techniques crucial for the mitigation of its spread; this is especially true in cas
167 temortem sampling techniques crucial for the mitigation of its spread; this is especially true in cas
168  of acute myocardial infarction has been the mitigation of lethal injury.
169 hort-term survival, long-term adaptation and mitigation of macromolecular damage.
170 ritical thresholds [12, 13] and suggest that mitigation of marine ecological traps will require match
171                                              Mitigation of N-nitrosodimethylamine (NDMA) and other ha
172 ement in behavioral deficits correlated with mitigation of neuropathological features commonly observ
173                          The most optimistic mitigation of noise and contaminants would make the diff
174           This study develops technology for mitigation of NOx formed in thermal processes using recy
175 l systems could facilitate the prevention or mitigation of organ damage underlying complex diseases,
176 d animals show improved bladder function and mitigation of pain-related symptoms.
177 ungal virulence may be welcome additions for mitigation of plant diseases.
178 o assist civil protection authorities in the mitigation of potential oil spill accidents in the Easte
179                                              Mitigation of primary PM appears to be the most efficien
180 uration of the study, suggesting therapeutic mitigation of SEB-induced morbidity.
181 ten be the only evolutionary path toward the mitigation of the cost incurred by their own selfish act
182 ansportation, lowering of personal exposure, mitigation of the direct effects of air pollution throug
183 at in a non-model organism opens the way for mitigation of the epidemic.
184                                              Mitigation of the widespread As-pollution in shallow aqu
185 ynergistic effects of these two hormones and mitigation of their adverse effects by engineering chemi
186                 We demonstrate pharmacologic mitigation of these phenotypes in Axin mutants by identi
187 g(2+) and Ca(2+)) on RED and demonstrate the mitigation of those effects using both novel and existin
188  metalloproteinase 9 in the tissues, and the mitigation of tissue damage.
189 they may be relevant therapeutic targets for mitigation of vascular calcification.
190 olonized plants and directly involved in the mitigation of WS effects need to be further investigated
191                In this study we assessed GTP mitigation on biomarkers of fumonisin B1 (FB1), a class
192                        Tanks represent a key mitigation opportunity for reducing methane and VOC emis
193  soils (SOC) is promoted as a climate change mitigation option.
194  and robust projections are needed to assess mitigation options and guide adaptation measures.
195 s provides the extreme boundary to potential mitigation options and requires the fewest assumptions t
196  include soil carbon and agriculture-related mitigation options.
197 ng improved food production, is an important mitigation pathway to achieve the less than 2 degrees C
198                    Compared to the reference mitigation pathway, eradicating extreme poverty increase
199                           For adaptation and mitigation planning, stakeholders need reliable informat
200 n rights impact assessments, with associated mitigation plans, were sequentially initiated and have i
201 n regulatory networks, to the development of mitigation policies for infectious diseases and financia
202 ssion scenarios emphasises the importance of mitigation policies for limiting global warming and redu
203                                         Yet, mitigation policies in agriculture may be in conflict wi
204  we analyze the impacts on food prices under mitigation policies targeting either incentives for prod
205 Ms) and the implementation of climate change mitigation policies that involve land-sector C accountin
206  targeting O3, health co-benefits of climate mitigation policies, and health implications of climate
207 critical to investigating land-based climate mitigation policies, assessing the potential of climate
208 ure that is needed for translation of better mitigation policies, including improved equipment to red
209 eness of detection technologies and proposed mitigation policies.
210 ct forest to fulfil biodiversity and climate mitigation policy targets, but the conservation strategi
211               By 2050, in the absence of any mitigation, population growth plus higher per capita pro
212 t GCM simulations enables us to quantify the mitigation potential of the projected circulation change
213 land stewardship options available and their mitigation potential.
214 art' soil greenhouse gas research, summarize mitigation practices and potentials, identify gaps in da
215 iliar with and trusting of the relevant risk mitigation practices.
216                                              Mitigation procedures that modify the Maillard reaction
217 n the samples which were treated by Advanced Mitigation Process.
218 realizing negative CO2 emissions for climate mitigation purposes, these aspects need further experime
219 ative effective mass density for stress wave mitigation purposes.
220  least $2.97 PPP would increase the required mitigation rate by 27%.
221 t Model (GCAM) for a range of climate change mitigation scenarios and future freight demand assumptio
222                            In climate change mitigation scenarios that apply a price to GHG emissions
223 century difference between high-emission and mitigation scenarios.
224 hly relevant metric for urban climate change mitigation since they not only include direct emissions
225                                              Mitigation slows the pace at which multiple drivers emer
226 would inform future formulation of effective mitigation standards and management protocols towards th
227                               These chemical mitigation strategies also engage another element in ene
228 l emission variability will promote improved mitigation strategies and additional analysis is needed
229 unities for these sources to improve disease-mitigation strategies and public health coordination.
230 and scale of the PVHI effect and identifying mitigation strategies are key in supporting decision-mak
231                                              Mitigation strategies based on the reaction mechanisms i
232 istic effects of deploying multiple chemical mitigation strategies coupled with the relaxation of the
233 sights into the influence of acid deposition mitigation strategies for both carbon cycling and waters
234  and source attribution, to develop reliable mitigation strategies for efficient reduction of BC impa
235  survey, and rated the efficacy of predation mitigation strategies for foxes, dogs, coyotes, wolves,
236 ure research efforts and elucidate effective mitigation strategies for managing the negative impacts
237              These results suggest potential mitigation strategies for N2 O emissions from fertilised
238 sion estimates and prioritize cost-effective mitigation strategies for Pennsylvania and beyond.
239 of appropriate therapeutic interventions and mitigation strategies for those susceptible subjects who
240                             While urban heat mitigation strategies have been shown to have beneficial
241                                              Mitigation strategies include surveillance and research
242 riendly microbiome-based solutions to future mitigation strategies of climate change.
243  risk and vegetation-related develop drought mitigation strategies over China in a warming world.
244                                 Implementing mitigation strategies requires an understanding and quan
245  from predators for millennia, yet effective mitigation strategies that balance wildlife conservation
246 r patterns can be used to develop short-term mitigation strategies that manipulate N fertilizer and c
247 e could be avoided under scenarios involving mitigation strategies to limit emissions and further war
248 ication of eco-regions and develop effective mitigation strategies to maintain western Canadian borea
249 provides background information for devising mitigation strategies to prevent this species from extin
250 lly-embedded network structures, and propose mitigation strategies to reduce the severity of damages
251 vidence-based, our results indicate that EIA mitigation strategies used to date have been ineffective
252            The general perception was lethal mitigation strategies were more effective than non-letha
253    Innovation in current or novel non-lethal mitigation strategies, and examples of efficacy, are nee
254                          In order to develop mitigation strategies, it is essential to understand the
255 aneously for future agronomic adaptation and mitigation strategies, particularly for breeding program
256          As a first step in the selection of mitigation strategies, the present work proposes a model
257  model performance and developing innovative mitigation strategies.
258 ysis of HIVDR data to monitor the success of mitigation strategies.
259 ss balance exercises, impact assessments and mitigation strategies.
260 ost-construction and on developing effective mitigation strategies.
261  any crisis and the necessary management and mitigation strategies.
262  tool for apportioning sources and exploring mitigation strategies.
263 ing the effectiveness of evolving stormwater mitigation strategies.
264  guiding sector-level environmental pressure mitigation strategies.
265 standing risks and developing monitoring and mitigation strategies.
266 scuss the implications of these findings for mitigation strategies.
267 these phenomena and facilitate the design of mitigation strategies.
268 f climate change conservation management and mitigation strategies.
269 itizing future plastic debris monitoring and mitigation strategies.
270 cination and influenza epidemic and pandemic mitigation strategies.
271 lt to use for guidance in developing nuanced mitigation strategy and policy response.
272 n sequestration in soils as a climate change mitigation strategy are discussed.
273 gical formations is regarded as an important mitigation strategy for anthropogenic CO2 emissions to t
274 ety actions, such as the Risk Evaluation and Mitigation Strategy initiative, whose effectiveness rema
275 cy of mitigation varied by predator species, mitigation strategy, and lethality of strategies, but no
276                                 As a climate mitigation strategy, CO2 capture from flue gases of indu
277 t broad implementation of cool roofs, a heat mitigation strategy, not only results in significant coo
278 revent ID in populations is a promising lead mitigation strategy.
279 OC sequestration can be an effective climate mitigation strategy.
280 untries less commonly targeted for cookstove mitigation such as Azerbaijan, Ukraine, and Kazakhstan h
281                              Incentive-based mitigation, such as protecting carbon-rich forests or ad
282                             Preference-based mitigation, such as reduced household waste or lower con
283 der studies and action regarding risk factor mitigation, targeted screening, medical management of PA
284        Excluding agricultural emissions from mitigation targets and plans will increase the cost of m
285 ally contribute to one of the most ambitious mitigation targets globally.
286 es in responding to ambitious climate change mitigation targets.
287  efficiency through improvement in emissions mitigation technologies and changes in consumption patte
288 ductions and the economic performance of the mitigation technologies can vary under different conditi
289 educed via climate mitigation measures; with mitigation, the proportion of ocean susceptible to multi
290 , AC has strong potential for climate change mitigation through direct emissions reductions and incre
291                         We show that failure mitigation through increased node protection can be effe
292                              We discuss risk mitigation through policies and standards such as not al
293 omes, suggesting avenues for future disaster mitigation through the provision of mental health servic
294 ts as a function of net greenhouse gas (GHG) mitigation: To achieve the same 73% mitigation as MEA-PC
295                 Rancher reported efficacy of mitigation varied by predator species, mitigation strate
296              Interestingly, carbon emissions mitigation via increasing biofuels production resulted i
297 cts on the water cycle and opportunities for mitigation warrant consideration.
298 emonstrate a potential constraint on climate mitigation when such forests are replaced by plantations
299 of radiation pneumonitis in time to initiate mitigation will benefit those exposed to radiation in th
300 s affecting food security and climate change mitigation, within multi-species agricultural contexts.

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