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Literature Cited

  • 1
    Taams LS,Palmer DB,Akbar AN,Robinson DS,Brown Z,Hawrylowicz CM. Regulatory T cells in human disease and their potential for therapeutic manipulation. Immunology 2006; 118: 19.
  • 2
    Trzonkowski P,Szarynska M,Mysliwska J,Mysliwski A. Ex vivo expansion of CD41CD251 T regulatory cells for immunosuppressive therapy. Cytometry Part A 2009; 75A:175–188 (this issue).
  • 3
    Merson M,Denny TN. The global health and diagnostic (flow) cytometry—Breakthroughs in HIV and tuberculosis. Cytometry Part B 2008; 74B( Suppl 1): S4S5.
  • 4
    Rouet F,Rouzioux C. The measurement of HIV-1 viral load in resource-limited settings: How and where? Clin Lab 2007; 53: 135148.
  • 5
    Peter T,Badrichani A,Wu E,Freeman R,Ncube B,Ariki F,Daily J,Shimada Y,Murtagh M. Challenges in implementing CD4 testing in resource-limited settings. Cytometry Part B 2008; 74B( Suppl 1): S123S130.
  • 6
    Abayomi EA,Landis RC. Flow cytometry as the spearhead for delivering sustainable and versatile laboratory services to HIV-burdened health care systems of the developing world: A Caribbean model. Cytometry Part B 2008; 74B( Suppl 1): S80S89.
  • 7
    Shapiro HM,Perlmutter NG. Killer applications: toward affordable rapid cell-based diagnostics for malaria and tuberculosis. Cytometry Part B 2008; 74B( Suppl 1): S152S164
  • 8
    Greve B,Weidner J,Cassens U,Odaibo G,Olaleye D,Sibrowski W,Reichelt D,Nasdala I,Göhde W. A new affordable flow cytometry based method to measure HIV-1 viral load. Cytometry Part A 2009; 75A:199–206 (this issue).
  • 9
    Lizard G. Diagnosing HIV Infection Using Flow Cytometry: From antigenic analyses to a specifically dedicated bead-based assay to measure viral load. Cytometry Part A 2009; 75A:172–174 (this issue).
  • 10
    Jimenez-Diaz MB,Mulet T,Gomez V,Viera S,Alvarez A,Garuti H,Vazquez Y,Fernandez A,Ibanez J,Jimenez M,Gargallo-Viola D,Angulo-Barturen I. Quantitative measurement of plasmodium-infected erythrocytes in murine models of malaria by flow cytometry using bidimensional assessment of SYTO-16 fluorescence. Cytometry Part A 2009; 75A:225–235 (this issue).
  • 11
    Ramirez S,Aiken CT,Andrzejewski B,Sklar LA,Edwards BS. High-throughput flow cytometry: Validation in microvolume bioassays. Cytometry Part A 2003; 53A: 5565.
  • 12
    Young SM,Bologa CM,Fara D,Bryant BK,Strouse JJ,Arterburn JB,Ye RD,Oprea TI,Prossnitz ER,Sklar LA,Edwards BS. Duplex high-throughput flow cytometry screen identifies two novel formylpeptide receptor family probes. Cytometry Part A 2009; 75A:253–263 (this issue).
  • 13
    Strouse JJ,Young SM,Mitchell HD,Ye RD,Prossnitz ER,Sklar LA,Edwards BS. A novel fluorescent cross-reactive formylpeptide receptor/formylpeptide receptor-like 1 hexapeptide ligand. Cytometry Part A 2009; 75A:264–270 (this issue).
  • 14
    Chi KR. Super-resolution microscopy: Breaking the limits. Nat Methods 2009; 6: 1518.
  • 15
    Abella M,Zubeldia JM,Conejero L,Malpica N,Vaquero JJ,Desco M. Automatic quantification of histological studies in allergic asthma. Cytometry Part A 2009; 75A:271–277 (this issue).
  • 16
    Zoog SJ,Itano A,Trueblood E,Pacheco E,Zhou L,Zhang X,Ferbas J,Ng GY,Juan G. Antagonists of CD117 (cKit) signaling inhibit mast cell accumulation in healing skin wounds. Cytometry Part A 2009; 75A:189–198 (this issue).
  • 17
    Peterson RA,Krull DL,Butler L. Applications of laser scanning cytometry in immunohistochemistry and routine histopathology. Toxicol Pathol 2008; 36: 117132.
  • 18
    Robers M,Pinson P,Leong L,Batchelor RH,Gee KR,Machleidt T. Fluorescent labeling of proteins in living cells using the FKBP12(F36V) tag. Cytometry Part A 2009; 75A:207–224 (this issue).
  • 19
    Shaner NC,Lin MZ,McKeown MR,Steinbach PA,Hazelwood KL,Davidson MW,Tsien RY. Improving the photostability of bright monomeric orange and red fluorescent proteins. Nat Methods 2008; 5: 545551.
  • 20
    Subach FV,Subach OM,Gundorov IS,Morozova KS,Piatkevich KD,Cuervo AM,Verkhusha VV. Monomeric fluorescent timers that change color from blue to red report on cellular trafficking. Nat Chem Biol (in press).
  • 21
    Gerashchenko BI,Dynlacht JR. A tool for enhancement and scoring of DNA repair foci. Cytometry Part A 2009; 75A: 245252 (this issue).
  • 22
    Bratosin D,Tcacenco L,Sidoroff M,Cotoraci C,Slomianny C,Estaquier J,Montreuil J. Active caspases-8 and -3 in circulating human erythrocytes purified on immobilized annexin-V: A cytometric demonstration. Cytometry Part A 2009; 75A:236–244 (this issue).
  • 23
    Zhao H,Tanaka T,Halicka HD,Traganos F,Zarebski M,Dobrucki J,Darzynkiewicz Z. Cytometric assessment of DNA damage by exogenous and endogenous oxidants reports aging-related processes. Cytometry Part A 2007; 71A: 905914.
  • 24
    Tanaka T,Huang X,Halicka HD,Zhao H,Traganos F,Albino AP,Dai W,Darzynkiewicz Z. Cytometry of ATM activation and histone H2AX phosphorylation to estimate extent of DNA damage induced by exogenous agents. Cytometry Part A 2007; 71A: 648661.
  • 25
    Zhao T,Murphy RF. Automated learning of generative models for subcellular location: Building blocks for systems biology. Cytometry Part A 2007; 71A: 978990.
  • 26
    Lugli E,Pinti M,Nasi M,Troiano L,Ferraresi R,Mussi C,Salvioli G,Patsekin V,Robinson JP,Durante C,Cocchi M,Cossarizza A. Subject classification obtained by cluster analysis and principal component analysis applied to flow cytometric data. Cytometry Part A 2007; 71A: 334344.
  • 27
    Meijering E,Jacob M,Sarria JC,Steiner P,Hirling H,Unser M. Design and validation of a tool for neurite tracing and analysis in fluorescence microscopy images. Cytometry Part A 2004; 58A: 167176.
  • 28
    Valet G. Cytomics, the human cytome project and systems biology: Top-down resolution of the molecular biocomplexity of organisms by single cell analysis. Cell Prolif 2005; 38: 171174.
  • 29
    Tárnok A,Brockhoff G. A lifelong dedication to cytometry—A tribute to Guenter Valet. Cytometry Part A 2007; 71A: 639642.