Silicon nitride as a versatile growth substrate for microspectroscopic imaging and mapping of individual cells

Carter, Elizabeth A.; Rayner, Benjamin S.; McLeod, Andrew I.; Wu, Lindsay E.; Marshall, Craig P.; Levina, Aviva; Aitken, Jade B.; Witting, Paul K.; Lai, Barry; Cai, Zhonghou; Vogt, Stefan; Lee, Yao-Chang; Chen, Ching-Iue; Tobin, Mark J.; Harris, Hugh H.; Lay, Peter A.

doi:10.1039/c001499k

Cited by 73 publications

(72 citation statements)

References 34 publications

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“…This study also demonstrated that the spectroscopic features reported in this paper are also observed in FTIR spectroscopic images collected in transmission mode from thin sections mounted on Si 3 N 4 windows (see the Supporting Information), which do not suffer from this artifact and also have the advantage of being able to be used with a large range of microscopies and microspectroscopies. 53 Data Analyses. FTIR spectroscopic data were processed (normalized to the area of the amide I band at 1690−1610 cm −1 ) and functional group images were generated using Cytospec software (Cytospec, version 1.2.04).…”

Section: ■ Conclusionmentioning

confidence: 99%

FTIR Imaging of Brain Tissue Reveals Crystalline Creatine Deposits Are an ex Vivo Marker of Localized Ischemia during Murine Cerebral Malaria: General Implications for Disease Neurochemistry

Hackett

Lee

El‐Assaad³

et al. 2012

ACS Chem. Neurosci.

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Phosphocreatine is a major cellular source of high energy phosphates, which is crucial to maintain cell viability under conditions of impaired metabolic states, such as decreased oxygen and energy availability (i.e., ischemia). Many methods exist for the bulk analysis of phosphocreatine and its dephosphorylated product creatine; however, no method exists to image the distribution of creatine or phosphocreatine at the cellular level. In this study, Fourier transform infrared (FTIR) spectroscopic imaging has revealed the ex vivo development of creatine microdeposits in situ in the brain region most affected by the disease, the cerebellum of cerebral malaria (CM) diseased mice; however, such deposits were also observed at significantly lower levels in the brains of control mice and mice with severe malaria. In addition, the number of deposits was observed to increase in a time-dependent manner during dehydration post tissue cutting. This challenges the hypotheses in recent reports of FTIR spectroscopic imaging where creatine microdeposits found in situ within thin sections from epileptic, Alzheimer's (AD), and amlyoid lateral sclerosis (ALS) diseased brains were proposed to be disease specific markers and/or postulated to contribute to the brain pathogenesis. As such, a detailed investigation was undertaken, which has established that the creatine microdeposits exist as the highly soluble HCl salt or zwitterion and are an ex-vivo tissue processing artifact and, hence, have no effect on disease pathogenesis. They occur as a result of creatine crystallization during dehydration (i.e., air-drying) of thin sections of brain tissue. As ischemia and decreased aerobic (oxidative metabolism) are common to many brain disorders, regions of elevated creatine-tophosphocreatine ratio are likely to promote crystal formation during tissue dehydration (due to the lower water solubility of creatine relative to phosphocreatine). The results of this study have demonstrated that although the deposits do not occur in vivo, and do not directly play any role in disease pathogenesis, increased levels of creatine deposits within air-dried tissue sections serve as a highly valuable marker for the identification of tissue regions with an altered metabolic status. In this study, the location of crystalline creatine deposits were used to identify whether an altered metabolic state exists within the molecular and granular layers of the cerebellum during CM, which complements the recent discovery of decreased oxygen availability in the brain during this disease. KEYWORDS: FTIR imaging, cerebral malaria, metabolism, creatine, ischemia, neurodegeneration T he total brain creatine pool (Cr T ) is the sum of the phosphorylated (Cr P ) and dephosphorylated (Cr) forms, and serves as an immediate supply of high energy phosphates under ATP depleting conditions. 1,2 A decrease in the Cr P level, and a corresponding increase in the dephosphorylated product (Cr), is observed in many neurodegenerative disorders in which ischemic conditions (reduce...

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Section: ■ Conclusionmentioning

confidence: 99%

FTIR Imaging of Brain Tissue Reveals Crystalline Creatine Deposits Are an ex Vivo Marker of Localized Ischemia during Murine Cerebral Malaria: General Implications for Disease Neurochemistry

Hackett

Lee

El‐Assaad³

et al. 2012

ACS Chem. Neurosci.

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“…The sample environment and window material need to be chosen deliberately to be x-ray compatible (resistant to the radiation and avoiding a strong background signal) and suited for cell culture. Silicon nitride (Si 3 N 4 ) membranes have proven to be an excellent growth substrate as well as window material [16].…”

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confidence: 99%

Scanning X-Ray Nanodiffraction on Living Eukaryotic Cells in Microfluidic Environments

et al. 2014

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High-resolution x-ray imaging techniques offer a variety of possibilities for studying the nanoscale structure of biological cells. A challenging task remains the study of cells by x rays in their natural, aqueous environment. Here, we overcome this limitation by presenting scanning x-ray diffraction measurements with beam sizes in the range of a few hundred nm on living and fixed-hydrated eukaryotic cells in microfluidic devices which mimic a native environment. The direct comparison between fixed-hydrated and living cells shows distinct differences in the scattering signal, pointing to structural changes on the order of 30 to 50 nm.

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“…Historically, different substrates, ranging from thin polycarbonate foils/films [35][36][37] , formvar coated gold transmission electron microscopy (TEM) grids [38][39][40][41][42] and silicon nitride windows 5,17,[43][44][45][46] , have been used to grow mammalian cells and used for X-ray fluorescence imaging. In comparison among the existing and potential substrates for imaging adherent mammalian cells by XFM, silicon nitride membrane (Si 3 N 4 ) windows are most suitable due to their low fluorescence background and relatively simple elemental composition [4][5][6]47,48 . In addition Si 3 N 4 windows support robust cell attachment and proliferation.…”

Section: Discussionmentioning

confidence: 99%

Preparing Adherent Cells for X-ray Fluorescence Imaging by Chemical Fixation

Finney

Jin²

2015

JoVE

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X-ray fluorescence imaging allows us to non-destructively measure the spatial distribution and concentration of multiple elements simultaneously over large or small sample areas. It has been applied in many areas of science, including materials science, geoscience, studying works of cultural heritage, and in chemical biology. In the case of chemical biology, for example, visualizing the metal distributions within cells allows us to study both naturally-occurring metal ions in the cells, as well as exogenously-introduced metals such as drugs and nanoparticles. Due to the fully hydrated nature of nearly all biological samples, cryo-fixation followed by imaging under cryogenic temperature represents the ideal imaging modality currently available. However, under the circumstances that such a combination is not easily accessible or practical, aldehyde based chemical fixation remains useful and sometimes inevitable. This article describes in as much detail as possible in the preparation of adherent mammalian cells by chemical fixation for X-ray fluorescent imaging. Video LinkThe video component of this article can be found at

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Silicon nitride as a versatile growth substrate for microspectroscopic imaging and mapping of individual cells

Cited by 73 publications

References 34 publications

FTIR Imaging of Brain Tissue Reveals Crystalline Creatine Deposits Are an ex Vivo Marker of Localized Ischemia during Murine Cerebral Malaria: General Implications for Disease Neurochemistry

FTIR Imaging of Brain Tissue Reveals Crystalline Creatine Deposits Are an ex Vivo Marker of Localized Ischemia during Murine Cerebral Malaria: General Implications for Disease Neurochemistry

Scanning X-Ray Nanodiffraction on Living Eukaryotic Cells in Microfluidic Environments

Preparing Adherent Cells for X-ray Fluorescence Imaging by Chemical Fixation

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