Exemplo n.º 1
0
        private void LoadSpectralLibraries(out List <string> errors)
        {
            errors = new List <string>();

            try
            {
                SpectralLibrary = new SpectralLibrary(SpectralLibraryPaths.ToList());
            }
            catch (Exception e)
            {
                SpectralLibrary = null;
                errors.Add("Problem loading spectral library: " + e.Message);
            }
        }
Exemplo n.º 2
0
        public static void CalculateSpectralAngles(SpectralLibrary spectralLibrary, PeptideSpectralMatch[] peptideSpectralMatches,
                                                   Ms2ScanWithSpecificMass[] arrayOfSortedMs2Scans, CommonParameters commonParameters)
        {
            foreach (PeptideSpectralMatch psm in peptideSpectralMatches.Where(p => p != null))
            {
                Ms2ScanWithSpecificMass scan = arrayOfSortedMs2Scans[psm.ScanIndex];

                //TODO: spectral angle could be used to disambiguate PSMs. right now for ambiguous PSMs, the spectral angle for only one peptide option is saved
                foreach (var peptide in psm.PeptidesToMatchingFragments)
                {
                    if (spectralLibrary == null || !spectralLibrary.TryGetSpectrum(peptide.Key.FullSequence, scan.PrecursorCharge, out var librarySpectrum))
                    {
                        continue;
                    }

                    double spectralAngle = CalculateNormalizedSpectralAngle(librarySpectrum.MatchedFragmentIons, scan.TheScan, commonParameters);

                    psm.SpectralAngle = spectralAngle;
                }
            }
        }
Exemplo n.º 3
0
        public static void CalculateSpectralAngles(SpectralLibrary spectralLibrary, PeptideSpectralMatch[] psms,
                                                   Ms2ScanWithSpecificMass[] arrayOfSortedMs2Scans, CommonParameters commonParameters)
        {
            if (spectralLibrary != null)
            {
                // one lock for each MS2 scan; a scan can only be accessed by one thread at a time
                var myLocks = new object[psms.Length];
                for (int i = 0; i < myLocks.Length; i++)
                {
                    myLocks[i] = new object();
                }

                int   maxThreadsPerFile = commonParameters.MaxThreadsToUsePerFile;
                int[] threads           = Enumerable.Range(0, maxThreadsPerFile).ToArray();
                Parallel.ForEach(threads, (i) =>
                {
                    // Stop loop if canceled
                    if (GlobalVariables.StopLoops)
                    {
                        return;
                    }
                    for (; i < psms.Length; i += maxThreadsPerFile)
                    {
                        lock (myLocks[i])
                        {
                            if (psms[i] != null)
                            {
                                Ms2ScanWithSpecificMass scan = arrayOfSortedMs2Scans[psms[i].ScanIndex];
                                List <(int, PeptideWithSetModifications)> pwsms = new();
                                List <double> pwsmSpectralAngles = new();
                                foreach (var(Notch, Peptide) in psms[i].BestMatchingPeptides)
                                {
                                    //if peptide is target, directly look for the target's spectrum in the spectral library
                                    if (!Peptide.Protein.IsDecoy && spectralLibrary.TryGetSpectrum(Peptide.FullSequence, scan.PrecursorCharge, out var librarySpectrum))
                                    {
                                        SpectralSimilarity s = new SpectralSimilarity(scan.TheScan.MassSpectrum, librarySpectrum.XArray, librarySpectrum.YArray, SpectralSimilarity.SpectrumNormalizationScheme.squareRootSpectrumSum, commonParameters.ProductMassTolerance.Value, false);
                                        if (s.SpectralContrastAngle().HasValue)
                                        {
                                            pwsms.Add((Notch, Peptide));
                                            pwsmSpectralAngles.Add((double)s.SpectralContrastAngle());
                                        }
                                    }

                                    //if peptide is decoy, look for the decoy's corresponding target's spectrum in the spectral library and generate decoy spectrum by function GetDecoyLibrarySpectrumFromTargetByRevers
                                    else if (Peptide.Protein.IsDecoy && spectralLibrary.TryGetSpectrum(Peptide.PeptideDescription, scan.PrecursorCharge, out var targetlibrarySpectrum))
                                    {
                                        var decoyPeptideTheorProducts = new List <Product>();
                                        Peptide.Fragment(commonParameters.DissociationType, commonParameters.DigestionParams.FragmentationTerminus, decoyPeptideTheorProducts);
                                        var decoylibrarySpectrum = GetDecoyLibrarySpectrumFromTargetByReverse(targetlibrarySpectrum, decoyPeptideTheorProducts);
                                        SpectralSimilarity s     = new SpectralSimilarity(scan.TheScan.MassSpectrum, decoylibrarySpectrum.Select(x => x.Mz).ToArray(), decoylibrarySpectrum.Select(x => x.Intensity).ToArray(), SpectralSimilarity.SpectrumNormalizationScheme.squareRootSpectrumSum, commonParameters.ProductMassTolerance.Value, false);
                                        if (s.SpectralContrastAngle().HasValue)
                                        {
                                            pwsms.Add((Notch, Peptide));
                                            pwsmSpectralAngles.Add((double)s.SpectralContrastAngle());
                                        }
                                    }
                                }
                                if (pwsmSpectralAngles.Count > 0 && !pwsmSpectralAngles.Max().Equals(null))
                                {
                                    psms[i].SpectralAngle = pwsmSpectralAngles.Max();
                                }
                                else
                                {
                                    psms[i].SpectralAngle = -1;
                                }
                            }
                        }