A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells

Cell motility is the brilliant result of cell status and its interaction with close environments. Its detection is now possible, thanks to the synergy of high-resolution camera sensors, time-lapse microscopy devices, and dedicated software tools for video and data analysis. In this scenario, we form...

Descripción completa

Detalles Bibliográficos
Autores principales: Comes, Maria Colomba, Mencattini, Arianna, Di Giuseppe, Davide, Filippi, Joanna, D’Orazio, Michele, Casti, Paola, Corsi, Francesca, Ghibelli, Lina, Di Natale, Corrado, Martinelli, Eugenio
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2020
Materias:
Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7085768/
https://www.ncbi.nlm.nih.gov/pubmed/32164292
http://dx.doi.org/10.3390/s20051531
_version_ 1783509008630415360
author Comes, Maria Colomba
Mencattini, Arianna
Di Giuseppe, Davide
Filippi, Joanna
D’Orazio, Michele
Casti, Paola
Corsi, Francesca
Ghibelli, Lina
Di Natale, Corrado
Martinelli, Eugenio
author_facet Comes, Maria Colomba
Mencattini, Arianna
Di Giuseppe, Davide
Filippi, Joanna
D’Orazio, Michele
Casti, Paola
Corsi, Francesca
Ghibelli, Lina
Di Natale, Corrado
Martinelli, Eugenio
author_sort Comes, Maria Colomba
collection PubMed
description Cell motility is the brilliant result of cell status and its interaction with close environments. Its detection is now possible, thanks to the synergy of high-resolution camera sensors, time-lapse microscopy devices, and dedicated software tools for video and data analysis. In this scenario, we formulated a novel paradigm in which we considered the individual cells as a sort of sensitive element of a sensor, which exploits the camera as a transducer returning the movement of the cell as an output signal. In this way, cell movement allows us to retrieve information about the chemical composition of the close environment. To optimally exploit this information, in this work, we introduce a new setting, in which a cell trajectory is divided into sub-tracks, each one characterized by a specific motion kind. Hence, we considered all the sub-tracks of the single-cell trajectory as the signals of a virtual array of cell motility-based sensors. The kinematics of each sub-track is quantified and used for a classification task. To investigate the potential of the proposed approach, we have compared the achieved performances with those obtained by using a single-trajectory paradigm with the scope to evaluate the chemotherapy treatment effects on prostate cancer cells. Novel pattern recognition algorithms have been applied to the descriptors extracted at a sub-track level by implementing features, as well as samples selection (a good teacher learning approach) for model construction. The experimental results have put in evidence that the performances are higher when a further cluster majority role has been considered, by emulating a sort of sensor fusion procedure. All of these results highlighted the high strength of the proposed approach, and straightforwardly prefigure its use in lab-on-chip or organ-on-chip applications, where the cell motility analysis can be massively applied using time-lapse microscopy images.
format Online
Article
Text
id pubmed-7085768
institution National Center for Biotechnology Information
language English
publishDate 2020
publisher MDPI
record_format MEDLINE/PubMed
spelling pubmed-70857682020-03-25 A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells Comes, Maria Colomba Mencattini, Arianna Di Giuseppe, Davide Filippi, Joanna D’Orazio, Michele Casti, Paola Corsi, Francesca Ghibelli, Lina Di Natale, Corrado Martinelli, Eugenio Sensors (Basel) Article Cell motility is the brilliant result of cell status and its interaction with close environments. Its detection is now possible, thanks to the synergy of high-resolution camera sensors, time-lapse microscopy devices, and dedicated software tools for video and data analysis. In this scenario, we formulated a novel paradigm in which we considered the individual cells as a sort of sensitive element of a sensor, which exploits the camera as a transducer returning the movement of the cell as an output signal. In this way, cell movement allows us to retrieve information about the chemical composition of the close environment. To optimally exploit this information, in this work, we introduce a new setting, in which a cell trajectory is divided into sub-tracks, each one characterized by a specific motion kind. Hence, we considered all the sub-tracks of the single-cell trajectory as the signals of a virtual array of cell motility-based sensors. The kinematics of each sub-track is quantified and used for a classification task. To investigate the potential of the proposed approach, we have compared the achieved performances with those obtained by using a single-trajectory paradigm with the scope to evaluate the chemotherapy treatment effects on prostate cancer cells. Novel pattern recognition algorithms have been applied to the descriptors extracted at a sub-track level by implementing features, as well as samples selection (a good teacher learning approach) for model construction. The experimental results have put in evidence that the performances are higher when a further cluster majority role has been considered, by emulating a sort of sensor fusion procedure. All of these results highlighted the high strength of the proposed approach, and straightforwardly prefigure its use in lab-on-chip or organ-on-chip applications, where the cell motility analysis can be massively applied using time-lapse microscopy images. MDPI 2020-03-10 /pmc/articles/PMC7085768/ /pubmed/32164292 http://dx.doi.org/10.3390/s20051531 Text en © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Comes, Maria Colomba
Mencattini, Arianna
Di Giuseppe, Davide
Filippi, Joanna
D’Orazio, Michele
Casti, Paola
Corsi, Francesca
Ghibelli, Lina
Di Natale, Corrado
Martinelli, Eugenio
A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells
title A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells
title_full A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells
title_fullStr A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells
title_full_unstemmed A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells
title_short A Camera Sensors-Based System to Study Drug Effects on In Vitro Motility: The Case of PC-3 Prostate Cancer Cells
title_sort camera sensors-based system to study drug effects on in vitro motility: the case of pc-3 prostate cancer cells
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7085768/
https://www.ncbi.nlm.nih.gov/pubmed/32164292
http://dx.doi.org/10.3390/s20051531
work_keys_str_mv AT comesmariacolomba acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT mencattiniarianna acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT digiuseppedavide acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT filippijoanna acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT doraziomichele acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT castipaola acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT corsifrancesca acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT ghibellilina acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT dinatalecorrado acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT martinellieugenio acamerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT comesmariacolomba camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT mencattiniarianna camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT digiuseppedavide camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT filippijoanna camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT doraziomichele camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT castipaola camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT corsifrancesca camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT ghibellilina camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT dinatalecorrado camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells
AT martinellieugenio camerasensorsbasedsystemtostudydrugeffectsoninvitromotilitythecaseofpc3prostatecancercells

Ejemplares similares