Lanthanide metal organic frameworks (MOFs), Eu(BTC) and TbEu(BTC) were assessed to follow uptake of deoxynucleotide triphosphate (dNTPs) in loop mediated isothermal amplification (LAMP) using BST2.0. dNTPs could be determined below 150 μM. A ratiometic measurement of Tb3+:Eu3+ fluorescence in TbEu(BTC) gave a limit of detection of 2.08 μM for dNTPs. dNTP uptake slowed above 8 mM Mg2+. This correlated with end‐point and real‐time LAMP, using PicoGreen and SYBR green respectively. For the P.Mal‐Lau 18S rRNA primer set, with P. malariae a detection limit of 102.5 copies was obtained. Cross reactivity between P. malariae and P. knowlesi was shown with 18S rRNA primer sets.
Focalised hypoxia is widely prevalent in diseases such as stroke, cardiac arrest, and dementia. While in some cases hypoxia improves cellular functions, it mostly induces or exacerbates pathological changes. The lack of methodologies that can simulate focal acute hypoxia, in either animal or cell culture, impedes our understanding of the cellular consequences of hypoxia. To address this gap, an electrochemical localised oxygen scavenging system (eLOS), is reported, providing an innovative platform for spatiotemporal in vitro hypoxia modulation. The electrochemical system is modelled showing O2 flux patterns and localised O2 scavenging and hypoxia regions, as a function of distance from the electrode and surrounding flux barriers, allowing an effective focal hypoxia tool to be designed for in vitro cell culture study. O2 concentration is reduced in an electrochemically defined targeted area from normoxia to hypoxia in about 6 min depending on the O2-flux boundaries. As a result, a cell culture-well was designed, where localised O2 scavenging could be induced. The impact of localised hypoxia was demonstrated on human neural progenitor cells (hNPCs) and it was shown that miniature focal hypoxic insults can be induced, that evoke time-dependent HIF-1α transcription factor accumulation. This transcription is “patterned” across the culture according to the electrochemically induced spatiotemporal hypoxia gradient. A basic lacunar infarct model was also developed through the application of eLOS in a purpose designed microfluidic device. Miniature focal hypoxic insults were induced in cellular processes of fully oxygenated cell bodies, such as the axons of human cortical neurons. The results demonstrate experimentally that localised axonal hypoxic stress can lead to significant increase of neuronal death, despite the neurons remaining at normoxia. This suggests that focal hypoxic insult to axons alone is sufficient to impact surrounding neurons and may provide an in vitro model to study the impact of microinfarcts occurring in the deep cerebral white matter, as well as providing a promising tool for wider understanding of acute hypoxic insults with potential to uncover its pathophysiology in multiple diseases.
In the published article, there was an error in Table 2 as published. This was due to a formatting error during publication causing rows to become misplaced in the final printed copy and subscript information to be lost.The corrected Table 2 and its caption Experimental design appear below.In the published article, there was an error in Table 3 as published. This was due to a formatting error during publication causing rows to become misplaced in the final printed copy.The corrected Table 3 and its caption pH and H 2 O 2 concentration under eLOS oxygen scavenging appear below.Error in Table carried over to the index figure.In the published article, there was an error in Index figure as published. This arose as a carry-over of the error in the formatting of the table that the publishers used as index figure A corrected index figure appears below corresponding to Figure 10 in the manuscript.The authors apologize for this error and state that this does not change the scientific conclusions of the article in any way. The original article has been updated.
Oxygen concentration is one of the critical factors tightly controlled in each part of an organism to regulate the cells’ role and function. Yet, changes in tissue oxygenation often occur in small focal areas with aging or as a result of an injury. Despite the serious health implications of focal hypoxia, no methodologies exist that can model oxygen supply system accordingly in animal models or in vitro models. Therefore, we designed a novel local hypoxia system as a sensing interface for in vitro cell culture. The oxygen removal efficiencies measured by Clark electrodes showed that O2 concentration can be reduced from 20.9% / 140mmHg or 5% / 35mmHg and maintained at hypoxia (< 1.5% / 10mmHg) in 15 or 8 minutes respectively. The induced hypoxia stimulated localized time-dependent HIF-1α transcription factor nuclear accumulation at the region of interest on human neural progenitor cells. This is the first system capable of robustly generating normoxia and hypoxia side-by-side on the same culture dish for comparative study. The new culture system provides the opportunity to decipher the pathophysiology of hypoxia-related diseases including stroke, dementia and cardiovascular complications.
Oxygen concentration is one of the critical factors tightly controlled in each part of an organism to regulate the cells’ role and function. Yet, changes in tissue oxygenation often occur in small focal areas with aging or as a result of an injury. Despite the serious health implications of focal hypoxia, no methodologies exist that can model oxygen supply system accordingly in animal models or in vitro models. Therefore, we designed a novel local hypoxia system as a sensing interface for in vitro cell culture. The oxygen removal efficiencies measured by Clark electrodes showed that O2 concentration can be reduced from 20.9% / 140mmHg or 5% / 35mmHg and maintained at hypoxia (< 1.5% / 10mmHg) in 15 or 8 minutes respectively, compared with 3 hours needed by conventional incubator and hypoxic chambers. The induced hypoxia stimulated localized time-dependent HIF-1α transcription factor nuclear accumulation at the region of interest on human neural progenitor cells. This new culture system can robustly generate a hypoxia gradient in the same culture dish for the first time and provides the opportunity to decipher the impact of focal hypoxia, the function of localised oxygen homeostasis and the pathophysiology of multiple diseases.
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