Selection and Enumeration of Low-Abundance Biological Cells from Complex Matrices

1. Selection and Enumeration of Low-Abundance Biological Cells from Complex Matrices Udara Dharmasiri Research Seminar April 19, 2010

2. “Highly Efficient Capture and Enumeration of Low Abundance Prostate Cancer Cells Using Prostate-Specific Membrane Antigen Aptamers Immobilized to a Polymeric Microfluidic Device” Electrophoresis, 2009, 30: 1-12 • “Microsystems for the Capture of Low-Abundance Cells” Annual Reviews of Analytical Chemistry, 2010, Vol. 3 • “Enrichment and Detection of Escherichia coli 0157:H7 Using An Antibody Modified Microfluidic Chip” Analytical Chemistry, 2010, 82 (7), 2844–2849 • “High-Throughput Isolation and Electrokinetic Manipulation of Circulating Tumor Cells Using a Polymeric Microfluidic Device” Manuscript in Preparation

3. Highly Efficient Capture and Enumeration of Low Abundance Prostate Cancer Cells Using Prostate-Specific Membrane Antigen Aptamers Immobilized to a Polymeric Microfluidic Device Electrophoresis, 2009, 30: 1-12

4. Clinical Utility of Circulating Tumor Cells (CTCs) • Cancer metastasis by circulating tumor cells (CTCs) • Elucidating the presence and number of CTCs is emerging as an effective method for www.metastasis.cauchoiscar.com - diagnosis - prognosis - prediction of therapeutic benefits Loeb, S. The oncologist 2008, 13, 299-305

5. Analyzing Low Abundance Material from Peripheral Blood • Red Blood Cells • 109/mL • 3 – 5 µm • Biconcave discs 1 = CTC 2 = Membrane Pore 3 = Leukocyte • White Blood Cells • 106/mL • ~15 µm • Spherical • Circulating Tumor Cells • 1 – 10/mL • 15 – 30 µm • Spherical Hayes, D. F. J. et al. 2008, Clinical Cancer Res., 14, 3646-3650 Allard, W. J. et al. 2004, Clinical Cancer Res., 10, 6897-904

6. Existing Tools for Analyzing CTCs in Peripheral Blood • Magnetic capture using microbeads coated with recognition elements • 5 log enrichment • Only mononucleated • cell fraction • 1 CTC in 106 MNC • Enumeration of cells by fluorescence visualization Dynal • Nuclear tracked polycarbonate membranes • Separation based on size • Requires whole blood density gradient centrifugation • 1 CTC in 1 mL of peripheral blood • Enumeration of cells by fluorescence visualization Vona et al., 2000, Am. J. Pathology 256: 57

7. CTC-chip ●Made from silica using DRIE and contains microposts ●Target CTCs interact with antibody (EpCAM) coated microposts ●CTCs in the peripheral blood are captured and isolated ●Capture efficiency - ~65% ●Purity - ~50% ●Cell enumeration - by cell staining Nagrath, S. Nature 2007, 450, 1235-1239

8. High Throughput Microsampling Unit (HTMSU) ●Selectively and specifically isolate breast cancer cells through a monoclonal antibody mediated process ●Sampling large input (1 ml) of whole blood in short time (<37 min) ●CTC capture efficiency >97% and purity ~100% ● The released CTCs enumerated on-device using conductivity detector with 100% detection efficiency Adams, A. A. JACS 2008, 130, 8633-8641

9. Prostate Cancer ●Prostate cancer develops in the prostate gland ●The most common type of cancer in men in the USA ●Diagnosed by Prostate Specific Antigen (PSA) test - high false positive and negative errors (30%) www.prostatecancerfoundation.org ●LNCaP (Prostate cancer cell line) - Metastasize into the lymph nodes ●LNCaP cell membrane contains Prostate Specific Membrane Antigen (PSMA) PSMA - 750 amino acids - Mw = 110 kDa - 1 x 106 molecules/cell LNCaP Cells Liu, T.Prostate, 2008, 68, 955-964

10. Aptamers for LNCaP Cell Capture NH2-(CH2)6-(CH2-CH2-O)6- CCAAGACCUGACUUCUAACUAAGUCUACGUUCC • Advantages • ● Chemically robust • ● Greater surface density • ● Properties can be changed on • demand • End-point attachment to surfaces ● Oligonucleotides ●Generated by in vitro selection process- SELEX PSMA Aptamer ●Mw = ~ 10 kDa and Kd = ~ 50 nM-1 Lupold, S. E. Cancer Res. 2002, 62, 4029-4033 Parrott, A.M Nuc. 2003, Acids Res. 28, 489-497

11. Polymer-based High-Throughput Sampling Unit for Capturing CTCs (PMMA) • 150 µm (depth) x 30 µm (width) x 3 cm (length) • Total volume = 180 nL • Number of parallel channels = 51 • Processing time for 1 mL input (4 mm/s) = 9.1 min • 4-levels of specificity (capture – 30 µm; detection – 50 µm; immunoaffinity; shear) • Integrated reader for enumerating cells

12. Production of Plastic Fluidic Components from Metal Molding Tools (2) • KERN MMP 2252 • Precision of ±1 µm • Microstructure aspect ratios ≤ 20:1 • Milling in metals, ceramics, polymers (3) (5) (6) 3) (1) CNC controller (2) 40,000 rpm spindle (3) Automated tool changer (4) Laser-based measurement system (5) Real-time imaging system (6) X-Y translational stage (4) (1)

13. Producing Parts from Metal Molding Tools • Jenoptik Microtechnik HEX 02 • Attach mould insert • Evacuate chamber • Heat substrate to Tg • (105oC - PMMA) • Thermal fusion bonding for channel enclosure (2) (3) (4) 51-channel linear 20 μm linear (5) (1) (1) 35 μm linear (1) CNC controller (2)Telescopic upper stage (3)Lower heating platen (4)Fixed stage (5)Vacuum system 50 μm linear 51-channel curvilinear

14. Immobilization of Aptamers to Polymer Surfaces 8.4 x 1012 molecules/cm2 Dharmasiri, U.R. Electrophoresis 2009, 30, 3289–3300 McCarley et al., J. Am. Chem. Soc. 2005, 127, 842-843

15. Monitoring Fluidic Optimization Measurements Carl Zeiss Axiovert ● Computer controlled ● Programmable motorized stage ● Inverted optical microscope ● Video CCD inspection ● Fluorescence imaging

16. Cell Capture Efficiency ●0.5 ml of 1,000 cells/ml suspension introduced at linear velocities between 0.1 to 10 mm/s ●Post capture rinse with 150 mM PBS at 50 mm/s linear velocity Capture determined by Encounter Rate (ko) ●The number of selected cells onto the PSMAaptamer and EpCAM antibody HTMSU counted using fluorescence microscopy Capture determined by reaction Probability (P) ■ Aptamer ■ Antibody Chang and Hammer, Biophys. J.,1999, 76, 1280 Dharmasiri, U.R. Electrophoresis 2009, 30, 3289–3300

17. Non-Specific Cell Adsorption ●PSMA aptamer immobilized onto the HTMSU i) MCF-7 - Human breast cancer cell line, does not express PSMA ii) WBC - White blood cells iii) RBC - Red blood cells introduced at 2.5 mm/s linear flow velocity ● A post capture rinse performed with PBS buffer at 50 mm/s linear velocity ● The number of cells adsorbed onto the HTMSU counted using fluorescence microscopy ●PSMA aptamer does not interact with MCF-7, WBC and RBC Dharmasiri, U.R. Electrophoresis 2009, 30, 3289–3300

18. Cell Release from the Capture Surface ● 0.25% (w/v) trypsin infused into the HTMSU ● Trypsin (23.8 KDa) – glycoprotein that proteolytically cleaves at arginine and lysine AA residues. pI = 10.5; Optimal activity at pH = 8.0 ● The process of typsination was evaluated by microscopy • Before trypsin infused • Exposed to trypsin for 2 min • Exposed to trypsin for 6.5 min - cell was released • Exposed to trypsin for 7.5 min - cell was removed Dharmasiri, U.R. Electrophoresis 2009, 30, 3289–3300

19. Automated Cell Enumeration S N ≥3 Whole blood Whole blood + LNCaP • One ml of blood containing 20 LNCaP cells seeded into the HTMSU ● The captured cells released using the trypsin prior to on-chip conductivity enumeration ● Total of 18 cells were counted at a volume flow rate of 5 µl/min ● The conductance response from whole blood without LNCaP obtained Dharmasiri, U.R. Electrophoresis 2009, 30, 3289–3300

20. Conclusions ●LNCaP cell capture efficiency for PSMA aptamer tethered microfluidic device was 95 +1% ● MCF-7 cells, WBCs and RBCs do not interfere with LNCaP cell capture and therefore cell separation purity is ~100% ● 0.25% (w/v) trypsin was an effective reagent for releasing LNCaP cells from the capture surface ● Conductivity enumeration efficiency was ~100% for the released LNCaP cells

21. Enrichment and Detection of E. coli O157:H7 from Water Samples Using an Antibody Modified Microfluidic Chip Analytical Chemistry, 2010, 82 (7), 2844–2849

22. E. coli O157:H7 • E. coli O157:H7 -gram negative bacterium • rod-shaped • 2 μm long and 0.5 μm diameter • The pathogenicity of E. coli O157:H7 is associated with the production of Shiga-like toxins • -bloody diarrhea • -colitis 2 m • In 2008, 2,000 Americans were hospitalized and • ~60 died (TC*- Total Coliform , FC*- Fecal Coliform) Alocilja, E.C. 2003. Biosens. Bioelectron. 18: 841-84

23. # colonies x100 volume processed EPA Approved Method for E. coli Detection • ß-D glucuronidase production is not present in O157:H7 serotype • E. coli O157:H7 viable but not culturable • Presence of interfering agents alter the accuracy of chromogenic media 15 cfu/100mL 24 cfu/10mL 4 cfu/1mL CFU/100 mL Cell culturing using EPA Method 1603. (LSU-BR University Lake) Bennett, A.R. 1996. Letters in Applied Microbiology 22: 237-243

24. Anti E.Coli O157:H7 Antibody • Mw = ~150 kDa • Polyclonal (pAb) • Kd = ~50 pM-1 • E. coli O157:H7 are identified by combination • of O and H antigens • 9×106 molecules of O antigen/bacteria www.kpl.com Microchip Enrichment (i) pAb can recognize O157 types for intact and non-culturable cells (ii) Selective cell capture allows cell enrichment and enumeration from potentially contaminated samples Fitzmaurice, J. Mol. Cell. Probes 2004, 18, 123-132

25. 5.5 mm Polymer-Based (PMMA) Sampling Unit forE. coli O157:H7 Selection 11 mm 8 sub devices-16 curvilinear channels-9.5 mm long, 15 µm width/80 µm depth. Surface area (cell selection bed) = 40 mm2 , volume = 250 nL Dharmasiri U. R. Anal. Chem.2010, 82 (7), 2844–2849

26. E. coli O157:H7 Selection and Enumeration 150 mM PBS solution infused at 50 mm/s linear velocity to remove non-specifically absorbed cells Dharmasiri U. R. Anal. Chem.2010, 82 (7), 2844–2849

27. System Operation Carl Zeiss Axiovert 15 m Syringe pump • Inverted optical microscope • Fluorescence imaging with high sensitivity CCD • Syringe pump • E. coli cells were stained - FITC (PKH67) - Lipophilic membrane linker

28. E. Coli O157:H7 Enumeration via RT-qPCR • PCR directed to the conserved regions within the genes encoding for SLT-I (shiga-like toxins) and the uidA gene, encodes for ß-glucuronidase in E. coli O157:H7 • Mismatch in G residue, as opposed to the T residue found in other E. coli strains) D Slt! 10 cfu Uid A 348 500 252 200 300 Threshold cycle (Ct) 6 cfu Log (cell density) [cfu] Recognition of Escherichia coli O157:H7 by mismatch amplification assay-multiplex PCR (Cebula et al.,1995, 33, 248)

29. RT-qPCR Experiment Amplification and Dissociation Curves specific DNA product (80 oC) slt1 < 75°C correspond to non-specific DNA Fluorescence (dRn) Fluorescence (-Rn(T)) Ct Cycle # Temperature (oC) Real-time qPCR results for the uidA gene Dharmasiri U. R. Anal. Chem.2010, 82 (7), 2844–2849

30. Cell Capture Efficiency Data for linear channel, depth- 80 m Data for curvilinear channel, width- 15 m and depth- 80 m Capture Efficiency (%) Capture Efficiency (%) Linear Flow Velocity (mm/s) Channel width (m) Chang/Hammer model for mobile cell interactions • Encounter rate • Probability of the reaction Dharmasiri U. R. Anal. Chem.2010, 82 (7), 2844–2849 • 3 x 103 cells/mL introduced at different volumetric flow rates • Total input volume analyzed = 500 µL Chang, K. C.; Hammer, D. A. Biophys. J. 1999, 76, 1280–1292

31. Specificity of Polyclonal Anti-E. coli O157:H7 Antibody • 3x103 cells/mL were introduced at 5 mm/s linear velocity A micrograph of capture surface E. coli O157:H7 A micrograph of capture surface E. coli K12 15 µm Dharmasiri U. R. Anal. Chem.2010, 82 (7), 2844–2849

32. Cell Release from the Capture Surface • Mixture of chelators infused into channels at 10 mm/s • Captured cells were observed microscopically until removed by release solution and Stoke’s force 4 min 0 min 0 min 4 min Avg. stripping time: 3.4 min +0.35 (n=25) • Brightfield micrograph of the captured cell before being infused the releasing solution • Fluorescent micrograph of the captured cell before being infused the releasing solution • Brightfield micrograph of the cell released surface (4 mins) • Fluorescent field micrograph of the cell released surface (4 mins) Dharmasiri U. R. Anal. Chem.2010, 82 (7), 2844–2849

33. Water Sample Evaluation * Max Capacity of the bed: 260 x 106 cells LSU Lake Dharmasiri U. R. Anal. Chem.2010, 82 (7), 2844–2849

34. Conclusions • Recovery of E. coli O157:H7was ~72% • E. coli O157:H7 was selected and enumerated without other serotype interferences • The strategy developed offered the ability to monitor recreational water quality without the need for a cell culture step • The entire processing steps were implemented in under 5 h

35. High-Throughput Isolation and Electrokinetic Manipulation of Circulating Tumor Cells Using a Polymeric Microfluidic Device Future Work

36. Objectives • Design a microfluidic device for processing 7.5 mL of blood to select CTCs in a short time period (~30 min) Allard, W.J. Clin. Cancer Res. 2004 10: 6897-904 • Electrokinetic collection of selected CTCs for molecular profiling

37. Cell Selection and Manipulation

38. High-Throughput Microsampling Unit (HTMSU) • Selectively and specifically isolate breast and prostate cancer cells through an affinity agent mediated process • Sampling 1 ml of whole blood in short time (<37 min) • CTC capture efficiency >97% and purity ~100% • The released CTCs enumerated on-device using conductivity detector with ~100% detection efficiency Adams, A. A. JACS 2008, 130, 8633-8641 Dharmasiri, U. Electrophoresis 2009, 30, 3289–3300

39. Cell Capture Section of µHTMSU Out put In put  460 curvilinear channels  Volume -100 L  Process 7.5 mL of sample in 30 min

40. Electrophoresis • Electrophoresis (EP): The force on a charged particle exerted by an electric field • Most mammalian cells are covered with negatively charged functional groups at neutral pH F = qE F - Coulomb force q- Net charge on the object E- The applied electric field • In water, the cells move at a velocity given by the balance of the Coulomb and viscous drag forces, a process known as EP Annu. Rev. Biomed. Eng. 2006. 8:425–54

41. Electrokinetics • Utilizes the electroosmotic flow (eof) of the solution and the electrophoretic mobility (ep) of the material being transported • The linear velocity (app) at which the material moves is governed by; Vassar, P.S. Nature 1963, 4873, 1215-26

42. Cell Manipulation Section of the Microfluidic Unit In put

43. Future Directions • CTCs in large volume of patients’ blood (>7.5 mL) will be selected in short time (<30 min) • Molecular profiling of CTCs • Determine biology of CTCs and cells at primary tumor • Detection of point mutations • Gene expression profiling • Genetic Make up • Adhesion properties • Metastatic potential

44. Acknowledgments Soper Research Group Prof. Steven A. Soper Prof. Robin McCarley Dr. Maggie Witek Dr. Robert Truax Ms. Karen National Science Foundation Grant NIH # - 1 R33 CA099246-01 State of Louisiana Board of Regents Texas Sea Grant (NA06OAR4170076)

45. THANK YOU