https://orcid.org/0000-0002-2958-7736
References
- James CA , BarfieldMD, MaassKF, PatelSR, AndersonMD. Will patient-centric sampling become the norm for clinical trials after COVID-19?Nat. Med.26(12), 1810–1811 (2020).
- Carter LJ , GarnerLV, SmootJWet al. Assay techniques and test development for COVID-19 diagnosis. ACS Cent. Sci.6(5), 591–605 (2020).
- Kalish H , Klumpp-ThomasC, HunsbergerSet al. Undiagnosed SARS-CoV-2 seropositivity during the first 6 months of the COVID-19 pandemic in the United States. Sci. Transl. Med.13(601), 1–11 (2021).
- Roxhed N , BendesA, DaleMet al. Multianalyte serology in home-sampled blood enables an unbiased assessment of the immune response against SARS-CoV-2. Nat. Commun.12(1), 1–9 (2021).
- Guerra Valero YC , WallisSC, LipmanJ, StoveC, RobertsJA, ParkerSL. Clinical application of microsampling versus conventional sampling techniques in the quantitative bioanalysis of antibiotics: a systematic review. Bioanalysis10(6), 407–423 (2018).
- Spooner N , AndersonKD, SipleJ, WickremsinheER, XuY, LeeM. Microsampling: considerations for its use in pharmaceutical drug discovery and development. Bioanalysis11(10), 1015–1038 (2019).
- Zhang Q , TomazelaD, VasicekLAet al. Automated DBS microsampling, microscale automation and microflow LC-MS for therapeutic protein PK. Bioanalysis8(7), 649–659 (2016).
- Fang K , BowenCL, KellieJF, KarlinseyMZ, EvansCA. Drug monitoring by volumetric absorptive microsampling: method development considerations to mitigate hematocrit effects. Bioanalysis10(4), 241–255 (2018).
- Yourno J . Recovery of white blood cells from dried blood spots on Guthrie cards. Screening2(4), 211–217 (1993).
- Ait Belkacem I , Mossadegh-KellerN, BourgoinPet al. Cell analysis from dried blood spots: new opportunities in immunology, hematology, and infectious diseases. Adv. Sci.8(18), 1–10 (2021).
- Heikali D , DiCarlo D. A niche for microfluidics in portable hematology analyzers. JALA15(4), 319–328 (2010).
- George-Gay B , ParkerK. Understanding the complete blood count with differential. J. Perianesthesia Nurs.18(2), 96–117 (2003).
- Hassan U , ReddyB, DamhorstGet al. A microfluidic biochip for complete blood cell counts at the point-of-care. Technology3(4), 201–213 (2015).
- Abbasi U , ChowdhuryP, SubramaniamSet al. A cartridge based point-of-care device for complete blood count. Sci. Rep.9(1), 1–16 (2019).
- Nguyen J , WeiY, ZhengY, WangC, SunY. On-chip sample preparation for complete blood count from raw blood. Lab Chip.15(6), 1533–1544 (2015).
- Holmes D , PettigrewD, RecciusCHet al. Leukocyte analysis and differentiation using high speed microfluidic single cell impedance cytometry. Lab Chip9(20), 2881–2889 (2009).
- Han X , Van BerkelC, GwyerJ, CaprettoL, MorganH. Microfluidic lysis of human blood for leukocyte analysis using single cell impedance cytometry. Anal. Chem.84(2), 1070–1075 (2012).
- Evander M , RiccoAJ, MorserJ, KovacsGTA, LeungLLK, GiovangrandiL. Microfluidic impedance cytometer for platelet analysis. Lab Chip13(4), 722–729 (2013).
- Smith S , MadzivhandilaP, SewartRet al. Microfluidic cartridges for automated, point-of-care blood cell counting. SLAS Technol.22(2), 176–185 (2017).
- Li X , DengQ, LiuHet al. A smart preparation strategy for point-of-care cellular counting of trace volumes of human blood. Anal. Bioanal. Chem.411(13), 2767–2780 (2019).
- Osei-Bimpong A , JuryC, McLeanR, LewisSM. Point-of-care method for total white cell count: an evaluation of the HemoCue WBC device. Int. J. Lab. Hematol.31(6), 657–664 (2009).
- Li SH , JainA, TscharntkeT, ArnoldT, TrauDW. Hand-held photometer for instant on-spot quantification of nucleic acids, proteins, and cells. Anal. Chem.90(4), 2564–2569 (2018).
- Shi W . Red blood cell count on-a-chip. Caltech Thesis, Calif. Inst. Technol.1(ID 7166), 177 (2013).
- Roy M , JinG, SeoD, NamMH, SeoS. A simple and low-cost device performing blood cell counting based on lens-free shadow imaging technique. Sensors Actuators, B Chem.201, 321–328 (2014).
- Klein R . Bland–Altman and correlation plot. MATLAB Cent. File Exch.https://www.mathworks.com/matlabcentral/fileexchange/45049-bland-altman-and-correlation-plot
- Hauser J , KylbergG, Colomb-DelsucM, StemmeG, SintornIM, RoxhedN. A microfluidic device for TEM sample preparation. Lab Chip20(22), 4186–4193 (2020).
- Lenk G , SandkvistS, PohankaA, StemmeG, BeckO, RoxhedN. A disposable sampling device to collect volume-measured DBS directly from a fingerprick onto DBS paper. Bioanalysis7(16), 2085–2094 (2015).
- Mark D , HaeberleS, RothG, Von StettenF, ZengerleR. Microfluidic lab-on-a-chip platforms: requirements, characteristics and applications. Chem. Soc. Rev.39(3), 1153–1182 (2010).
- Prinyakupt J , PluempitiwiriyawejC. Segmentation of white blood cells and comparison of cell morphology by linear and naïve Bayes classifiers. Biomed. Eng. Online14(1), 1–19 (2015).
- Chan YK , TsaiMH, HuangDC, ZhengZH, HungKD. Leukocyte nucleus segmentation and nucleus lobe counting. BMC Bioinform.11(1), 1–18 (2010).
- Detomaso L , GristinaR, SenesiGS, D'AgostinoR, FaviaP. Stable plasma-deposited acrylic acid surfaces for cell culture applications. Biomaterials26(18), 3831–3841 (2005).