key: cord-0017469-0o5c3weo
authors: Wang, Yung-Li; Zheng, Cai-Mei; Lee, Yu-Hsuan; Cheng, Ya-Yun; Lin, Yuh-Feng; Chiu, Hui-Wen
title: Micro- and Nanosized Substances Cause Different Autophagy-Related Responses
date: 2021-04-30
journal: Int J Mol Sci
DOI: 10.3390/ijms22094787
sha: dd3b0ff26830b1d7c95554b21cb0a48f48d3cd44
doc_id: 17469
cord_uid: 0o5c3weo

With rapid industrialization, humans produce an increasing number of products. The composition of these products is usually decomposed. However, some substances are not easily broken down and gradually become environmental pollutants. In addition, these substances may cause bioaccumulation, since the substances can be fragmented into micro- and nanoparticles. These particles or their interactions with other toxic matter circulate in humans via the food chain or air. Whether these micro- and nanoparticles interfere with extracellular vesicles (EVs) due to their similar sizes is unclear. Micro- and nanoparticles (MSs and NSs) induce several cell responses and are engulfed by cells depending on their size, for example, particulate matter with a diameter ≤2.5 μm (PM2.5). Autophagy is a mechanism by which pathogens are destroyed in cells. Some artificial materials are not easily decomposed in organisms. How do these cells or tissues respond? In addition, autophagy operates through two pathways (increasing cell death or cell survival) in tumorigenesis. Many MSs and NSs have been found that induce autophagy in various cells and tissues. As a result, this review focuses on how these particles interfere with cells and tissues. Here, we review MSs, NSs, and PM2.5, which result in different autophagy-related responses in various tissues or cells.

Micro-and nanomaterials with different physical and chemical properties have been developed for human needs [1, 2] . However, micro-and nanomaterials also show unexpected toxicity [3] . Nanotoxicology is rapidly developing with potential hazardous effects for nanomaterials [4, 5] . Due to their larger sizes and small surface-to-volume ratios, micromaterials are considered less toxic than nanomaterials. In addition, nanomaterials can aggregate to a microscale size [6, 7] . Micromaterials are also harmful to humans [3, 8] . These materials may return to humans via the food chain [9, 10] . Human consumption of microor nanoplastics may occur through seafood [11, 12] , water [13, 14] , etc. However, PM2.5 (particulate matter ≤ 2.5 µm) is a mix of micro-and nanosized substances (MSs and NSs) that can cause many chronic diseases [15, 16] . Many studies show that MSs and NSs are toxic [17] . These related materials have a potential risk to human health. MSs and NSs employ one or multiple endocytosis pathways to enter cells. The main endocytosis pathways of MSs or NSs include clathrin-mediated endocytosis, caveolae/lipid raft-mediated endocytosis, clathrin-and caveolin-independent endocytosis, macropinocytosis and phagocytosis. The possible mechanisms by which MSs and NSs modulate several cell responses, such as ER-stress, mitochondrial damage, lysosome dysfunction, ROS production, and autophagy, are summarized. MSs: Micro-sized substances; NSs: Nanosized substances.Extracellular vesicles (EVs) are defined as lipid-bound particles of various sizes secreted from cells to extracellular spaces or circulated to target tissues [69, 70] . EVs can be briefly classify into three types based on their size and biogenesis [71, 72] . Small EVs are 50-100 nm in size and, include exosomes and endosome-derived membrane vesicles that are formed from multivesicular bodies (MVBs), intraluminal vesicles (ILVs) and the cellular plasma membrane [73, 74] . Microvesicles (MVs), microparticles (MPs) and ectosomes are considered large EVs that are shed directly from the cell surface [73, 75] ; apoptotic bodies are formed during apoptosis genesis, and their diameters range between 1000 and 5000 nm [76, 77] . Previous studies have shown that EVs have important biological relevance, such as immunity and inflammation [78, 79] , hemostasis [80, 81] , reproduction [82] , and tumorigenesis [83] . Recently, conditioned medium from stem cells is as a new therapeutic application [84, 85] . Conditioned medium applicates in diabetic wound healing [86, 87] , preventing activation of keloid fibroblasts in human [88] , musculoskeletal tissue regeneration [89] , hair regeneration in human [90] , retinal ischemia-reperfusion in rat [91] , differentiation of rat retinal progenitor cells, [92] promoting survival and neurite outgrowth of neural stem cells in canine [93] , autoimmune encephalomyelitis in mice [94] , spinal cord injury in canine [95] , lung injury and disease [96] , EVs can isolated form conditioned medium [97] . Therefore, EVs have sizes similar to those of MSs and NSs or particulate matter less than 2.5 μm (PM 2.5). Whether these micro-and nanoparticles interfere with the function of EVs is still unclear. MSs and NSs employ one or multiple endocytosis pathways to enter cells. The main endocytosis pathways of MSs or NSs include clathrin-mediated endocytosis, caveolae/lipid raft-mediated endocytosis, clathrin-and caveolin-independent endocytosis, macropinocytosis and phagocytosis. The possible mechanisms by which MSs and NSs modulate several cell responses, such as ER-stress, mitochondrial damage, lysosome dysfunction, ROS production, and autophagy, are summarized. MSs: Micro-sized substances; NSs: Nanosized substances. Schematic picture of the macroautophagy process. MNs and NSs, including protein aggregates, damaged organs, plastics particles, dust, and silica are shown. LC3-II, Beclin 1, and p62 conjugate enzymes generate the phagophore form and then the surrounding MNs and NSs during the elongation stage. At the end of the elongation stage, the membrane is sealed to form a doublemembrane vesicle, called the autophagosome, which contains degraded cellular enzymes. The autophagosome fuses with a lysosome, forming an autolysosome in which lysosomal enzymes degrade the cargo and release the degraded products into the cytoplasm. Undecomposed MSs and NSs, such as dust and silica, have carcinogenic potential.

Microparticles and nanoparticles are particulate particles with a size ranging from 1- Figure 2 . Schematic picture of the macroautophagy process. MNs and NSs, including protein aggregates, damaged organs, plastics particles, dust, and silica are shown. LC3-II, Beclin 1, and p62 conjugate enzymes generate the phagophore form and then the surrounding MNs and NSs during the elongation stage. At the end of the elongation stage, the membrane is sealed to form a double-membrane vesicle, called the autophagosome, which contains degraded cellular enzymes. The autophagosome fuses with a lysosome, forming an autolysosome in which lysosomal enzymes degrade the cargo and release the degraded products into the cytoplasm. Undecomposed MSs and NSs, such as dust and silica, have carcinogenic potential.

Extracellular vesicles (EVs) are defined as lipid-bound particles of various sizes secreted from cells to extracellular spaces or circulated to target tissues [69, 70] . EVs can be briefly classify into three types based on their size and biogenesis [71, 72] . Small EVs are 50-100 nm in size and, include exosomes and endosome-derived membrane vesicles that are formed from multivesicular bodies (MVBs), intraluminal vesicles (ILVs) and the cellular plasma membrane [73, 74] . Microvesicles (MVs), microparticles (MPs) and ectosomes are considered large EVs that are shed directly from the cell surface [73, 75] ; apoptotic bodies are formed during apoptosis genesis, and their diameters range between 1000 and 5000 nm [76, 77] . Previous studies have shown that EVs have important biological relevance, such as immunity and inflammation [78, 79] , hemostasis [80, 81] , reproduction [82] , and tumorigenesis [83] . Recently, conditioned medium from stem cells is as a new therapeutic application [84, 85] . Conditioned medium applicates in diabetic wound healing [86, 87] , preventing activation of keloid fibroblasts in human [88] , musculoskeletal tissue regeneration [89] , hair regeneration in human [90] , retinal ischemia-reperfusion in rat [91] , differentiation of rat retinal progenitor cells [92] , promoting survival and neurite outgrowth of neural stem cells in canine [93] , autoimmune encephalomyelitis in mice [94] , spinal cord injury in canine [95] , lung injury and disease [96] , EVs can isolated form conditioned medium [97] . Therefore, EVs have sizes similar to those of MSs and NSs or particulate matter less than 2.5 µm (PM2.5). Whether these micro-and nanoparticles interfere with the function of EVs is still unclear.

Microparticles and nanoparticles are particulate particles with a size ranging from 1-1000 µm or 1-1000 nm, respectively [98] . The sources of MSs and NSs can be classified into three main categories based on their origin. There are three main categories (A), (B), and (C).

(A) Unexpected MSs and NSs are produced through industrial processes, such as particles produced from urban dust, non-exhaust vehicle emissions, vehicle engine exhaust, road dust, welding fumes, combustion processes and even some natural processes, such as forest fires or volcano bursts [99] . Automobile exhaust or diesel engines release approximately 20-130 nm sized particles. Therefore, gasoline engines release approximately 20-60 nm sized particles [100, 101] . In addition, plastics originate from synthetic polymers produced by the polymerization of monomers [102] . Plastic is divided into polyamides (PA), polycarbonate (PC), polyethylene (PE), polyester (PES), polyethylene terephthalate (PET), polyetherimide (PEI), polystyrene (PS), polypropylene (PP), polyvinyl chloride (PVC), polyvinylidene chloride (PVDC), low-density polyethylene (LDPE), high-density polyethylene (HDPE), high impact polystyrene (HIPS), acrylonitrile butadiene styrene (ABS), polycarbonate/acrylonitrile butadiene styrene (PC/ABS), polyurethanes (PU), polymethyl methacrylate (PMMA), polytetrafluoroethylene (PTFE) melamine formaldehyde (MF), and urea-formaldehyde (UF) [103] . These plastics can be fragmented into smaller pieces by ultraviolet light and biodegraded [104] . Furthermore, the mixed synthetic fibers textiles we wear daily also generate MSs or NSs from laundering [105] [106] [107] [108] . Briefly, synthetic fibers contain glass and ceramic fibers, aramid fibers, viscose rayon fibers, carbon fibers, polyolefin fibers, nylon fibers [108] . Synthetic [11, 137, 138] , milk [132, 139] , beer [140, 141] , sea salt [141, 142] , sugar [143] , honey [143] , plastic teabags [144] , raw water [145] , tap water [141] , and bottled water [146, 147] . In particular, some MSs and NSs engulfing cells are not easily decomposed.

The mechanisms of autophagy in particle-induced toxicity are complex, given the different physicochemical and biochemical properties of particles and the various interactions between particles and cells. Therefore, the dispersity, size, charge and coating play important roles in toxicity [148] . Recently, many inorganic nanomaterials have been frequently used to observe inorganic nanomaterial-mediated autophagy in a variety of cell lines, such as mouse dendritic cells, U251 cells, L02 cells, LLC-PK1 cells, PC12 cells, human umbilical vein endothelial cells (HUVECs), hippocampal neurons, NCI-H460 cells, HeLa cells, RAW264.7 cells and human cerebral endothelial cells [121] . Engineered nanomaterials cause chronic inflammation in the lungs of rodents [149] and induce and/or aggravate type I allergic hypersensitivity reactions including asthma, atopic dermatitis, allergic rhinitis, food allergies [150] , and immune responses [151] . In addition, magnetic nanoparticles and iron oxide nanoparticles induce inflammation [152, 153] , autophagy markers, such as Atg5, Atg12 and LC3 [154] , carcinogenic potential [17] , and human neurodegenerative diseases [155] , after long-term iron oxide nanoparticle exposure [156, 157] . Manganese nanoparticles activate autophagy markers, such as Beclin 1 and LC3, in dopaminergic neuronal cells [158] . Quantum dots have a potential toxicity, such as oxidative damage to DNA and proteins and changes in autophagy markers, such as p62 and LC3 [159] [160] [161] . Quantum dots also induce autophagy markers, such as LC3 in porcine kidney cells [162] . Graphene oxide quantum dots increase autophagy markers, p62 and LC3, in the GC-2 and TM4 cell lines (male reproductive cells in mouse) [163] . Graphene oxide cause autophagy markers, p62 and LC3, in F98 rat glioblastoma cells [164] . Metal nanoparticles and carbon nanotubes (CNTs) not only affect asthma in animal models but also induce allergic airway disease [165] . Metal nanomaterials have the potential to induce dermal and respiratory allergies [166] . PM2.5 induces autophagy markers, such as Beclin 1, ULK-1, and LC3 [167, 168] , and results in developmental toxicity in zebrafish embryos [169] , autophagy-mediated cell death in human bronchial epithelium cells [170] , and cardiac dysfunction [171] . PM2.5 may represent a significant risk factor for the development of Alzheimer's disease [172] . PM2.5 also counteracts hepatic steatosis in mice fed a high-fat diet by stimulating hepatic autophagy markers, such as p62 and LC3 [173] . PM2.5 exposure activates the autophagy markers in the spleen of SD rats, such as ATG5, VSP34, Beclin 1, and LC3 [174] . PM2.5 exposure induces renal injury and changes autophagy markers, such as p62, Beclin 1, and LC3, in rats and HK-2 cells [175] . Diesel exhaust particles (DEP) induce the generation of ROS, pro-inflammation, and apoptosis in the HUVEC tube cells [176] . DEP induce macrophage activation and dysfunction [177] . Exposure to a high-intensity traffic area affects metabolism and hormones [178] . Traffic-related PM induces autophagy markers, such as p62, Beclin 1, and LC3, in HK-2 human kidney tubular epithelial cells and rat kidney tissues [179] . In addition, silica submicrospheres [180] or zinc oxide (ZnO) nanoparticles [181] induce autophagy marker, such as LC3. ZnO nanoparticles cause the formation of ROS and autophagy marker in human ovarian cancer cells (SKOV3) [182] , human epidermal keratinocytes [183] , and immune cells [184] . ZnO nanoparticles result in autophagosome accumulation and autophagic cell death in PC12 cells (pheochromocytoma cells in rat) [185] . ZnO nanoparticles induce the autophagy marker, LC3, and apoptosis marker caspase-3/7 activity and change the glutathione peroxidase, superoxide dismutase, tumor necrosis factor (TNF-α), and interleukin-6 in primary astrocyte cultures [186] . ZnO nanoparticles cause the expression of annexin V, caspase-3/7 activity, and mitochondrial membrane potential, which are mediated by lipoxygenase (LOX) in human dopaminergic neuroblastoma SH-SY5Y cells [187] .

Silica nanoparticles induce cardiac dysfunction in rat hearts and human cardiomyocytes [188] and cardiotoxicity in adult rat cardiomyocytes [189] . Silica nanoparticles disturb ion channels and transmembrane potentials in cardiomyocytes and induce arrhythmias in adult male C57BL/6J mice [190] . The 20 nm silica nanoparticles significantly induce apoptosis and necrosis in human endothelial cells (ECs) [191] . Silica nanomaterials induce calcium mobilization and the formation of ROS in HUVECs and adult female Balb/c mice [192] . Silica nanoparticles also increase autophagy markers, such as LC3, and autophagic cell death in HepG2 cells (human liver cancer cells) [193] . Ultrafine silicon dioxide nanoparticles trigger apoptosis in lung epithelial cells [194] . Silica nanoparticles induce inflammation in the lungs of mice [195] and the autophagy marker, p62 [196] . Amorphous silica nanoparticles cause autophagy markers, such as p62 and LC3, and vascular endothelial cell injury [197] . Silver nanoparticles increase the formation of ROS, oxidative stress [198] and the genotoxicity in human TK6 cells (lymphoblast cells) [199] . Silver nanoparticle-induced autophagy markers, such as LC3, disrupts inflammasome activation in HepG2 cells [200] . Silver nanoparticles increase autophagy markers, such as p62 and LC3, decrease the expression of transcription factors in A549 human lung adenocarcinoma cells [201] , and induce other autophagy markers, such as Beclin 1 and LC3, in the adult rat brain [202] . Amine-modified silver nanoparticles trigger autophagy markers, such as P62 and LC3, and lysosomal dysfunction in NIH 3T3 cells (mouse embryonic fibroblast cells) [203] . The spleen can capture nanoparticles in Wistar rats [204] . Nanoparticles are mainly ingested by liver Kupffer cells, but splenic macrophages also play an important role [205] . Bismuth nanoparticles induce autophagy markers, such as LC3, Beclin 1, and Atg12, resulting in nephrotoxicity in the human embryonic kidney 293 cell line and kidney of BALB/c mice [206] . Bismuth nanoparticles also induce oxidative stress, such as GSH, SOD, and catalase, and apoptosis in MCF-7 cells (human breast carcinoma cells) [207] . Bismuth sulfide nanoparticles inhibit the migration and invasion in HepG2 cells and induce autophagy markers, such as p62 [208] . Bismuth nanoparticles affect the autophagy-associated cytotoxicity and cellular uptake mechanisms in human kidney cells [209] . Nanosized titanium dioxide (Nano TiO 2 ) results in a potential reproduction toxicity in rat Sertoli cells (SCs), induces apoptosis, decreases cell viability, and impairs morphological structures of SCs via the related wingless MMTV integration site (Wnt) pathway [210] . Long-term exposure to nano-TiO 2 results in liver inflammation and hepatic fibrosis in mice [211] . Nasal instillation to nano-TiO 2 induces lung injury in mice [212] . Nano-TiO 2 results in inflammation and fibration in mice kidneys [213] . Nano-TiO 2 changes autophagy markers, such as Beclin 1, p62 and LC3, in podocytes [214] . Nano-TiO 2 causes the autophagy marker, LC3, to increase in human HaCaT cells at non-cytotoxic levels [215] . Nano-TiO 2 induces autophagic response in HeLa cells [216] . Nano-TiO 2 induces proteostasis disruption and autophagy markers, such as LC3 and p62, in HTR-8/SVneo cells [217] . Planetary micro-and nanosized particles cause nervous system injury [218] . Copper oxide nanoparticles induce an autophagy-related response in A549 cells [219] . Copper-palladium alloy tetrapod nanoparticles induce autophagy [220] . In addition, a workplace was assessed in terms of the exposure to engineered nanoparticles of alumina, amorphous silica, and ceria used in semiconductor device fabrication [221] . One study shows workers occupational exposure to engineered nanomaterials closed to micro-sized agglomerated NSs [222] . Autophagy induces cell survival, which may induce inflammation, toxicity, and diseases.

Briefly, plastic particles can be classified into the following three types: macroplastics (over 5 mm in size) [223] , small plastic particles (less than 5 mm in size) named microplastics [224] , and nanoplastics (less than 1000 nm or 100 nm in size) [225] . Recently, we overused plastic-related products. When waste plastic is fragmented into micro and nanoparticles, it can cause obstruction, inflammation, and accumulation in organs [226, 227] . PS microplastics change gut microbiota dysbiosis and decrease gut mucin secretion in mice [228] . Due to their neuron toxicity, PS microplastics change the acetylcholinesterase activity in mice [135] . PS nanoplastics induce ER stress-mediated autophagy markers, such as LC3, in human lung cells [229] , LGG-1, an ortholog of Atg8 on the nematode, Caenorhabditis elegans [230] , and the autophagic marker, LC3B, in mouse embryonic fibroblasts [231] . Positively charged PS nanospheres induce autophagy markers, such as p62, Beclin 1, and LC3, in mice macrophage-like cells, RAW 264.7, and human lung epithelial cells, BEAS-2B [232] . Vinyl chloride (VC) or PVC is considered a carcinogenic factor that causes angiosarcoma in the liver [233] . VC induces fibrosis and autophagy markers, such as Beclin 1, and LC3, in kidney cells [234] . Synthetic textile workers are potentially exposed to high concentrations of microplastics in the air and suffer higher rates of lung-cancer-related mortality [235] . In addition, MSs and NSs, such as dust, silica, and asbestos, in cells are not easily decomposed. Workers exposed to high concentrations of dust are at risk of pneumoconiosis [68, 236] . Pneumonoultramicroscopic silicovolcanoconiosis or silicosis is a type of pulmonary fibrosis caused by the accumulation of fine particles of crystalline silica in the lungs [237] . The prevalence of asbestosis is due to the use of asbestos-related products [238] (Figure 3 ). Asbestos also induces programmed necrosis in human mesothelial cells [239] . A recent study showed that asbestos induces autophagy markers, such as ATG5, p62, Beclin 1, and LC3, and mesothelial cell transformation [240] . In addition, microplastic particles were found to be deposited in urban dust [241] [242] [243] . Urban dust is a kind of airborne PM, containing 2-10 µm particles [244] . Recent, studies investigating MSs, NSs, and PM show that these materials may endocytose cells and result in cell death or cell survival, depending on their characteristics. 

We found that the previous studies show that many MSs or NSs induce autophagy (Table 1) . Autophagy plays dual roles, resulting in cell death [38, 245] and cell survival [246, 247] . Cell survival may result in tumorigenesis [248] . Autophagy may represent a type of tumor suppressor mechanism, as it has been found that this pathway is frequently related to autophagy markers that are downregulated in tumor cells [249] , which are implied to be involved in tumorigenesis [250] . Studies have indicated that a loss of autophagy function initiates cancer [251] . Autophagy is as a tumor suppressor. For example, a study indicated that mice with a deletion of atg5 and atg7 had benign liver adenomas [252] . Beclin 1 is deleted in most cases of human breast, prostate, and ovarian cancer [253] . The frameshift mutation in the ultraviolet radiation resistance-associated gene (UVRAG) decreases autophagy in colon and gastric cancers [254] . There are other proteins involved in autophagy, such as Atg4c [255] , Bax-interacting factor-1 (Bif-1) [256] , BH3-only proteins [257] , DAP kinase [258] , and PTEN [259] , which shows its potential role in tumor suppression. Recently, a study showed that autophagy is involved in tumor suppression via three mechanisms. First, autophagy plays a role in tumor suppression by inhibiting necrosismediated inflammation. Second, autophagy plays a role in tumor suppression by maintaining genome integrity. Third, autophagy plays a role in tumor suppression by maintaining autophagy-mediated cell death and senescence [260] . In addition, autophagy plays a dual role in cancer [261] . In the beginning of tumorigenesis, autophagy prevents mutations and genotoxicity in healthy tissues due to the production of ROS [262] . However, autophagy can also be useful for tumor survival if carcinogenesis has already begun. Autophagy also helps cancer stem cells to survive stressors [263] , such as cancer cell survival or chemoresistance [264] . In fact, some MSs or NSs have carcinogenic potential such as iron oxide nanoparticles [17] . PM2.5 is associated with chronic airway inflammatory diseases and lung cancer [32] . VC is considered a carcinogenic factor [233] . Asbestos causes laryngeal cancer [265] . Many MSs and NSs have been found to induce autophagy ( Table  1 ), implying that these cells have a chance of undergoing tumorigenesis. 

We found that the previous studies show that many MSs or NSs induce autophagy (Table 1) . Autophagy plays dual roles, resulting in cell death [38, 245] and cell survival [246, 247] . Cell survival may result in tumorigenesis [248] . Autophagy may represent a type of tumor suppressor mechanism, as it has been found that this pathway is frequently related to autophagy markers that are downregulated in tumor cells [249] , which are implied to be involved in tumorigenesis [250] . Studies have indicated that a loss of autophagy function initiates cancer [251] . Autophagy is as a tumor suppressor. For example, a study indicated that mice with a deletion of atg5 and atg7 had benign liver adenomas [252] . Beclin 1 is deleted in most cases of human breast, prostate, and ovarian cancer [253] . The frameshift mutation in the ultraviolet radiation resistance-associated gene (UVRAG) decreases autophagy in colon and gastric cancers [254] . There are other proteins involved in autophagy, such as Atg4c [255] , Bax-interacting factor-1 (Bif-1) [256] , BH3-only proteins [257] , DAP kinase [258] , and PTEN [259] , which shows its potential role in tumor suppression. Recently, a study showed that autophagy is involved in tumor suppression via three mechanisms. First, autophagy plays a role in tumor suppression by inhibiting necrosis-mediated inflammation. Second, autophagy plays a role in tumor suppression by maintaining genome integrity. Third, autophagy plays a role in tumor suppression by maintaining autophagy-mediated cell death and senescence [260] . In addition, autophagy plays a dual role in cancer [261] . In the beginning of tumorigenesis, autophagy prevents mutations and genotoxicity in healthy tissues due to the production of ROS [262] . However, autophagy can also be useful for tumor survival if carcinogenesis has already begun. Autophagy also helps cancer stem cells to survive stressors [263] , such as cancer cell survival or chemoresistance [264] . In fact, some MSs or NSs have carcinogenic potential such as iron oxide nanoparticles [17] . PM2.5 is associated with chronic airway inflammatory diseases and lung cancer [32] . VC is considered a carcinogenic factor [233] . Asbestos causes laryngeal cancer [265] . Many MSs and NSs have been found to induce autophagy (Table 1 ), implying that these cells have a chance of undergoing tumorigenesis.

Magnetic nanoparticles Autophagy markers: Atg5, Atg12, and LC3

In vitro: Human lung adenocarcinoma cells (A549) and human lung fibroblast cells (IMR-90) [154] Manganese nanoparticles Autophagy markers: Beclin 1, and LC3

In vitro: Rat mesencephalic dopaminergic cells (N27) [158] Quantum dots Autophagy markers: p62 and LC3 In vitro: Rat adrenal medulla pheochromocytoma cells (PC12) [161] Autophagy marker: LC3

In vitro: Porcine renal proximal cell line (LLC-PK1) [162] Graphene oxide quantum dots Autophagy markers: p62 and LC3 In vitro: Mouse reproductive cells (GC-2 and TM4 cells) [163] Graphene oxide Autophagy markers: p62 and LC3 In vitro: Rat glioblastoma cells (F98) [164] Particulate matter 2.5 (PM2.5)

Autophagy markers: Beclin 1, ULK-1, and LC3

In vitro: Human bronchial epithelial cells (BEAS-2B) [167] Autophagy markers: Beclin 1, ATG5,ULK-1, and LC3

In vitro: Monocytic leukemia cells (THP-1) [168] Autophagy-mediated cell death

In vitro: Human bronchial epithelium cells (BEAS-2B) [170] Autophagy markers: p62 and LC3

In vivo: Liver of C57BL/6 mice [173] Autophagy markers: ATG5, VSP34, Beclin 1, and LC3

In vivo: Spleen of Sprague Dawley (SD) rats [174] Autophagy markers: p62, Beclin 1, and LC3

In vitro: Human kidney tubular epithelial cells (HK-2) [175] In vivo: Kidney of SD rat Autophagy marker: LC3 [181] Autophagy marker: LC3 In vitro: Human ovarian cancer cells (SKOV3) [182] Autophagy markers: p62 and LC3 In vitro: Human epidermal keratinocytes (HEKn) [183] Autophagy marker LC3A and autophagic cell death

In vitro: Human T lymphoblast cells (SupT1 and Jurkat cells), C57BL/6 mouse primary splenocytes and primary human T-cells [184] Autophagic cell death In vitro: Rat adrenal medulla pheochromocytoma cells (PC12 cells) [185] Autophagy marker: LC3 In vitro: Primary murine astrocytes [186] Silica nanoparticles Autophagy marker: LC3 and autophagic cell death

In vitro: Human liver cancer cells (HepG2 cells) [193] Autophagy marker: P62

In vitro: Human bronchial epithelial cells (BEAS-2B) [196] In vivo: Lung of Bltw:CD1 (ICR) mice Table 1 . Cont.

Autophagy markers: p62 and LC3 Human umbilical vein endothelial cells (HUVECs) [197] Silver nanoparticles Autophagy markers: LC3 In vitro: Human liver cancer cells (HepG2 cells) [200] Autophagy markers: p62 and LC3

In vitro: Human lung adenocarcinoma cells (A549) [201] Autophagy markers: Beclin 1 and LC3 In vivo: Adult brain of Wistar rat [202] Autophagy markers: P62 and LC3

In vitro: Mouse embryonic fibroblast cells (NIH 3T3 cells) [203] Bismuth nanoparticles Autophagy markers: Atg12, Beclin 1, and LC3

In vitro: Human embryonic kidney 293 cells (HEK293) [204] In vivo: Kidney of BALB/c mice Autophagy marker: p62

In vitro: Human liver cancer cells (HepG2 cells) [208] Autophagy associated cytotoxicity In vitro: Human embryonic kidney 293 cells (HEK293) [209] Nanosized titanium dioxide(Nano TiO 2

Autophagy markers: Beclin 1, p62, and LC3 In vitro: Mouse podocyte cells (MPCs) [214] Autophagy marker: LC3 In vitro: Human keratinocytes (HaCaT cells) [215] Autophagy marker: LC3 In vitro: Human cervical cancer cells (HeLa cells) [216] Autophagy markers: p62, LC3 and autophagic cell death

In vitro: Human trophoblast cells (HTR-8/SVneo cells) [217] Copper oxide nanoparticles Autophagic cell death

In vitro: Human lung adenocarcinoma cells (A549) [219] Polystyrene (PS) nanoplastics Endoplasmic Reticulum(ER) stress-mediated autophagy marker: LC3

In vitro: Human bronchial epithelial cells (BEAS-2B) [229] Autophagic marker: LC3B

In vitro: Mouse embryonic fibroblasts (MEFs) [231] Autophagy markers: p62, Beclin 1, and LC3 

Many MSs and NSs may pose a potential risk to human health. How can these MSs and NSs be decreased and prevented from flowing into natural systems? Recently, some MSs and NSs have been applied in wastewater purification, such as activated carbon, carbon nanotubes, graphene, manganese oxide, zinc oxide, titanium oxide, magnesium oxide, and ferric oxides, which can be applied to remove heavy metals from wastewater [266] . In addition, wastewater treatment plants in several countries have found microplastic particles [267, 268] , such as the USA [268] , Canada [269] , and Turkey [270] . Several approaches can be used to decrease the volume of micro-and nanoplastics in water and wastewater, such as density separation, coagulation, membrane bioreactors, and biodegradation [271, 272] . In addition, new techniques have been developed for water purification, such as three-dimensional graphene-based hybrid materials [273] , the removal of heavy metals [274] , and microplastic removal [275] . Biodegradation also seems to be a good approach, as plastic particles can be completely transformed into CO 2 and water. Studies investigating several potential candidate marine bacteria have found that these bacteria can be used in the degradation of plastic particles [276] . Some fungal strains have been shown to degrade several plastics, such as PHB and PLA [103] . PS is known to be biodegraded in the gut of yellow mealworms because there are special microorganisms in the gut [277] . In addition, many enzymes purified from different bacteria, such as Ideonella sakaiensis 201-F6, have been identified and can degrade PET plastics [278] . In April 2020, a total of 436 species reported in 1451 publications were found to degrade plastic. The three types of species that can degrade plastic that were reported most often reported among the 66 different types are Bacillus pumilus, Aspergillus fumigatus, and Phanerochaete chrysosporium, which were found to degrade 14, 11, and 10 different types of plastic, respectively [279] . Furthermore, many enzymes have been found that can hydrolyze polyesters, such lipase, esterase, protease, cutinase, PHA depolymerase, catalase, urease and glucosidases [280] . On other hand, polyester-based biodegradable plastics, such as PLA (poly(lactic acid)), PCL (polylcaprolactone), PHB (polyhydroxybutyrate)/PHBV (Polyhydroxybutyrate-covalarate), PBST(Poly(butylene succinate co-terephthalate), PBAT (Poly(butyrate adipate co-terephthalate)), PU (Polyurethanes) and PET (poly(ethylene terephthalate)), have potential in relation to waste reduction [280, 281] . In addition, changing consumer behavior is another way to reduce plastics, such as plastic bag fee changes in Turkey [282] . The plastic carrier bag tax in Portugal reduced plastic bag consumption by 74% and increased reusable plastic bag consumption by 61% [283] . Several countries, such as the USA [284] and Caribbean countries [285] , have adopted several methods for reducing single-use plastic bags.

Recently, EVs have played an important role in cell communication. The size of EVs, MSs, and NSs is similar. Some products made by humans are not easily decomposed. These products become environmental pollutants and bioaccumulate when they are fragmented into MSs and NSs. Among these particles, their interaction with other toxic matter has been well studied in PM2.5, MSs, and NSs. These studies have shown that MSs and NSs accumulate in organs via the food chain. In addition, MSs and NSs engulf cells and induce several cell responses, depending on their size and carrying capacity. Autophagy is a mechanism by which foreign matter decomposes in tissues or organisms. Some artificial materials are not easily decomposed by autophagy. Many MSs and NSs induce the formation of ROS, autophagic responses and apoptosis in various cells or tissues. Studies have indicated that autophagy operates through two pathways (cell death and cell survival) in tumorigenesis. MS-and NS-expressed autophagy may lead to tumorigenesis. Therefore, we found that pneumoconiosis, silicosis, and asbestosis from dust, silica, and asbestos have long disease histories, implying that MSs and NSs have previously interfered with cells and tissues and may interfere with our health through different materials in the future. Finally, the number of species of environmental bacteria and fungi found to degrade plastic seems to be increasing. [CrossRef] [PubMed] 

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Genotoxicity of TiO2 Nanoparticles in Four Different Human Cell Lines (A549, HEPG2, A172 and SH-SY5Y). Nanomaterials 2020

Study of electrolyte induced aggregation of gold nanoparticles capped by amino acids

Impact of natural organic matter and divalent cations on the stability of aqueous nanoparticles

Transcriptome changes in undifferentiated Caco-2 cells exposed to food-grade titanium dioxide (E171): Contribution of the nano-and micro-sized particles

Evidence for biomagnification of gold nanoparticles within a terrestrial food chain

Bioaccumulation of gold nanomaterials by Manduca sexta through dietary uptake of surface contaminated plant tissue

Abundance and characteristics of microplastics in market bivalves from South Korea

Microplastics in Seafood and the Implications for Human Health

Microplastics Detection in Streaming Tap Water with Raman Spectroscopy

Microplastics in freshwaters and drinking water: Critical review and assessment of data quality

Influencing Factors of PM2.5 Pollution: Disaster Points of Meteorological Factors

Xing Shi Gan Decoction Attenuates PM2.5 Induced Lung Injury via Inhibiting HMGB1/TLR4/NFkappaB Signal Pathway in Rat

Evaluation of tumorigenic potential of CeO 2 and Fe 2 O 3 engineered nanoparticles by a human cell in vitro screening model

Using machine learning to understand the temporal morphology of the PM2.5 annual cycle in East Asia

Chemical fractionation, bioavailability, and health risks of heavy metals in fine particulate matter at a site in the Indo-Gangetic Plain

Airborne nanoparticles (PM0.1) induce autophagic cell death of human neuronal cells

PM0.1 particles from aircraft may increase risk of vascular disease

Spermatogenesis dysfunction induced by PM2.5 from automobile exhaust via the ROS-mediated MAPK signaling pathway

Urban fine particulate matter (PM2.5) exposure destroys blood-testis barrier (BTB) integrity through excessive ROS-mediated autophagy

A Comparison of the Health Effects of Ambient Particulate Matter Air Pollution from Five Emission Sources

Molecular definitions of autophagy and related processes

Biological Functions of Autophagy Genes: A Disease Perspective

Atg" is an abbreviation for "autophagy-related

Autophagy and multidrug resistance in cancer

Exercise-induced BCL2-regulated autophagy is required for muscle glucose homeostasis

Pancreatic stellate cells support tumour metabolism through autophagic alanine secretion

Author Correction: Disruption of the beclin 1-BCL2 autophagy regulatory complex promotes longevity in mice

Regulation of endoplasmic reticulum turnover by selective autophagy

Metabolic control of cell death

EGFR-mediated Beclin 1 phosphorylation in autophagy suppression, tumor progression, and tumor chemoresistance

Autophagosome-lysosome fusion

The proteome of lysosomes

Processing and activation of lysosomal proteinases

Lack of Cathepsin D in the Renal Proximal Tubular Cells Resulted in Increased Sensitivity against Renal Ischemia/Reperfusion Injury

Prevalence of and factors related to pneumoconiosis among foundry workers in central Taiwan

Extracellular Vesicles in Cardiovascular Diseases: Alternative Biomarker Sources, Therapeutic Agents, and Drug Delivery Carriers

Extracellular Vesicles in Cardiovascular Theranostics. Theranostics

Specificities of secretion and uptake of exosomes and other extracellular vesicles for cell-to-cell communication

Stem cell-derived extracellular vesicles: Role in oncogenic processes, bioengineering potential, and technical challenges

Extracellular Vesicles: Exosomes and Microvesicles, Integrators of Homeostasis

Exosomes: Revisiting their role as "garbage bags

Microparticles and vascular dysfunction in obstructive sleep apnoea

Apoptotic cell clearance: Basic biology and therapeutic potential

Disassembly of the Dying: Mechanisms and Functions

Extracellular vesicles, news about their role in immune cells: Physiology, pathology and diseases

Large Extracellular Vesicles: Have We Found the Holy Grail of Inflammation?

Extracellular vesicles in atherosclerosis

Extracellular Vesicles as Messengers in Atherosclerosis

The Role of Extracellular Vesicles and PIBF in Embryo-Maternal Immune-Interactions

Extracellular vesicles in the tumor microenvironment: Old stories, but new tales

Conditioned Medium of Mesenchymal Stromal Cells: A New Class of Therapeutics

Dental Pulp Stem Cell-Derived Conditioned Medium: An Attractive Alternative for Regenerative Therapy

Understanding the multifaceted mechanisms of diabetic wound healing and therapeutic application of stem cells conditioned medium in the healing process

Conditioned medium from 3D culture system of stromal vascular fraction cells accelerates wound healing in diabetic rats

Conditioned Medium Obtained from Amnion-Derived Mesenchymal Stem Cell Culture Prevents Activation of Keloid Fibroblasts

The use of cell conditioned medium for musculoskeletal tissue regeneration

Hair Regeneration Therapy: Application of Adipose-Derived Stem Cells

Mesenchymal stem cell-derived extracellular vesicles and retinal ischemia-reperfusion

Retinal ganglion cell-conditioned medium and surrounding pressure alters gene expression and differentiation of rat retinal progenitor cells

Canine mesenchymal stromal cellconditioned medium promotes survival and neurite outgrowth of neural stem cells

Therapeutic potential of conditioned medium derived from oligodendrocytes cultured in a self-assembling peptide nanoscaffold in experimental autoimmune encephalomyelitis

Stem Cell Conditioned Medium Treatment for Canine Spinal Cord Injury: Pilot Feasibility Study

Therapeutic potential of mesenchymal stem/stromal cell-derived secretome and vesicles for lung injury and disease

Exosomes from Cell Culture-Conditioned Medium: Isolation by Ultracentrifugation and Characterization

Silk nanospheres and microspheres from silk/pva blend films for drug delivery

Vertical distribution of aerosols in dust storms during the Arctic winter

Mobile platform measurements of ultrafine particles and associated pollutant concentrations on freeways and residential streets in Los Angeles

Exposure assessment for atmospheric ultrafine particles (UFPs) and implications in epidemiologic research

Our plastic age

Study of microbes having potentiality for biodegradation of plastics

Combined Effects of UV Exposure Duration and Mechanical Abrasion on Microplastic Fragmentation by Polymer Type

Quantifying shedding of synthetic fibers from textiles; a source of microplastics released into the environment

Microplastic fibres from synthetic textiles: Environmental degradation and additive chemical content

Microfibers in oceanic surface waters: A global characterization

Effects of Technical Textiles and Synthetic Nanofibers on Environmental Pollution

Microplastics in mussels sampled from coastal waters and supermarkets in the United Kingdom

Branded milks-Are they immune from microplastics contamination?

Synthetic particles as contaminants in German beers

Anthropogenic contamination of tap water, beer, and sea salt

Microplastics in Spanish Table Salt. Sci. Rep. 2017, 7, 8620

Non-pollen particulates in honey and sugar

Plastic Teabags Release Billions of Microparticles and Nanoparticles into Tea

Occurrence of microplastics in raw and treated drinking water

Analysis of microplastics in water by micro-Raman spectroscopy: Release of plastic particles from different packaging into mineral water

Microplastic in bottled natural mineral water-literature review and considerations on exposure and risk assessment

The Role of Autophagy in Nanoparticles-Induced Toxicity and Its Related Cellular and Molecular Mechanisms

Susceptibility Factors in Chronic Lung Inflammatory Responses to Engineered Nanomaterials

Engineered Nanomaterials and Type I Allergic Hypersensitivity Reactions. Front. Immunol. 2020, 11, 222

Immune responses to engineered nanomaterials: Current understanding and challenges

Inflammatory responses may be induced by a single intratracheal instillation of iron nanoparticles in mice

Chronic pulmonary accumulation of iron oxide nanoparticles induced Th1-type immune response stimulating the function of antigen-presenting cells

Induction of ROS, mitochondrial damage and autophagy in lung epithelial cancer cells by iron oxide nanoparticles

Uptake and metabolism of iron oxide nanoparticles in brain cells

Potential Toxicity and Underlying Mechanisms Associated with Pulmonary Exposure to Iron Oxide Nanoparticles: Conflicting Literature and Unclear Risk

Potential Toxicity of Iron Oxide Magnetic Nanoparticles: A Review

Manganese nanoparticle activates mitochondrial dependent apoptotic signaling and autophagy in dopaminergic neuronal cells

Revisiting the cytotoxicity of quantum dots: An in-depth overview

Dysfunction of various organelles provokes multiple cell death after quantum dot exposure

Autophagy-sensitized cytotoxicity of quantum dots in PC12 cells

Induction of autophagy in porcine kidney cells by quantum dots: A common cellular response to nanomaterials?

Graphene oxide quantum dots disrupt autophagic flux by inhibiting lysosome activity in GC-2 and TM4 cell lines

The interrupted effect of autophagic flux and lysosomal function induced by graphene oxide in p62-dependent apoptosis of F98 cells

The Toxicology of Engineered Nanomaterials in Asthma

Metal nanomaterials: Immune effects and implications of physicochemical properties on sensitization, elicitation, and exacerbation of allergic disease

Stress fibers, autophagy and necrosis by persistent exposure to PM2.5 from biomass combustion

PM 2.5 Exposure Induced Autophagy Activation via the ROS/AMPK/mTOR/ULK1 Signaling Axis in Macrophages

Developmental toxicity induced by PM2.5 through endoplasmic reticulum stress and autophagy pathway in zebrafish embryos

5 induces autophagymediated cell death via NOS2 signaling in human bronchial epithelium cells

Metformin protects against PM2.5-induced lung injury and cardiac dysfunction independent of AMP-activated protein kinase alpha2

Air pollution, a rising environmental risk factor for cognition, neuroinflammation and neurodegeneration: The clinical impact on children and beyond

Counteracts Hepatic Steatosis in Mice Fed High-fat Diet by Stimulating Hepatic Autophagy. Sci. Rep. 2017, 7, 16286

The potential immunotoxicity of fine particulate matter based on SD rat spleen

PM 2.5 exposure induced renal injury via the activation of the autophagic pathway in the rat and HK-2 cell

Causation by Diesel Exhaust Particles of Endothelial Dysfunctions in Cytotoxicity, Proinflammation, Permeability, and Apoptosis Induced by ROS Generation

Diesel Exhaust Particles and the Induction of Macrophage Activation and Dysfunction

Association between Metabolic and Hormonal Derangements and Professional Exposure to Urban Pollution in a High Intensity Traffic Area

Traffic-related particulate matter exposure induces nephrotoxicity in vitro and in vivo. Free Radic

Silica sub-microspheres induce autophagy in an endocytosis dependent manner

Zinc Oxide Particles Induce Activation of the Lysosome-Autophagy System

Zinc oxide nanoparticles induce apoptosis and autophagy in human ovarian cancer cells

Understanding the implications of engineered nanoparticle induced autophagy in human epidermal keratinocytes in vitro

Acute exposure to ZnO nanoparticles induces autophagic immune cell death

Zinc oxide nanoparticles effectively regulate autophagic cell death by activating autophagosome formation and interfering with their maturation

Zinc Oxide Nanoparticles Induce Autophagy and Apoptosis via Oxidative Injury and Pro-Inflammatory Cytokines in Primary Astrocyte Cultures

Zinc Oxide Nanoparticles Exhibit Both Cyclooxygenaseand Lipoxygenase-Mediated Apoptosis in Human Bone Marrow-Derived Mesenchymal Stem Cells

Amorphous SiO 2 nanoparticles promote cardiac dysfunction via the opening of the mitochondrial permeability transition pore in rat heart and human cardiomyocytes

Silica nanoparticles induce cardiotoxicity interfering with energetic status and Ca(2+) handling in adult rat cardiomyocytes

Silica Nanoparticles Disturb Ion Channels and Transmembrane Potentials of Cardiomyocytes and Induce Lethal Arrhythmias in Mice

Two distinct cellular pathways leading to endothelial cell cytotoxicity by silica nanoparticle size

Silica nanomaterials induce organ injuries by Ca(2+)-ROS-initiated disruption of the endothelial barrier and triggering intravascular coagulation

Silica nanoparticles induce autophagy and autophagic cell death in HepG2 cells triggered by reactive oxygen species

Ultrafine silicon dioxide nanoparticles cause lung epithelial cells apoptosis via oxidative stress-activated PI3K/Akt-mediated mitochondria-and endoplasmic reticulum stress-dependent signaling pathways

Silica nanoparticles induce lung inflammation in mice via ROS/PARP/TRPM2 signaling-mediated lysosome impairment and autophagy dysfunction

p62/SQSTM1 accumulation due to degradation inhibition and transcriptional activation plays a critical role in silica nanoparticle-induced airway inflammation via NF-kappaB activation

Amorphous silica nanoparticles trigger vascular endothelial cell injury through apoptosis and autophagy via reactive oxygen species-mediated MAPK/Bcl-2 and PI3K/Akt/mTOR signaling

Silver nanoparticles: Electron transfer, reactive oxygen species, oxidative stress, beneficial and toxicological effects. Mini review

Differential genotoxicity mechanisms of silver nanoparticles and silver ions

Silver Nanoparticle-Induced Autophagic-Lysosomal Disruption and NLRP3-Inflammasome Activation in HepG2 Cells Is Size-Dependent

Silver nanoparticles induce lysosomal-autophagic defects and decreased expression of transcription factor EB in A549 human lung adenocarcinoma cells

A Low Dose of Nanoparticulate Silver Induces Mitochondrial Dysfunction and Autophagy in Adult Rat Brain

Endoplasmic reticulum stress-triggered autophagy and lysosomal dysfunction contribute to the cytotoxicity of amine-modified silver nanoparticles in NIH 3T3 cells

Spleen capture of nanoparticles: Influence of animal species and surface characteristics

Emerging Role of the Spleen in the Pharmacokinetics of Monoclonal Antibodies, Nanoparticles and Exosomes

The protective role of autophagy in nephrotoxicity induced by bismuth nanoparticles through AMPK/mTOR pathway

Bismuth oxide nanoparticles induce oxidative stress and apoptosis in human breast cancer cells

Autophagic blockage by bismuth sulfide nanoparticles inhibits migration and invasion of HepG2 cells

Autophagy associated cytotoxicity and cellular uptake mechanisms of bismuth nanoparticles in human kidney cells

Wnt Pathway-Mediated Nano TiO 2 -Induced Toxic Effects on Rat Primary Cultured Sertoli Cells

Liver Inflammation and Fibrosis Induced by Long-Term Exposure to Nano Titanium Dioxide (TiO 2 ) Nanoparticles in Mice and Its Molecular Mechanism

Respiratory exposure to nano-TiO 2 induces pulmonary toxicity in mice involving reactive free radical-activated TGF-beta/Smad/p38MAPK/Wnt pathways

Nanosized titanium dioxide resulted in the activation of TGF-beta/Smads/p38MAPK pathway in renal inflammation and fibration of mice

Nano-TiO 2 induces autophagy to protect against cell death through antioxidative mechanism in podocytes

Dose-dependent autophagic effect of titanium dioxide nanoparticles in human HaCaT cells at non-cytotoxic levels

Autophagic response to cellular exposure to titanium dioxide nanoparticles

Titanium dioxide nanoparticles induce proteostasis disruption and autophagy in human trophoblast cells

Nervous System Injury in Response to Contact with Environmental, Engineered and Planetary Micro-and Nano-Sized Particles

Copper oxide nanoparticles induce autophagic cell death in A549 cells

Harnessing copper-palladium alloy tetrapod nanoparticle-induced pro-survival autophagy for optimized photothermal therapy of drug-resistant cancer

An occupational exposure assessment for engineered nanoparticles used in semiconductor fabrication

A Systematic Review of Reported Exposure to Engineered Nanomaterials

Microplastics in the marine environment: Current trends in environmental pollution and mechanisms of toxicological profile

Export of Plastic Debris by Rivers into the Sea

Current opinion: What is a nanoplastic?

The behaviors of microplastics in the marine environment

The physical impacts of microplastics on marine organisms: A review

Impacts of polystyrene microplastic on the gut barrier, microbiota and metabolism of mice

Targeted metabolomics reveals differential biological effects of nanoplastics and nanoZnO in human lung cells

Effect of chronic exposure to nanopolystyrene on nematode Caenorhabditis elegans

Stress Response of Mouse Embryonic Fibroblasts Exposed to Polystyrene Nanoplastics

Cationic polystyrene nanospheres induce autophagic cell death through the induction of endoplasmic reticulum stress

Arsenic, vinyl chloride, viral hepatitis, and hepatic angiosarcoma: A hospital-based study and review of literature in Taiwan

Induction of Fibrosis and Autophagy in Kidney Cells by Vinyl Chloride

Cancer mortality in a synthetic spinning plant in Besancon, France

Possible effect of gene polymorphisms on the release of TNFα and IL1 cytokines in coal workers' pneumoconiosis

Silicosis in a grey iron foundry: The persistence of an ancient disease

Programmed necrosis induced by asbestos in human mesothelial cells causes high-mobility group box 1 protein release and resultant inflammation

Asbestos induces mesothelial cell transformation via HMGB1-driven autophagy

Microplastic pollution in deposited urban dust

Distribution and potential health impacts of microplastics and microrubbers in air and street dusts from Asaluyeh County

Temporal and spatial variations of microplastics in roadside dust from rural and urban Victoria, Australia: Implications for diffuse pollution

Analysis of urban dust (PM2/PM10-2) in Daejeon city by instrumental neutron activation analysis

Selenium nanoparticles induce autophagy mediated cell death in human keratinocytes

Ubiquitin-coated nanodiamonds bind to autophagy receptors for entry into the selective autophagy pathway

Key Role of TFEB Nucleus Translocation for Silver Nanoparticle-Induced Cytoprotective Autophagy

The interplay between autophagy and tumorigenesis: Exploiting autophagy as a means of anticancer therapy

Reduced autophagic activity in primary rat hepatocellular carcinoma and ascites hepatoma cells

Mechanism and medical implications of mammalian autophagy

Autophagic cell death restricts chromosomal instability during replicative crisis

Autophagy-deficient mice develop multiple liver tumors

Promotion of tumorigenesis by heterozygous disruption of the beclin 1 autophagy gene

Frameshift mutation of UVRAG, an autophagy-related gene, in gastric carcinomas with microsatellite instability

Tissue-specific autophagy alterations and increased tumorigenesis in mice deficient in Atg4C/autophagin-3

Mild heat shock induces autophagic growth arrest, but not apoptosis in U251-MG and U87-MG human malignant glioma cells

Control of autophagy by oncogenes and tumor suppressor genes

Lethal weapons: DAP-kinase, autophagy and cell death: DAP-kinase regulates autophagy

Programmed autophagy in the Drosophila fat body is induced by ecdysone through regulation of the PI3K pathway

Autophagy in tumor suppression and cancer therapy

Challenges and Therapeutic Opportunities of Autophagy in Cancer Therapy

U2AF35(S34F) Promotes Transformation by Directing Aberrant ATG7 Pre-mRNA 3' End Formation

Autophagy and cancer stem cells: Molecular mechanisms and therapeutic applications

Autophagy: A novel mechanism of chemoresistance in cancers

Remediation of wastewater using various nanomaterials

Wastewater treatment plants as a pathway for microplastics: Development of a new approach to sample wastewater-based microplastics

Microplastic pollution is widely detected in US municipal wastewater treatment plant effluent

Retention of microplastics in a major secondary wastewater treatment plant in Vancouver

Microplastics in municipal wastewater treatment plants in Turkey: A comparison of the influent and secondary effluent concentrations

Nano/microplastics in water and wastewater treatment processes-Origin, impact and potential solutions

Bioremediation as a promising strategy for microplastics removal in wastewater treatment plants

Synthesis of Three-Dimensional Graphene-Based Hybrid Materials for Water Purification: A Review

Membrane Processes for Microplastic Removal

Degradation of plastics and plastic-degrading bacteria in cold marine habitats

Biodegradation of Polyethylene and Plastic Mixtures in Mealworms (Larvae of Tenebrio molitor) and Effects on the Gut Microbiome

Phylogenetic Distribution of Plastic-Degrading Microorganisms. mSystems 2021, 6

Polyester-based biodegradable plastics: An approach towards sustainable development

Biodegradable plastics: Green hope or greenwashing?

An evaluation of the effect of plastic bag fee on consumer behavior: Case of Turkey

The Portuguese plastic carrier bag tax: The effects on consumers' behavior. Waste Manag

Reducing single-use plastic shopping bags in the USA

Policy responses to reduce single-use plastic marine pollution in the Caribbean

The authors declare no conflict of interest.