Novel cryoprotective agents to improve the quality of cryopreserved mammalian cells

Al-Otaibi, Noha

January 2018

Cryopreservation is a promising approach to long-term biopreservation of living cells, tissues and organs. The use of cryoprotective agents (CPAs) in combination with extremely low temperatures is mandatory for optimum biopreservation. CPAs (e.g., glycerol, trehalose, dimethyl sulphoxide (DMSO)), however, are relatively cytotoxic and compromise biopreserved cell quality. This is usually resultant in oxidative damage, diminishing cell functionality and survival rate. The growing market of cell therapy medicinal products (CTMPs) demands effective cryopreservation with greater safety, of which the currently available CPAs are unable to provide. The present study was aimed at developing cryomedia formulation to enhance the cryopreservation of nucleated and anucleated mammalian cells. Here, eleven compounds of a polyol nature were selected and examined for their cryoprotective properties. These compounds are derived from plants and honey, thereby ensuring their safety for human consumption. The selection was based on their molecular structure and chemical properties. Here, the presented study is divided into three main phases: 1) Screening the compounds panel for cryo-additive effects on cells during and post-cryopreservation and optimising the dose response and time course for trehalose and glycerol with and without the novel compounds; 2) Assessing the influence of biophysical criteria on biospecimen cryopreservation (e.g., biosampling procedure, cell age, donor age); 3) Establishing the mechanisms of action underpinning the modulatory effect of novel CPAs on biological pathways during cryopreservation. For the stated purposes, red blood cells (RBCs) obtained from sheep and humans were used to screen the compounds for novel cryo-additive agents. Cryosurvival rate was employed as an indication of the compounds' cryoprotective performance. Cellular biochemical profiles, including lipid and protein oxidative damage as well as key redox enzymatic activities (e.g., lactate dehydrogenase (LDH), glutathione reductase (GR)) were measured. The study revealed that nigerose (Nig) and salidroside (Sal) were significantly effective in protecting cells during the freeze-thaw cycle and recovery phases. Both compounds promoted the activity of GR and reduced oxidative stress mirrored by diminished LDH activity. This was also reflected in the protein and lipid oxidation levels, which was limited to a comparable level with the cells' prior freezing. Further studies on human leukaemia (HL-60) were carried out to elucidate the molecular and biological pathways associated with cryodamage and the modulatory effects of adding novel CPAs. The proteome profile and the corresponding biological functions were evaluated and iii showed that Nig and Sal protected cells against cryodamage. The additive compounds (Nig and Sal) demonstrated a unique and overlapping modulation effect pattern. Nig was found to highly influence proteins engaged with metabolic and energetic pathways, whereas Sal greatly affected nuclear and DNA-binding proteins. The current study concluded that novel CPAs have high potency in protecting cells and each compound has a unique effect on the cellular proteome. These features can be applied to designing cryomedia formulae with higher protective efficiency for targeted applications in cell based therapy and biopharmaceutical industries.

Pollution de l'air extérieur et intérieur à Dakar (Sénégal) : caractérisation de la pollution, impact toxicologique et évaluation épidémiologique des effets sanitaires / Outdoor and indoor air pollution in Dakar (Senegal) : characterization of pollution, toxicological impact and epidemiological evaluation of health effects

Ndong, Awa

25 January 2019

La pollution atmosphérique constitue de nos jours un enjeu sociétal majeur, tant pour ses conséquences néfastes sur la santé humaine que sur l'environnement. L'objectif général de ce présent travail était de déterminer le niveau de la pollution atmosphérique dakaroise, extérieure et intérieure, et d'évaluer son impact sanitaire au sein de la population urbaine. Les particules fines (PM₂.₅) et une fraction plus grossière (PM>₂.₅) échantillonnées sur un site urbain de Dakar (HLM), caractérisées par de fortes émissions du trafic routier, ont été comparées aux particules échantillonnées dans une zone rurale, Toubab Dialaw, située à environ 40 kms de Dakar. Les caractéristiques physicochimiques des échantillons ont révélé que les particules différaient par leurs propriétés physiques (surface) et chimiques (en termes de CHN, métaux, ions, paraffines, COV et HAP) de 65 à 75 % plus élevées dans les échantillons urbains. Selon les différentes sources et les différentes propriétés physiques et chimiques, la réponse inflammatoire (TNF-α, IL-1β, IL-6, IL-8) et les dommages oxydatifs (protéines carbonylées totales et 8-OHdG) se sont révélés plus importants dans les cellules bronchiques BEAS-2B exposées aux particules urbaines. La campagne de mesure de la qualité de l'air a montré que l'intérieur du bus était plus pollué en PM₁₀, CO, CO₂ et NO que le marché et les sites intérieurs urbains et ruraux. La comparaison de la qualité de l'air entre les sites intérieurs et extérieurs a révélé que, particulièrement dans les zones urbaines, la qualité de l'air intérieur pouvait être moins bonne que celle des sites extérieurs correspondants. Le suivi de l'exposition individuelle aux polluants a montré que les ménagères de la zone urbaine et rurale étaient plus exposées que les professionnels à la pollution de l'air, confirmant les observations précédentes d'un niveau d'exposition potentiellement plus élevé des polluants dans l'environnement intérieur. Cependant, il convient de tenir compte du niveau d'exposition des commerçants et des conducteurs d'autobus résultant de l'échappement du trafic avec des véhicules souvent anciens, mal entretenus et non contrôlés, en raison des niveaux élevés de polluants gazeux rapportés ici. / Air pollution is nowadays a major societal challenge, as much for its harmful consequences on human health as on the environment. The general objective of this work was to determine the level of Dakar air pollution, outdoor and indoor, and to assess its health impact in the urban population. Fine particles (PM₂.₅) and a coarser fraction (PM>₂.₅) sampled at an urban site in Dakar (HLM), characterized by high road traffic emissions, were compared with particles sampled at a rural area, Toubab Dialaw located about 40 km from Dakar. The physicochemical characteristics of samples revealed that PMs differ for their physical (surface area) and chemical properties (in terms of CHN, metals, ions, paraffins, VOCs and PAHs) that were 65 to 75 % higher in urban samples. In accordance with the different sources and different physical and chemical properties, the inflammatory response (TNF-α, IL-1β, IL-6, IL-8) and the oxidative damage (total carbonylated proteins and 8-OHdG) were found higher in bronchial BEAS-2B cells exposed to urban PMs. The air quality measurement campaign showed that the bus interior was more polluted with PM₁₀, CO, CO₂ and NO than the market and the urban and rural indoor sites. The comparison of air quality between indoor and outdoor sites revealed that, particularly in urban areas, indoor air quality may be worse than the corresponding outdoor one. Monitoring individual exposure to pollutants showed that housewives in urban and rural sites were more exposed than professionals to air pollution, confirming previous observations of potential higher individual exposure level to pollutants in indoor environment. However, exposure level of traders and bus drivers that would result from the exhaust of traffic with often old, poorly maintained and uncontrolled vehicles has to be taken into consideration due the higher levels of gaseous pollutants here reported.

Biomarqueurs

Caractérisation physico-chimique

Cellules BEAS-2B

Dommages oxydatifs

Exposition professionnelle

Pollution de l'air

PMs

Réaction inflammatoire

Physicochemical characterization

BEAS-2B cells

Oxidative damages

Air pollution

Inflammatory response

PM₂.₅

PM>₂.₅