7 research outputs found
DataSheet_1_Elucidating common pathogenic transcriptional networks in infective endocarditis and sepsis: integrated insights from biomarker discovery and single-cell RNA sequencing.docx
BackgroundInfective Endocarditis (IE) and Sepsis are two closely related infectious diseases, yet their shared pathogenic mechanisms at the transcriptional level remain unclear. This research gap poses a barrier to the development of refined therapeutic strategies and drug innovation.MethodsThis study employed a collaborative approach using both microarray data and single-cell RNA sequencing (scRNA-seq) data to identify biomarkers for IE and Sepsis. It also offered an in-depth analysis of the roles and regulatory patterns of immune cells in these diseases.ResultsWe successfully identified four key biomarkers correlated with IE and Sepsis, namely CD177, IRAK3, RNASE2, and S100A12. Further investigation revealed the central role of Th1 cells, B cells, T cells, and IL-10, among other immune cells and cytokines, in the pathogenesis of these conditions. Notably, the small molecule drug Matrine exhibited potential therapeutic effects by targeting IL-10. Additionally, we discovered two Sepsis subgroups with distinct inflammatory responses and therapeutic strategies, where CD177 demonstrated significant classification value. The reliability of CD177 as a biomarker was further validated through qRT-PCR experiments.ConclusionThis research not only paves the way for early diagnosis and treatment of IE and Sepsis but also underscores the importance of identifying shared pathogenic mechanisms and novel therapeutic targets at the transcriptional level. Despite limitations in data volume and experimental validation, these preliminary findings add new perspectives to our understanding of these complex diseases.</p
Integrating CRISPR-Cas12a into a Microfluidic Dual-Droplet Device Enables Simultaneous Detection of HPV16 and HPV18
Fast, simplified, and multiplexed detection of human
papillomaviruses
(HPVs) is of great importance for both clinical management and population
screening. However, current HPV detection methods often require sophisticated
instruments and laborious procedures to detect multiple targets. In
this work, we developed a simple microfluidic dual-droplet device
(M-D3) for the simultaneous detection of HPV16 and HPV18 by combining
the CRISPR-Cas12a system and multiplexed recombinase polymerase amplification
(RPA) assay. A new approach of combining pressure/vacuum was proposed
for efficient droplet generation with minimal sample consumption.
Two groups of droplets that separately encapsulate the relevant Cas12a/crRNA
and the fluorescent green or red reporters are parallelly generated,
followed by automatic imaging to discriminate the HPV subtypes based
on the specific fluorescence of the droplets. The M-D3 platform performs
with high sensitivity (∼0.02 nM for unamplified plasmids) and
specificity in detecting HPV16 and HPV18 DNA. By combining the RPA
and Cas12a assay, M-D3 allows on-chip detection of HPV16 and HPV18
DNA simultaneously within 30 min, reaching a detection limit of 10–18 M (∼1 copy/reaction). Moreover, the outstanding
performance of M-D3 was validated in testing 20 clinical patient samples
with HPV infection risk, showing a sensitivity of 92.3% and a specificity
of 100%. By integrating the dual-droplet generator, CRISPR-Cas12a,
and multiplexed RPA, the M-D3 platform provides an efficient way to
discriminate the two most harmful HPV subtypes and holds great potential
in the applications of multiplexed nucleic acid testing
Integrating CRISPR-Cas12a into a Microfluidic Dual-Droplet Device Enables Simultaneous Detection of HPV16 and HPV18
Fast, simplified, and multiplexed detection of human
papillomaviruses
(HPVs) is of great importance for both clinical management and population
screening. However, current HPV detection methods often require sophisticated
instruments and laborious procedures to detect multiple targets. In
this work, we developed a simple microfluidic dual-droplet device
(M-D3) for the simultaneous detection of HPV16 and HPV18 by combining
the CRISPR-Cas12a system and multiplexed recombinase polymerase amplification
(RPA) assay. A new approach of combining pressure/vacuum was proposed
for efficient droplet generation with minimal sample consumption.
Two groups of droplets that separately encapsulate the relevant Cas12a/crRNA
and the fluorescent green or red reporters are parallelly generated,
followed by automatic imaging to discriminate the HPV subtypes based
on the specific fluorescence of the droplets. The M-D3 platform performs
with high sensitivity (∼0.02 nM for unamplified plasmids) and
specificity in detecting HPV16 and HPV18 DNA. By combining the RPA
and Cas12a assay, M-D3 allows on-chip detection of HPV16 and HPV18
DNA simultaneously within 30 min, reaching a detection limit of 10–18 M (∼1 copy/reaction). Moreover, the outstanding
performance of M-D3 was validated in testing 20 clinical patient samples
with HPV infection risk, showing a sensitivity of 92.3% and a specificity
of 100%. By integrating the dual-droplet generator, CRISPR-Cas12a,
and multiplexed RPA, the M-D3 platform provides an efficient way to
discriminate the two most harmful HPV subtypes and holds great potential
in the applications of multiplexed nucleic acid testing
Integrating CRISPR-Cas12a into a Microfluidic Dual-Droplet Device Enables Simultaneous Detection of HPV16 and HPV18
Fast, simplified, and multiplexed detection of human
papillomaviruses
(HPVs) is of great importance for both clinical management and population
screening. However, current HPV detection methods often require sophisticated
instruments and laborious procedures to detect multiple targets. In
this work, we developed a simple microfluidic dual-droplet device
(M-D3) for the simultaneous detection of HPV16 and HPV18 by combining
the CRISPR-Cas12a system and multiplexed recombinase polymerase amplification
(RPA) assay. A new approach of combining pressure/vacuum was proposed
for efficient droplet generation with minimal sample consumption.
Two groups of droplets that separately encapsulate the relevant Cas12a/crRNA
and the fluorescent green or red reporters are parallelly generated,
followed by automatic imaging to discriminate the HPV subtypes based
on the specific fluorescence of the droplets. The M-D3 platform performs
with high sensitivity (∼0.02 nM for unamplified plasmids) and
specificity in detecting HPV16 and HPV18 DNA. By combining the RPA
and Cas12a assay, M-D3 allows on-chip detection of HPV16 and HPV18
DNA simultaneously within 30 min, reaching a detection limit of 10–18 M (∼1 copy/reaction). Moreover, the outstanding
performance of M-D3 was validated in testing 20 clinical patient samples
with HPV infection risk, showing a sensitivity of 92.3% and a specificity
of 100%. By integrating the dual-droplet generator, CRISPR-Cas12a,
and multiplexed RPA, the M-D3 platform provides an efficient way to
discriminate the two most harmful HPV subtypes and holds great potential
in the applications of multiplexed nucleic acid testing
Integrating CRISPR-Cas12a into a Microfluidic Dual-Droplet Device Enables Simultaneous Detection of HPV16 and HPV18
Fast, simplified, and multiplexed detection of human
papillomaviruses
(HPVs) is of great importance for both clinical management and population
screening. However, current HPV detection methods often require sophisticated
instruments and laborious procedures to detect multiple targets. In
this work, we developed a simple microfluidic dual-droplet device
(M-D3) for the simultaneous detection of HPV16 and HPV18 by combining
the CRISPR-Cas12a system and multiplexed recombinase polymerase amplification
(RPA) assay. A new approach of combining pressure/vacuum was proposed
for efficient droplet generation with minimal sample consumption.
Two groups of droplets that separately encapsulate the relevant Cas12a/crRNA
and the fluorescent green or red reporters are parallelly generated,
followed by automatic imaging to discriminate the HPV subtypes based
on the specific fluorescence of the droplets. The M-D3 platform performs
with high sensitivity (∼0.02 nM for unamplified plasmids) and
specificity in detecting HPV16 and HPV18 DNA. By combining the RPA
and Cas12a assay, M-D3 allows on-chip detection of HPV16 and HPV18
DNA simultaneously within 30 min, reaching a detection limit of 10–18 M (∼1 copy/reaction). Moreover, the outstanding
performance of M-D3 was validated in testing 20 clinical patient samples
with HPV infection risk, showing a sensitivity of 92.3% and a specificity
of 100%. By integrating the dual-droplet generator, CRISPR-Cas12a,
and multiplexed RPA, the M-D3 platform provides an efficient way to
discriminate the two most harmful HPV subtypes and holds great potential
in the applications of multiplexed nucleic acid testing
Integrating CRISPR-Cas12a into a Microfluidic Dual-Droplet Device Enables Simultaneous Detection of HPV16 and HPV18
Fast, simplified, and multiplexed detection of human
papillomaviruses
(HPVs) is of great importance for both clinical management and population
screening. However, current HPV detection methods often require sophisticated
instruments and laborious procedures to detect multiple targets. In
this work, we developed a simple microfluidic dual-droplet device
(M-D3) for the simultaneous detection of HPV16 and HPV18 by combining
the CRISPR-Cas12a system and multiplexed recombinase polymerase amplification
(RPA) assay. A new approach of combining pressure/vacuum was proposed
for efficient droplet generation with minimal sample consumption.
Two groups of droplets that separately encapsulate the relevant Cas12a/crRNA
and the fluorescent green or red reporters are parallelly generated,
followed by automatic imaging to discriminate the HPV subtypes based
on the specific fluorescence of the droplets. The M-D3 platform performs
with high sensitivity (∼0.02 nM for unamplified plasmids) and
specificity in detecting HPV16 and HPV18 DNA. By combining the RPA
and Cas12a assay, M-D3 allows on-chip detection of HPV16 and HPV18
DNA simultaneously within 30 min, reaching a detection limit of 10–18 M (∼1 copy/reaction). Moreover, the outstanding
performance of M-D3 was validated in testing 20 clinical patient samples
with HPV infection risk, showing a sensitivity of 92.3% and a specificity
of 100%. By integrating the dual-droplet generator, CRISPR-Cas12a,
and multiplexed RPA, the M-D3 platform provides an efficient way to
discriminate the two most harmful HPV subtypes and holds great potential
in the applications of multiplexed nucleic acid testing
Single Cell Chemical Proteomics with Membrane-Permeable Activity-Based Probe for Identification of Functional Proteins in Lysosome of Tumors
Proteomics at single-cell resolution
can help to identify the heterogeneity
among cell populations, shows more and more significance in current
chemistry and biology. In this work, we demonstrated a new single
cell chemical proteomic (SCCP) strategy with a membrane-permeable
activity-based probe (ABP) to characterize the functional proteins
in lysosome located in the cytosol. The ABP targeted to the cysteine
cathepsin family protein, CpFABP-G, was designed for cysteine cathepsins
labeling. The labeled HeLa cell of a cancer cell line was injected
into a capillary and was lysed by SDS solution with heating. The lysate
was then online readout by capillary electrophoresis-laser-induced
fluorescence method. Due to the employment of highly specified ABP
kicking out the uncorrelated proteins, the expression of cysteine
cathepsins in individual HeLa cells was easily detected, and heterogeneity
among those HeLa cells was readily discriminated. Further work was
concentrated on SCCP analysis of the mouse leukemia cell of monocyte
macrophage (RAW264.7). It was for the first time identifying two expression
modes of cysteine cathepsins in RAW264.7, which could be undermined
by the analysis of cell populations. We believed that SCCP would be
one of the powerful alternatives for proteomics at single-cell resolution