Your search keyword '"Fachin F"' showing total 11 results

1. Nanocomposite Flexible Pressure Sensor for Biomedical Applications

Author

Sepúlveda, A.T., Fachin, F., Villoria, R. Guzmán de, Wardle, B.L., Viana, J.C., Pontes, A.J., and Rocha, L.A.

Published

2011

2. Nanocomposite Flexible Pressure Sensor for Biomedical Applications.

Author

Sepúlveda, A.T., Fachin, F., Villoria, R. Guzmán de, Wardle, B.L., Viana, J.C., Pontes, A.J., and Rocha, L.A.

Abstract

Abstract: A new approach for the fabrication of flexible pressure sensors based on aligned carbon nanotubes (A-CNTs) is described in this paper. The technology is suitable for blood pressure sensors that can be attached to a stent-graft and deployed during an endovascular aneurysm repair (EVAR) procedure. Given the specifications of EVAR, the device should be foldable (extremely flexible) and characterized by a (very small) profile that integrates with the stent-graft cross section. A-CNTs embedded in a flexible substrate of polydimethylsiloxane (PDMS), a transparent, nontoxic and biocompatible silicone elastomer, are used to fabricate elements of the capacitive sensors. Fabricated prototypes validate our approach and show that CNTs/PDMS layered composites can be used to create highly flexible pressure sensors. [Copyright &y& Elsevier]

Published

2012

3. Treatment of symptomatic endobronchial hamartoma by bronchoscopy.

Author

Cano ME, Pagnoncelli Fachin F, and Felicetti JC

Subjects

Humans, Male, Middle Aged, Tomography, X-Ray Computed, Hamartoma surgery, Hamartoma diagnostic imaging, Hamartoma pathology, Bronchoscopy, Bronchial Diseases surgery, Bronchial Diseases diagnostic imaging, Bronchial Diseases pathology, COVID-19

Abstract

Hamartomas are benign tumors characterized by disorganized tissue native to a specific anatomical location. We present the case of a 61-year-old male with a history of COVID-19 infection who presented with a persistent cough. Chest tomography revealed an endobronchial lesion, which led to further investigation with a bronchoscopy. Using a cold loop, the lesion was successfully resected and pathology confirmed the diagnosis of a hamartoma.  Endobronchial resection is the preferred strategy for diagnosing and treating these tumors. This case highlights the successful management of an endobronchial hamartoma in a patient with a history of COVID-19 infection, emphasizing the importance of thorough investigation and appropriate intervention in similar cases., (Universidad Nacional de Córdoba)

Published

2024

4. A Machine-Learning Model for the Prognostic Role of C-Reactive Protein in Myocarditis.

Author

Baritussio A, Cheng CY, Lorenzoni G, Basso C, Rizzo S, De Gaspari M, Fachin F, Giordani AS, Ocagli H, Pontara E, Cattini MGP, Bison E, Gallo N, Plebani M, Tarantini G, Iliceto S, Gregori D, Marcolongo R, and Caforio ALP

Abstract

Aims: The role of inflammation markers in myocarditis is unclear. We assessed the diagnostic and prognostic correlates of C-reactive protein (CRP) at diagnosis in patients with myocarditis. Methods and results: We retrospectively enrolled patients with clinically suspected (CS) or biopsy-proven (BP) myocarditis, with available CRP at diagnosis. Clinical, laboratory and imaging data were collected at diagnosis and at follow-up visits. To evaluate predictors of death/heart transplant (Htx), a machine-learning approach based on random forest for survival data was employed. We included 409 patients (74% males, aged 37 ± 15, median follow-up 2.9 years). Abnormal CRP was reported in 288 patients, mainly with CS myocarditis (p < 0.001), recent viral infection, shorter symptoms duration (p = 0.001), chest pain (p < 0.001), better functional class at diagnosis (p = 0.018) and higher troponin I values (p < 0.001). Death/Htx was reported in 13 patients, of whom 10 had BP myocarditis (overall 10-year survival 94%). Survival rates did not differ according to CRP levels (p = 0.23). The strongest survival predictor was LVEF, followed by anti-nuclear auto-antibodies (ANA) and BP status. Conclusions: Raised CRP at diagnosis identifies patients with CS myocarditis and less severe clinical features, but does not contribute to predicting survival. Main death/Htx predictors are reduced LVEF, BP diagnosis and positive ANA.

Published

2022

5. Microfluidic isolation of platelet-covered circulating tumor cells.

Author

Jiang X, Wong KHK, Khankhel AH, Zeinali M, Reategui E, Phillips MJ, Luo X, Aceto N, Fachin F, Hoang AN, Kim W, Jensen AE, Sequist LV, Maheswaran S, Haber DA, Stott SL, and Toner M

Subjects

Biomarkers, Tumor, Breast Neoplasms pathology, Epithelial-Mesenchymal Transition, Female, Humans, Immunoassay, Lung Neoplasms pathology, Blood Platelets cytology, Cell Separation methods, Microfluidic Analytical Techniques methods, Neoplastic Cells, Circulating chemistry

Abstract

The interplay between platelets and tumor cells is known to play important roles in metastasis by enhancing tumor cell survival, tumor-vascular interactions, and escape from immune surveillance. However, platelet-covered circulating tumor cells (CTC) are extremely difficult to isolate due to masking or downregulation of surface epitopes. Here we describe a microfluidic platform that takes advantage of the satellite platelets on the surface of these "stealth" CTCs as a ubiquitous surface marker for isolation. Compared to conventional CTC enrichment techniques which rely on known surface markers expressed by tumor cells, platelet-targeted isolation is generally applicable to CTCs of both epithelial and mesenchymal phenotypes. Our approach first depletes unbound, free platelets by means of hydrodynamic size-based sorting, followed by immunoaffinity-based capture of platelet-covered CTCs using a herringbone micromixing device. This method enabled the reliable isolation of CTCs from 66% of lung and 60% of breast cancer (both epithelial) patient samples, as well as in 83% of melanoma (mesenchymal) samples. Interestingly, we observed special populations of CTCs that were extensively covered by platelets, as well as CTC-leukocyte clusters. Because these cloaked CTCs often escape conventional positive and negative isolation mechanisms, further characterization of these cells may uncover important yet overlooked biological information in blood-borne metastasis and cancer immunology.

Published

2017

6. Monolithic Chip for High-throughput Blood Cell Depletion to Sort Rare Circulating Tumor Cells.

Author

Fachin F, Spuhler P, Martel-Foley JM, Edd JF, Barber TA, Walsh J, Karabacak M, Pai V, Yu M, Smith K, Hwang H, Yang J, Shah S, Yarmush R, Sequist LV, Stott SL, Maheswaran S, Haber DA, Kapur R, and Toner M

Subjects

Automation, Laboratory instrumentation, Automation, Laboratory methods, Cell Separation instrumentation, Female, Humans, Male, Blood Cells, Cell Separation methods, Lab-On-A-Chip Devices, Neoplasms diagnosis, Neoplastic Cells, Circulating

Abstract

Circulating tumor cells (CTCs) are a treasure trove of information regarding the location, type and stage of cancer and are being pursued as both a diagnostic target and a means of guiding personalized treatment. Most isolation technologies utilize properties of the CTCs themselves such as surface antigens (e.g., epithelial cell adhesion molecule or EpCAM) or size to separate them from blood cell populations. We present an automated monolithic chip with 128 multiplexed deterministic lateral displacement devices containing ~1.5 million microfabricated features (12 µm-50 µm) used to first deplete red blood cells and platelets. The outputs from these devices are serially integrated with an inertial focusing system to line up all nucleated cells for multi-stage magnetophoresis to remove magnetically-labeled white blood cells. The monolithic CTC-iChip enables debulking of blood samples at 15-20 million cells per second while yielding an output of highly purified CTCs. We quantified the size and EpCAM expression of over 2,500 CTCs from 38 patient samples obtained from breast, prostate, lung cancers, and melanoma. The results show significant heterogeneity between and within single patients. Unbiased, rapid, and automated isolation of CTCs using monolithic CTC-iChip will enable the detailed measurement of their physicochemical and biological properties and their role in metastasis.

Published

2017

7. Microfluidic Isolation of Circulating Tumor Cell Clusters by Size and Asymmetry.

Author

Au SH, Edd J, Stoddard AE, Wong KHK, Fachin F, Maheswaran S, Haber DA, Stott SL, Kapur R, and Toner M

Subjects

Cell Separation instrumentation, Cell Survival, Flow Cytometry, Humans, Microfluidic Analytical Techniques instrumentation, Reproducibility of Results, Single-Cell Analysis instrumentation, Single-Cell Analysis methods, Cell Separation methods, Cell Size, Microfluidic Analytical Techniques methods, Neoplastic Cells, Circulating pathology

Abstract

Circulating tumor cell clusters (CTC clusters) are potent initiators of metastasis and potentially useful clinical markers for patients with cancer. Although there are numerous devices developed to isolate individual circulating tumor cells from blood, these devices are ineffective at capturing CTC clusters, incapable of separating clusters from single cells and/or cause cluster damage or dissociation during processing. The only device currently able to specifically isolate CTC clusters from single CTCs and blood cells relies on the batch immobilization of clusters onto micropillars which necessitates long residence times and causes damage to clusters during release. Here, we present a two-stage continuous microfluidic chip that isolates and recovers viable CTC clusters from blood. This approach uses deterministic lateral displacement to sort clusters by capitalizing on two geometric properties: size and asymmetry. Cultured breast cancer CTC clusters containing between 2-100 + cells were recovered from whole blood using this integrated two-stage device with minimal cluster dissociation, 99% recovery of large clusters, cell viabilities over 87% and greater than five-log depletion of red blood cells. This continuous-flow cluster chip will enable further studies examining CTC clusters in research and clinical applications.

Published

2017

8. Microfluidic, marker-free isolation of circulating tumor cells from blood samples.

Author

Karabacak NM, Spuhler PS, Fachin F, Lim EJ, Pai V, Ozkumur E, Martel JM, Kojic N, Smith K, Chen PI, Yang J, Hwang H, Morgan B, Trautwein J, Barber TA, Stott SL, Maheswaran S, Kapur R, Haber DA, and Toner M

Subjects

Humans, Insect Proteins, Magnets, Cell Separation methods, Microfluidic Analytical Techniques methods, Neoplastic Cells, Circulating

Abstract

The ability to isolate and analyze rare circulating tumor cells (CTCs) has the potential to further our understanding of cancer metastasis and enhance the care of cancer patients. In this protocol, we describe the procedure for isolating rare CTCs from blood samples by using tumor antigen-independent microfluidic CTC-iChip technology. The CTC-iChip uses deterministic lateral displacement, inertial focusing and magnetophoresis to sort up to 10⁷ cells/s. By using two-stage magnetophoresis and depletion antibodies against leukocytes, we achieve 3.8-log depletion of white blood cells and a 97% yield of rare cells with a sample processing rate of 8 ml of whole blood/h. The CTC-iChip is compatible with standard cytopathological and RNA-based characterization methods. This protocol describes device production, assembly, blood sample preparation, system setup and the CTC isolation process. Sorting 8 ml of blood sample requires 2 h including setup time, and chip production requires 2-5 d.

Published

2014

9. Nanoporous micro-element arrays for particle interception in microfluidic cell separation.

Author

Chen GD, Fachin F, Colombini E, Wardle BL, and Toner M

Subjects

Cell Line, Tumor, Cell Separation instrumentation, Dimethylpolysiloxanes chemistry, Escherichia coli isolation & purification, Humans, Microfluidic Analytical Techniques methods, Nanotubes, Carbon chemistry, Particle Size, Porosity, Cell Separation methods, Microfluidic Analytical Techniques instrumentation, Nanotechnology instrumentation

Abstract

The ability to control cell-surface interactions in order to achieve binding of specific cell types is a major challenge for microfluidic immunoaffinity cell capture systems. In the majority of existing systems, the functionalized capture surface is constructed of solid materials, where flow stagnation at the solid-liquid interface is detrimental to the convection of cells to the surface. We study the use of ultra-high porosity (99%) nanoporous micro-posts in microfluidic channels for enhancing interception efficiency of particles in flow. We show using both modelling and experiment that nanoporous posts improve particle interception compared to solid posts through two distinct mechanisms: the increase of direct interception, and the reduction of near-surface hydrodynamic resistance. We provide initial validation that the improvement of interception efficiency also results in an increase in capture efficiency when comparing nanoporous vertically aligned carbon nanotube (VACNT) post arrays with solid PDMS post arrays of the same geometry. Using both bacteria (∼1 μm) and cancer cell lines (∼15 μm) as model systems, we found capture efficiency increases by 6-fold and 4-fold respectively. The combined model and experimental platform presents a new generation of nanoporous microfluidic devices for cell isolation.

Published

2012

10. Nanoporous elements in microfluidics for multiscale manipulation of bioparticles.

Author

Chen GD, Fachin F, Fernandez-Suarez M, Wardle BL, and Toner M

Subjects

Permeability, Porosity, Microfluidics methods, Nanoparticles chemistry, Particle Size

Abstract

Solid materials, such as silicon, glass, and polymers, dominate as structural elements in microsystems including microfluidics. Porous elements have been limited to membranes sandwiched between microchannel layers or polymer monoliths. This paper reports the use of micropatterned carbon-nanotube forests confined inside microfluidic channels for mechanically and/or chemically capturing particles ranging over three orders of magnitude in size. Nanoparticles below the internanotube spacing (80 nm) of the forest can penetrate inside the forest and interact with the large surface area created by individual nanotubes. For larger particles (>80 nm), the ultrahigh porosity of the nanotube elements reduces the fluid boundary layer and enhances particle-structure interactions on the outer surface of the patterned nanoporous elements. Specific biomolecular recognition is demonstrated using cells (≈10 μm), bacteria (≈1 μm), and viral-sized particles (≈40 nm) using both effects. This technology can provide unprecedented control of bioseparation processes to access bioparticles of interest, opening new pathways for both research and point-of-care diagnostics., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2011

11. Flexible sensor for blood pressure measurement.

Author

Sepúlveda AT, Pontes AJ, Viana JC, de Villoria RG, Fachin F, Wardle BL, and Rocha LA

Subjects

Elastic Modulus, Equipment Design, Equipment Failure Analysis, Miniaturization, Reproducibility of Results, Sensitivity and Specificity, Blood Pressure Determination instrumentation, Prostheses and Implants, Telemetry instrumentation, Transducers, Pressure

Abstract

A new approach for the design and fabrication of a highly flexible blood pressure sensor is introduced in this paper. The goal is to measure the pressure within an aneurysm sac for post-endovascular aneurysms repair (EVAR) surveillance. Biocompatible polydimethylsiloxane (PDMS) membranes with embedded aligned carbon nanotubes (CNTs) are used to build the conductive elements of the pressure sensitive capacitor and the inductor for telemetry. Inductive coupling will be used to measure the internal capacitive variations. Fabricated test sensors validate the approach and demonstrate that CNTs/PDMS technology can be used to build highly flexible pressure sensors.

Published

2011