Implementation and appraisal of an in-fibre Bragg grating quasi-distributed health and usage monitoring system with applications to advanced materials

O'Dwyer, Martin Joseph

January 2000

No description available.

621.381045

Protein Identification Algorithms Developed from Statistical Analysis of MS/MS Fragmentation Patterns

Li, Wenzhou

January 2012

Tandem mass spectrometry is widely used in proteomic studies because of its ability to identify large numbers of peptides from complex mixtures. In a typical LC-MS/MS experiment, thousands of tandem mass spectra will be collected and peptide identification algorithms are of great importance to translate them into peptide sequences. Though these spectra contain both m/z and intensity values, most popular protein identification algorithms primarily use predicted fragment m/z values to assign peptide sequences to fragmentation spectra. The intensity information is often undervalued, because it is not as easy to predict and incorporate into algorithms. Nevertheless, the use of intensity to assist peptide identification is an attractive prospect and can potentially improve the confidence of matches and generate more identifications. In this dissertation, an unsupervised statistical method, K-means clustering, was used to study peptide fragmentation patterns for both CID and ETD data, and many unique fragmentation features were discovered. For instance, strong c(n-1) ions were observed in ETD, indicating that the fragmentation site in ETD is highly related to the amino acid residue location. Based on the fragmentation patterns observed through data mining, a peptide identification algorithm that makes use of these patterns was developed. The program is named SQID and it is the first algorithm in our bioinformatics project. Our testing results using multiple public datasets indicated an improvement in the number of identified peptides compared with popular proteomics algorithms such as Sequest or X!Tandem. SQID was further extended to improve cross-linked peptide identification (SQID-XLink) as well as blind modification identification (SQID-Mod), and both of them showed significant improvement compared with existing methods. In this dissertation the SQID algorithm was also successfully applied to a mosquito proteomics project. We are incorporating new features and new algorithms to our software, such as more fragmentation methods, more accurate spectra prediction and more user-friendly interface. We hope the SQID project can continually benefit researchers and help to improve the data analysis of proteomics community.

peptide fragmentation pattern

Chemistry

algorithm

mass spectrometry

Evolutionary optimisation for electromagnetics design

Kemp, Benjamin

January 2000

No description available.

621.382

Analysis and prediction of protein-protein recognition

Betts, Matthew James

January 1999

No description available.

572

A computational model of learning in Go

Follett, Stephen James

January 2001

No description available.

370

Nonlinear systems identification using the Narmax method

Mao, Ke Zhi

January 1998

No description available.

629.8

Multidisciplinary optimisation using evolutionary computing

Khatib, Wael

January 1999

No description available.

621.39

The development and analysis of algorithms for constructing digitised straight lines

Castle, C.

January 1986

No description available.

510

Algorithm for chain code symmetry

The reduction tomography of materials-forming processes

Toft, Malcolm

January 1999

No description available.

519

Automated comparative protein modelling

May, Alexander Conrad William

January 1996

No description available.

572

3-D structures; Genetic algorithm