The effects of various combinations of different Cdasses of anticancer drugs and tyrosine kinase inhibitors on the human MCF-7 and triple-negative MDA-MB 231 breast carcinoma cell lines

Abrahams, Beynon

January 2020

Philosophiae Doctor - PhD / Globally, breast cancer is the most common cancer affecting women and it is predicted that in 2030 about 12 million deaths will occur with approximately 21.7 million new cases [2]. Genetic risk factors as well as race and ethnicity, account for about 5-10% of all breast cancer occurrences. Triple negative breast cancer (TNBC), tumors that tested negative for oestrogen receptor (ER), progesterone receptor (PR) and human epidermal growth factor receptor 2 (HER2), contribute to 10-20% of all breast carcinomas [3,4] and is known to be a more aggressive type of cancer with varying degree of response to chemotherapeutic and radiation therapy [5,6] / 2022-02-24

Breast cancer

MCF-7 breast carcinoma cells

MDA-MB-231 TNBC cells

Tyrosine kinase inhibitor

EGFR inhibitor

Combinational Effects of Polymethoxyflavones and Atorvastatin in Inhibiting Human Breast Cancer Cells

Li, Longfang

01 January 2013

Utilization of potential synergistic interactions among different bioactive agents is a promising approach to inhibit complex diseases such as cancer. Nobiletin (NBT) and tangeretin (TAN) are major polymethoxyflavones (PMFs) found in citrus fruits. Herein, we studied NBT and TAN in combination with atorvastatin (ATST, Lipitor, a cholesterol-lowering drug) in MDAMB231 and MCF-7 human breast cancer cells. Both NBT/ATST and TAN/ATST combinations at low doses produced much stronger inhibitory effect on cancer cell viability in comparison to those produced by NBT, TAN, or ATST alone at much higher doses. Isobologram analysis confirmed that both NBT/ATST and TAN/ATST combinations produced strong synergy in inhibiting the growth of two breast cancer cell lines. Flow cytometry analysis showed that both NBT/ATST and TAN/ATST combinations caused significant cell cycle arrest at G0/G1 phase in MDAMB231 cells (ER+). Consistent with these results, PMFs and ATST combinations decreased expression levels of phospho Rb, cyclin D1, and CDK4. Further experiments showed that the combination treatment induced autophagy and late apoptosis in MDA-MB-231 cells. Meanwhile, co-treatment of PMFs and ATST induce G2/M phase in MCF-7 (ER+) cells.. The combination of PMFs and ATST also caused autophagy in MCF-7 cells, which was evidenced by activation of LC3B and P62. In conclusion, our result demonstrated strong synergy between two major citrus PMFs (NBT and TAN) and ATST in inhibiting human breast cancer cell growth.

MDA-MB-231 (ER-)

Food Science

Nanoparticle-Based Drug Delivery and the Impacts on Cancer Cell Biophysical Markers

Babahosseini, Hesam

19 November 2015

Cancer progression and physiological changes within the cells are accompanied by alterations in the biophysical properties. Therefore, the cell biophysical properties can serve as promising markers for cancer detection and physiological activities. To aid in the investigation of the biophysical markers of cells, a microfluidic chip has been developed which consists of a constriction channel and embedded microelectrodes. Single-cell impedance magnitudes at four frequencies and entry and travel times are measured simultaneously during their transit through the constriction channel. This microchip provides a high-throughput, label-free, automated assay to define biophysical signatures of malignant cells and monitor the therapeutic efficacy of drugs. Here, we monitored the dynamic cellular biophysical markers in response to sphingosine kinase inhibitors (SphKIs), and compared the effectiveness of drug delivery using Poly(lactic-co-glycolic acid) (PLGA) nanoparticles (NPs) loaded with SphKIs versus conventional delivery. Cells treated with SphKIs showed significantly higher impedance magnitudes at all four frequencies. The bioelectrical parameters extracted using a model also revealed that the highly aggressive breast cells treated with SphKIs shifted electrically towards that of a less malignant phenotype; SphKI-treated cells exhibited an increase in cell-channel interface resistance and a significant decrease in specific membrane capacitance. Furthermore, SphKI-treated cells became slightly more deformable as measured by a decrease in their channel entry and travel times. We observed no significant difference in the bioelectrical changes produced by SphKI delivered conventionally or with NPs. However, NPs-packaged delivery of SphKI decreased the cell deformability. In summary, the results showed that while the bioelectrical properties of the cells were dominantly affected by SphKIs, the biomechanical properties were mainly changed by the NPs. / Master of Science

MicroElectroMechanical Systems (MEMS)

Microfluidics

Biosensor

Nanoparticles

Drug Delivery

Biomechanics

Bioelectronics

Breast Cancer

MDA-MB-231

Sphingosine Kinase Inhibitors

Caracterização química e atividades biológicas dos óleos essenciais de Protium heptaphyllum, Hedyosmum brasiliense, Blepharocalyx salicifolius, Baccharis dracunculifolia e Nectandra megapotamica

Furtado, Fabiana Barcelos

January 2018

Orientador: Ary Fernandes Junior / Resumo: Espécies vegetais são fontes de moléculas biologicamente ativas que têm um importante papel no desenvolvimento de novos fármacos e, portanto, suas propriedades merecem ser investigadas. Apesar de serem espécies aromáticas e apresentarem um potencial farmacológico, algumas atividades biológicas dos óleos essenciais das folhas de Protium heptaphyllum, Hedyosmum brasiliense, Blepharocalyx salicifolius, Baccharis dracunculifolia e Nectandra megapotamica ainda não foram avaliadas. O objetivo deste trabalho foi verificar a ação citotóxica, antileishmania e antimicrobiana destes óleos essenciais com o intuito de estabelecer espécies vegetais com potencial uso na elaboração de fármacos ou como terapias complementares aos tratamentos convencionais de doenças de impacto em saúde pública. Os óleos essenciais foram obtidos por destilação de folhas frescas por arraste de vapor, a composição química determinada por análises de cromatografia gasosa/espectrometria de massas, as atividades biológicas testadas utilizando o método de microdiluição e a verificação dos mecanismos de morte celular feita por citometria de fluxo. B. salicifolius e B. dracunculifolia apresentaram elevado rendimento (0,86% e 0,89% respectivamente) quando comparado aos demais óleos essenciais avaliados. H. brasiliense e B. salicifolius apresentaram resultados promissores sobre linhagens tumorais Ehrlich (51,59 e 42,04 μg mL-1) e MDA-MB-231 (62,40 e 46,60 μg mL-1), com maior ação seletiva para estes tipos celulares se c... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: lant species are sources of biologically active molecules that play an important role in the development of new drugs, and therefore, their properties deserve to be investigated. In this regard, Protium heptaphyllum, Hedyosmum brasiliense, Blepharocalyx salicifolius, Baccharis dracunculifolia and Nectandra megapotamica are aromatic species with pharmacological potential, producing essential oils whose biological activities had not yet been investigated. The aim of this work was to assess any cytotoxic, antileishmania, or antimicrobial action of these essential oils to determine those plant species with potential in the elaboration of drugs or in complementary treatments of diseases with an impact on public health. Essential oils were obtained from fresh leaves by steam distillation. Chemical composition was determined by gas chromatography/mass spectrometry. Biological activities were assessed using the microdilution method while cell death was checked by flow cytometry. B. salicifolius and B. dracunculifolia presented high yields (0.86% and 0.89%, respectively) relative to the other species assessed. H. brasiliense and B. salicifolius showed promising action on Ehrlich (at 51.59 and 42.04 μg mL-1 concentration respectively) and MDA-MB-231 tumor lines (at 62.40 and 46.60 μg mL-1 concentration respectively), with less selective action against normal MCF-10A breast cells (at > 512 and 314.44 μg mL-1 concentration respectively). Flow cytometry results showed that B. salicifolius... (Complete abstract click electronic access below) / Doutor

Paracoccidioides brasiliensis.

MDA-MB-231

Ehrlich

MCF-10A

Essências e óleos essenciais.

Tumor de mama

Citometria de fluxo.

Essencial oils

Breast tumor

Flow cytometry

Microarray Applications For Determination Of The Effects Of Emodin On Breast Cancer Cell Lines

Qomi Ekenel, Emilia

01 March 2011

ABSTRACT MICROARRAY APPLICATIONS FOR DETERMINATION OF THE EFFECTS OF EMODIN ON BREAST CANCER CELL LINES Ekenel Qomi, Emilia M.S., Department of Biotechnology Supervisor: Prof. Dr. Mesude Iscan Co-Supervisor: Assoc. Prof. Dr. Nursen &Ccedil / oruh February 2012, 191 pages Cancer is a genetic disease that is characterized by uncontrolled cells growth. Breast cancer is a type of cancer originating from breast tissue. Some breast cancers are sensitive to hormones such as estrogen which makes it possible to treat them by blocking the effects of these hormones in the target tissues. These require less aggressive treatment than hormone negative cancers. Breast cancers without hormone receptors, are higher-risk, and are treated more aggressively. The aim of our study is to investigate the effect of emodin on MCF-7 which is ER (estrogen receptor) positive, and MDA-MB-231 (ER negative) cancerous cell lines. Emodin which is a phytoestrogen component, extracted from rheum (genus) plant, has been reported to suppress the growth of tumor in some clinical situation, and it&rsquo / s found that emodin induced apoptosis through the decrease of Bcl-2/Bax ratio and the increase of cytoplasm cytochrome c concentration in human breast cancer Bcap-37 cells. Comparing the effect of emodin between ER positive and ER negative cells at the molecular level was investigated by Microarray analysis of gene expressions using Affymetrix Human Genome U133 plus 2.0 Array. The microarray data analysis was performed by using BRB-Array Tools, v.4.2.0. GST and its classes / Alpha, Mu, Pi, Theta, Sigma, Omega, Zeta and Kappa is our interested genes because of its role in regulating susceptibility to cancer, by their ability to metabolize reactive electrophilic intermediates to usually less reactive and more water soluble glutathione conjugates. And also its have a role in detoxifying the damage caused by oxidative stress which is a result of the radiotherapy. v The differentially expressed genes from emodin treated and untreated control breast cancer cell lines were compared after normalization and filtering and annotated, it was shown that the top 10 highly (significantly) varied genes belong to the biological processes such as (namely) cell cycle, cell division, cell proliferation, mitosis and meiosis, this insure the relation of emodin to the cell growth processes in the cancerous cells. The analysis of the change on the cell growth confirmed the anti-tumor effect of emodin. About the effect of emodin treatment on MCF-7 and MDA-MB-231 cancerous cell lines separately / Both cells its significant genes was belong to cell growth biological processes, in MCF-7 cells in-addition other biological processes was shown, for example / stimulus to estradoil response, and the metabolism of xenobiotic by cytochrome p450, so CYP1A1 gene code for a protein which is used in emodin metabolism. The varied gene number was nearly 4400 gene from the scatter plot result in MCF-7 cells while in MDA-MB-231 cells it was nearly 3400 gene, these result insured the effect of emodin as a phytoestrogenic component as MCF-7 cells are ER positive cells, so emodin bind to the ER in MCF-7 cells and affected more gene number than MDA-MB-231. More number of GST enzyme classes changed in MCF-7 cells than MDA-MB-231, and the effect of emodin as anti-cancer showed different change of GST genes between MCF-7 and MDA-MB-231. The results confirmed by network analysis done, to find the most related genes to our top 10 regulated gene list, and these genes were analyzed / most of them where in our gene list, and their regulation after emodin treatment analyzed and the result was supported to emodin as anti-tumor and phytoestrogenic component.

Q General Science 1-385

Photoactivatable Organic and Inorganic Nanoparticles in Cancer Therapeutics and Biosensing

Mathew, Mona

01 January 2014

In photodynamic therapy a photosensitizer drug is administered and is irradiated with light. Upon absorption of light the photosensitizer goes into its triplet state and transfers energy or an electron to oxygen to form reactive oxygen species (ROS). These ROS react with biomolecules in cells leading to cell damage and cell death. PDT has interested many researchers because of its non-invasiveness as compared to surgery, it leaves little to no scars, it is time and cost effective, it has potential for targeted treatment, and can be repeated as needed. Different photosensitizers such as porphyrines, chlorophylls, and dyes have been used in PDT to treat various cancers, skin diseases, aging and sun-damaged skin. These second generation sensitizers have yielded reduced skin sensitivity and improved extinction coefficients (up to ~ 105 L mol-1 cm-1). While PDT based on small molecule photosensitizers has shown great promise, several problems remain unsolved. The main issues with current sensitizers are (i) hydrophobicity leading to aggregation in aqueous media resulting in reduced efficacy and potential toxicity, (ii) dark toxicity of photosensitizers, (iii) non-selectivity towards malignant tissue resulting in prolonged cutaneous photosensitivity and damage to healthy tissue, (iv) limited light absorption efficiency, and (v) a lack of understanding of where the photosensitizer ends up in the tissue. In this dissertation research program, these issues were addressed by the development of conducting polymer nanoparticles as a next generation of photosensitizers. This choice was motivated by the fact that conducting polymers have large extinction coefficients ( > 107 L mol-1 cm-1), are able to undergo intersystem crossing to the triplet state, and have triplet energies that are close to that of oxygen. It was therefore hypothesized that such polymers could be effective at generating ROS due to the large excitation rate that can be generated. Conducting polymer nanoparticles (CPNPs) composed of the conducting polymer poly[2-methoxy-5-(2-ethylhexyl-oxy)-p-phenylenevinylene] (MEH-PPV) were fabricated and studied in-vitro for their potential in PDT application. Although not fully selective, the nanoparticles exhibited a strong bias to the cancer cells. The formation of ROS was proven in-vitro by staining of the cells with CellROX Green Reagent, after which PDT results were quantified by MTT assays. Cell mortality was observed to scale with nanoparticle dosage and light dosage. Based on these promising results the MEH-PPV nanoparticles were developed further to allow for surface functionalization, with the aim of targeting these NPs to cancer cell lines. For this work targeting of cancers that overexpress folate receptors (FR) were considered. The functionalized nanoparticles (FNPs) were studied in OVCAR3 (ovarian cancer cell line) as FR+, MIA PaCa2 (pancreatic cell line) as FR-, and A549 (lung cancer cell line) having marginal FR expression. Complete selectivity of the FNPs towards the FR+ cell line was found. Quantification of PDT results by MTS assays and flow cytometry show that PDT treatment was fully selective to the FR+ cell line (OVCAR3). No cell mortality was observed for the other cell lines studied here within experimental error. Finally, the issue of confirming and quantifying small molecule drug delivery to diseased tissue was tackled by developing quantum dot (Qdot) biosensors with the aim of achieving fluorescence reporting of intracellular small molecule/drug delivery. For fluorescence reporting prior expertise in control of the fluorescence state of Qdots was employed, where redox active ligands can place the Qdot in a quenched OFF state. Ligand attachment was accomplished by disulfide linker chemistry. This chemistry is reversible in the presence of sulfur reducing biomolecules, resulting in Qdots in a brightly fluorescent ON state. Glutathione (GSH) is such a biomolecule that is present in the intracellular environment. Experimental in-vitro data shows that this design was successfully implemented.

Chemistry

Biomaterials Modeling Of Localized Hyperthermia And Drug Delivery For Breast Cancer

Mulamba, Peter

January 2008

No description available.

Agricultural Engineering

Biomedical Research

Biostatistics

Engineering

Oncology

Quotient response Z-model

biomaterials modeling

MDA-MB-231 cell line

drug delivery

localized hyperthermia

Paclitaxel nanoparticles (Taxol)

breast cancer

Identification of Cell Biomechanical Signatures Using Three Dimensional Isotropic Microstructures

Nikkhah, Mehdi

28 December 2010

Micro and nanofabrication technologies have been used extensively in many biomedical and biological applications. Integration of MEMS technology and biology (BioMEMS) enables precise control of the cellular microenvironments and offers high throughput systems. The focus of this research was to develop three dimensional (3-D) isotropic microstructures for comprehensive analysis on cell-substrate interactions. The aim was to investigate whether the normal and cancerous cells differentially respond to their underlying substrate and whether the differential response of the cells leads to a novel label-free technique to distinguish between normal and cancerous cells. Three different generations of 3-D isotropic microstructures comprised of curved surfaces were developed using a single-mask, single-etch step process. Our experimental model included HS68 normal human fibroblasts, MCF10A normal human breast epithelial cells and MDA-MB-231 metastatic human breast cancer cells. Primary findings on the first generation of silicon substrates demonstrated a distinct adhesion and growth behavior in HS68 and MDA-MB-231 cells. MDA-MB-231 cells deformed while the fibroblasts stretched and elongated their cytoskeleton on the curved surfaces. Unlike fibroblasts, MDA-MB-231 cells mainly trapped and localized inside the deep microchambers. Detailed investigations on cytoskeletal organization, adhesion pattern and morphology of the cells on the second generation of the silicon substrates demonstrated that cytoskeletal prestress and microtubules organization in HS68 cells, cell-cell junction and cell-substrate adhesion strength in MCF10A cells, and deformability of MDA-MB-231 cells (obtained by using AFM technique) affect their behavior inside the etched cavities. Treatment of MDA-MB-231 cells with experimental breast cancer drug, SAHA, on the second generation of substrates, significantly altered the cells morphology, cytoarchitecture and adhesion pattern inside the 3-D microstructures. Third generation of silicon substrates was developed for comprehensive analysis on behavior of MDA-MB-231 and MCF10A cells in a co-culture system in response to SAHA drug. Formation of colonies of both cell types was evident inside the cavities within a few hours after seeding the cells on the chips. SAHA selectively altered the morphology and cytoarchitecture in MDA-MB-231 cells. Most importantly, the majority of MDA-MB-231 cells stretched inside the etched cavities, while the adhesion pattern of MCF10A cells remained unaltered. In the last part of this dissertation, using AFM analysis, we showed that the growth medium composition has a pronounced effect on cell elasticity. Our findings demonstrated that the proposed isotropic silicon microstructures have potential applications in development of biosensor platforms for cell segregation as well as conducting fundamental biological studies. / Ph. D.

HS68

MCF10A

Silicon

Atomic Force Microscopy (AFM)

MDA-MB-231

Breast Cancer

Suberoylanilide Hydroxamic Acid (SAHA)

Isotropic

Three Dimensional (3-D)

MicroElectroMechanical Systems (MEMS)

Optimisation de nanoparticules multifonctionnelles pour une amélioration de l'efficacité photodynamique, de la sélectivité tumorale et de la détection par IRM / Optimization of multifunctional nanoparticles for improvements of photodynamic efficiency, tumor selectivity and MRI detection

Seve, Aymeric

03 December 2013

La thérapie photodynamique (PDT pour Photodynamic Therapy) met en jeu des molécules nommées photosensibilisateurs (PS), de l'oxygène et de la lumière. Les PS, non cytotoxiques à l'obscurité, produisent des espèces réactives de l'oxygène (ROS) lorsqu'ils sont excités avec une longueur d'onde appropriée en présence d'oxygène. Les ROS regroupent les radicaux de l'oxygène et l'oxygène singulet (1O2), qui est la principale forme de ROS formés lors du processus de PDT. En présence de tissus vivants, l'1O2 va conduire à la mort cellulaire par apoptose ou par nécrose. Pour améliorer l'efficacité photodynamique, une des pistes étudiées par la communauté scientifique consiste à améliorer la sélectivité du traitement. Le traitement des tumeurs primaires malignes du cerveau, dont le glioblastome multiforme (GBM ou astrocytome de grade IV) est la forme la plus agressive, reste un challenge. Lorsqu'elle est possible, la chirurgie occupe une place prépondérante. L'exérèse ne concerne que la partie volumineuse centrale de la tumeur, tandis que la zone périphérique infiltrante est, quant à elle ciblée par des traitements supplémentaires. Malgré les progrès de la neurochirurgie et de la radiothérapie, l'espérance de vie à 5 ans ne dépasse pas 10%. La thérapie photodynamique se présente comme une alternative thérapeutique grâce aux améliorations apportées par le contrôle local. Pour traiter le gliobastome par PDT, une première approche a consisté à coupler un peptide, à un photosensibilisateur (la chlorine) via un bras espaceur Ahx (acide aminohexanoïque). Le peptide utilisé (ATWLPPR) est un ligand spécifique du récepteur neuropiline 1 (NRP-1). NRP-1 est lui-même un co-récepteur au récepteur du facteur vasculaire de croissance endothéliale (VEGFR) qui est surexprimé au niveau des néovaisseaux et qui favorise la néoangiogenèse au cours du développement des tumeurs solides. L'assemblage PS-Ahx-ATWLPPR a montré une stabilité peptidique in vivo et in vitro avec une bonne pharmacocinétique et une bonne biodistribution. Ses efficacités anti-tumorales et anti-vasculaires ont notamment été prouvées. Cependant, in vivo, le peptide ATWLPPR montrait une dégradation par le système réticulo-endothélial et l'assemblage présentait une affinité moindre pour NRP-1 par rapport au peptide seul. Afin de résoudre ces problèmes, une nouvelle stratégie décrite dans cette thèse a consisté à développer des nanoparticules multifonctionnelles. Ces nanoparticules sont constituées d'un coeur d'oxyde de gadolinium (Gd2O3) pour permettant un réhaussement de contraste positif en IRM, enrobé d'une couche de polysiloxane biocompatible dans laquelle est greffé le photosensibilisateur par liaison amide. La nanoparticule est ensuite fonctionnalisée en surface avec des agents chélatants (DOTA, DTPA) par l'intermédiaire de fonctions amines libres de la couche de polysiloxane. Les peptides de type ATWLPPR sont greffés sur les agents chélatants, ce qui permet un ciblage spécifique de NRP-1. De cette façon, on obtient des nanoparticules qui offrent à la fois une possibilité de ciblage actif des néovaisseaux tumoraux, de visualisation par IRM et un effet PDT. Dans l'objectif d'obtenir un effet PDT optimal, une augmentation du contraste en imagerie IRM et une sélectivité maximale pour les cellules endothéliales, un plan d'expérience a été élaboré. Chaque lot du plan d'expérience a été synthétisé en faisant varier la composition chimique du coeur, l'épaisseur de la couche de polysiloxane, le nombre de photosensibilisateurs, le type de surfactant, le nombre et le type de peptides. Une fois la synthèse et la purification de ces nanoparticules effectuées, chaque lot a été caractérisé pour vérifier la conservation des propriétés photophysiques, en particulier la formation d'oxygène singulet. Des études biologiques sur des cellules tumorales de type MDA-MB-231 et U87 ont été réalisées, pour étudier la cytototoxicité, la phototoxicité et le réhaussement de contraste IRM de ces nanoparticules / Photodynamic therapy (PDT) involves molecules called photosensitizers (PS), molecular oxygen and light. PS are non-cytotoxic in the dark but produce reactive oxygen species (ROS) when they are excited with light of an appropriate wavelength in the presence of oxygen. ROS include oxygen radicals and singlet oxygen (1O2), which is the main form of ROS formed during PDT processes. In the presence of living tissue, 1O2 leads to cell death by apoptosis or necrosis. To improve photodynamic efficiency, a strategy developed by scientists consists in improving the selectivity of the treatment. The treatment of primary malignant brain tumors, including glioblastoma multiforme (GBM or astrocytoma level IV) which is the most aggressive form, remains a challenge. When it is possible, surgery is performed by removing the central volume of the tumor, while infiltrating peripheral zone is treated by additional treatments. Despite advances in neurosurgery and radiotherapy, the life expectancy at 5 years after the tumor detection does not exceed 10 %. PDT appears as an alternative treatment. In preliminary study a photosensitizer (chlorin) coupled to a peptide (ATWLPPR) through an Ahx linker (aminohexanoic acid) has been designed. The peptide is a specific ligand of neuropilin-1 receptor (NRP-1). NRP-1 is a co-receptor of vascular endothelial growth factor receptor (VEGFR) overexpressed in neovessels and which promotes the formation of new vessels during the development of solid tumors. This targeted photosensitizer presented a peptidic stability in vivo and in vitro with good pharmacokinetic and biodistribution. Its anti-tumor and anti-vascular efficiencies have been proven. However, the ATWLPPR peptide showed degradation in the reticuloendothelial system (RES) and a reduced affinity for NRP-1 compared with peptide alone. To solve these problems, a new strategy using multifunctional nanoparticles has been developed in this thesis. The nanoparticles consist of a core of gadolinium oxide (Gd2O3) for MRI contrast, coated with a layer of biocompatible polysiloxane wherein the photosensitizer is covalenty grafted. The nanoparticle surface is functionalized by chelating agents (DOTA, DTPA) via free amine functions of the polysiloxane layer. ATWLPPR peptides are grafted on chelating agents, which allows specific targeting of NRP-1. Nanoparticles allow a MRI visualization, a PDT effect and an active targeting of the tumor neovasculature. With the aim to obtain an optimal PDT effect, an enhancement of contrast in MRI imaging and a high selectivity for endothelial cells, an experimental design has been developed. Each batch of the experimental design was synthesized with various chemical compositions of the core, the size of the polysiloxane layer, the number of photosensitizers, the number and the type of peptides and the type of surfactant. Once the synthesis and purification of these nanoparticles done, each batch was characterized to ensure the conservation of the photophysical properties, in particular the formation of the singlet oxygen. Biological studies on tumor cell type MDA- MB-231 and U87 were carried out, especially their cytototoxicity and phototoxicity

ATWLPR

DOTA

DTPA

Gd2O3

Glioblastome

IRM

MDA-MB-231

Nanoparticules multifonctionnelles

Néovaisseaux

Neuropiline 1

NRP-1

PDT

Oxygène singulet

Photosensibilisateurs

Polysiloxane

U87

ATWLPR

DOTA

DTPA

Gd2O3

Glioblastoma

IRM

MDA-MB-231

Multifunctional nanoparticles

Neovessels

Neuropilin 1

NRP-1

PDT

Photosensitizer

Polysiloxan

Singlet oxygen

U87

616.994 0631

Red palm oil as a therapeutic agent in triple-negative breast cancer patients

Slahudeen, Sameera

January 2020

Magister Scientiae (Medical Bioscience) - MSc(MBS) / Purpose: Breast cancer is one of the most frequent and fatal diseases women all around the globe are challenged with today. In women, breast cancer has the highest mortality rate of all cancers and the incidence rate is on the increase. It is estimated that by the year 2025, 19.3 million women will become a victim of this grave health problem. This disease is a result of the formation of malignant tumours caused by genetic alterations that are involved in the proliferation of cells, cellular differentiation and the disturbance in homeostasis which subsequently leads to the abnormal multiplication and growth of cells. Breast cancer is considered a multifactorial disease with various risk factors such as age, radiation exposure, hormone therapy, oral contraceptives, dietary factors, environmental exposure and genetic predispositions. Breast cancers can be subdivided and classified based on their cellular surface receptors such as Estrogen Receptors, Progesterone Receptors and Human Epidermal Growth Factor Receptor 2. Of the various subtypes, the triple-negative breast cancer subtype which is negative for all 3 surface receptors and presents as the most aggressive form of breast cancer with a poor prognosis. Between 10-20% of all breast cancer cases are classified as triple-negative breast cancer. Due to the hormonal status of triple-negative breast cancer, treatment options are limited and thus of great concern. Chemotherapy remains the most common treatment modality, but prognosis is poor with relapse within years ultimately leading to poor survival outcome. Due to this lack of effective treatment plans, an alternative treatment with minimal side effects and better survival remains an imperative area to explore. A wide scope of literature highlights red palm oil and its health benefits, with its growth inhibitory potential drawing great attention. Red palm oil, extracted from the Elaeis guineensis palm tree is red in colour due to the abundance of carotenoids, tocotrienols and tocopherols found in the oil. Various compounds make up the oil such as lycopene, carotenes, vitamin E and coenzyme Q10. Most studies have researched the effects of vitamin E extracted from the oil as a contributor to its growth inhibitory activity. This study focuses on the effects of the commercial red palm oil as a whole with all its compounds on the proliferation of breast cancer cells as well as the effect it has on various genes associated with breast cancer. Method: This study investigated the effect of red palm oil concentrations (1, 10, 100, 500 and 1000 μg/ml) on breast cancer cells—MCF-7 and MDA-MB-231 with comparison to a non-cancerous cell line—MCF-12A for 24-, 48- and 72-hour treatment periods. The parameter investigated was cell proliferation through the CCK-8 cell proliferation assay and the morphology following red palm oil treatment was observed and captured. Additionally, this study also investigated the effect of red palm oil on the expression of Human Mammaglobin (hMAM) and Maspin genes through the PCR assay and results visualised through agarose gel electrophoresis. Data was statistically analysed using GraphPad version 6.0 software. Results: Following treatment of red palm oil, no apparent changes in the cell morphology was observed despite using variable treatment concentrations over variable times for MCF-7, MDA-MB-231 and MCF-12A cells relative to their respective controls. Immortalised MCF-12A cells showed a significant increase in proliferation with the varying treatment concentrations, but more prominently with the highest concentration at 24, 48 and 72 hours. MCF-7 cells showed significant decreases at 24 and 72 hours. Decreased proliferation was observed at all dosages used, particularly at 10, 100, and 500 μg/ml. Furthermore, MDA-MB-231 cells demonstrated a gradual increase in cell proliferation for the 3 selected time periods in the varying concentrations. Additionally, red palm oil did not alter the gene expression of Maspin at any of the varying treatments for MDA-MB-231 nor MCF-7 cells. However, changes in hMAM gene expression were observed at treatment concentration of 100 μg/ml in MDA-MB-231 cells that were incubated for 24 and 48 hours. However, the hMAM expression was not affected in treated MCF-7 cells. Conclusion: Red palm oil, as an alternative dietary oil, seems to have potential growth inhibitory properties as demonstrated by the change in the cell proliferation of the MCF-7 cells. Literature show that various individual compounds extracted from red palm oil have anti-proliferative and inhibitory effects on breast cancer cells making them good candidates for therapy. However, this study concludes that red palm oil as a whole component would not be a suitable therapeutic agent for highly aggressive triple-negative breast cancer.

Breast cancer

Triple-negative breast cancer

Red palm oil

Cell proliferation

Human MCF-7 cells

MDA-MB-231 (TNBC) cells

Human epithelial MCF-12A cells

PCR

Gene expression

GAPDH housekeeping gene

hMAM gene

Maspin gene