Your search keyword '"Al-Assam, Hisham"' showing total 4 results

1. Automatic detection of the hippocampal region associated with Alzheimer's disease from microscopic images of mice brain

Author

Jassim, Sabah A., Agaian, Sos S., Albaidhani, Tahseen, Hawkes, Cheryl, Jassim, Sabah, Al-Assam, Hisham, Jassim, Sabah A., Agaian, Sos S., Albaidhani, Tahseen, Hawkes, Cheryl, Jassim, Sabah, and Al-Assam, Hisham

Abstract

The hippocampus is the region of the brain that is primarily associated with memory and spatial navigation. It is one of the first brain regions to be damaged when a person suffers from Alzheimer's disease. Recent research in this field has focussed on the assessment of damage to different blood vessels within the hippocampal region from a high throughput brain microscopic images. The ultimate aim of our research is the creation of an automatic system to count and classify different blood vessels such as capillaries, veins, and arteries in the hippocampus region. This work should provide biologists with efficient and accurate tools in their investigation of the causes of Alzheimer's disease. Locating the boundary of the Region of Interest in the hippocampus from microscopic images of mice brain is the first essential stage towards developing such a system. This task benefits from the variation in colour channels and texture between the two sides of the hippocampus and the boundary region. Accordingly, the developed initial step of our research to locating the hippocampus edge uses a colour-based segmentation of the brain image followed by Hough transforms on the colour channel that isolate the hippocampus region. The output is then used to split the brain image into two sides of the detected section of the boundary: the inside region and the outside region. Experimental results on a sufficiently number of microscopic images demonstrate the effectiveness of the developed solution.

Published

2016

2. Automatic detection of the hippocampal region associated with Alzheimer's disease from microscopic images of mice brain

Author

Jassim, Sabah A., Agaian, Sos S., Albaidhani, Tahseen, Hawkes, Cheryl, Jassim, Sabah, Al-Assam, Hisham, Jassim, Sabah A., Agaian, Sos S., Albaidhani, Tahseen, Hawkes, Cheryl, Jassim, Sabah, and Al-Assam, Hisham

Abstract

The hippocampus is the region of the brain that is primarily associated with memory and spatial navigation. It is one of the first brain regions to be damaged when a person suffers from Alzheimer's disease. Recent research in this field has focussed on the assessment of damage to different blood vessels within the hippocampal region from a high throughput brain microscopic images. The ultimate aim of our research is the creation of an automatic system to count and classify different blood vessels such as capillaries, veins, and arteries in the hippocampus region. This work should provide biologists with efficient and accurate tools in their investigation of the causes of Alzheimer's disease. Locating the boundary of the Region of Interest in the hippocampus from microscopic images of mice brain is the first essential stage towards developing such a system. This task benefits from the variation in colour channels and texture between the two sides of the hippocampus and the boundary region. Accordingly, the developed initial step of our research to locating the hippocampus edge uses a colour-based segmentation of the brain image followed by Hough transforms on the colour channel that isolate the hippocampus region. The output is then used to split the brain image into two sides of the detected section of the boundary: the inside region and the outside region. Experimental results on a sufficiently number of microscopic images demonstrate the effectiveness of the developed solution.

Published

2016

3. Automatic Hotspots Detection for Intracellular Calcium Analysis in Fluorescence Microscopic Videos

Author

Valdés Hernández, M., González-Castro, V., Traore, David, Rietdorf, Katja, Al-Jawad, Naseer, Al-Assam, Hisham, Valdés Hernández, M., González-Castro, V., Traore, David, Rietdorf, Katja, Al-Jawad, Naseer, and Al-Assam, Hisham

Abstract

In recent years, life-cell imaging techniques and their software applications have become powerful tools to investigate complex biological mechanisms such as calcium signalling. In this paper, we propose an automated framework to detect areas inside cells that show changes in their calcium concentration i.e. the regions of interests or hotspots, based on videos taken after loading living mouse cardiomyocytes with fluorescent calcium reporter dyes. The proposed system allows an objective and efficient analysis through the following four key stages: (1) Pre-processing to enhance video quality, (2) First level segmentation to detect candidate hotspots based on adaptive thresholding on the frame level, (3) Second-level segmentation to fuse and identify the best hotspots from the entire video by proposing the concept of calcium fluorescence hit-ratio, and (4) Extraction of the changes of calcium fluorescence over time per hotspot. From the extracted signals, different measurements are calculated such as maximum peak amplitude, area under the curve, peak frequency, and inter-spike interval of calcium changes. The system was tested using calcium imaging data collected from Heart muscle cells. The paper argues that the automated proposal offers biologists a tool to speed up the processing time and mitigate the consequences of inter-intra observer variability.

4. Automatic Hotspots Detection for Intracellular Calcium Analysis in Fluorescence Microscopic Videos

Author

Valdés Hernández, M., González-Castro, V., Traore, David, Rietdorf, Katja, Al-Jawad, Naseer, Al-Assam, Hisham, Valdés Hernández, M., González-Castro, V., Traore, David, Rietdorf, Katja, Al-Jawad, Naseer, and Al-Assam, Hisham

Abstract

In recent years, life-cell imaging techniques and their software applications have become powerful tools to investigate complex biological mechanisms such as calcium signalling. In this paper, we propose an automated framework to detect areas inside cells that show changes in their calcium concentration i.e. the regions of interests or hotspots, based on videos taken after loading living mouse cardiomyocytes with fluorescent calcium reporter dyes. The proposed system allows an objective and efficient analysis through the following four key stages: (1) Pre-processing to enhance video quality, (2) First level segmentation to detect candidate hotspots based on adaptive thresholding on the frame level, (3) Second-level segmentation to fuse and identify the best hotspots from the entire video by proposing the concept of calcium fluorescence hit-ratio, and (4) Extraction of the changes of calcium fluorescence over time per hotspot. From the extracted signals, different measurements are calculated such as maximum peak amplitude, area under the curve, peak frequency, and inter-spike interval of calcium changes. The system was tested using calcium imaging data collected from Heart muscle cells. The paper argues that the automated proposal offers biologists a tool to speed up the processing time and mitigate the consequences of inter-intra observer variability.