Liquid biopsy can detect circulating epithelial cells (CECs) in the setting of localized cancers as well as preneoplastic lesions, suggesting their presence is not limited to cells derived from established cancers [11,12]. Hepatic CECs have not been widely studied in the absence of malignancy, but existing studies suggest they could serve as a powerful biomarker for the widespread diagnosis and monitoring of various CLDs as well of hepatocellular carcinoma. The CECs associated with a known malignancy are termed circulating tumor cells (CTCs) [13] (see Fig. 1).

CTCs are lost by both primary and metastatic cancers and they are thought to mediate the hematogenous disperse of cancer to remote sites, including bone, lung, brain, and liver. In metastasis, whole living cells (CTCs) released from carcinoma in situ survive in the bloodstream to then successfully settle in another organ [14]. The pathophysiology of metastatic cell distribution, most likely, involves interaction with other circulating cells and its target site.

Despite considerable progress, studies of CTCs and their potential use for diagnosis and monitoring of disease, some difficulties remain. One of the main issues in oncology is that in early-stage cancer, few tumor cells are present in the bloodstream because their number is proportional to tumor mass [15]. The estimated abundance of CTCs is almost to none in metastatic disease, e.g., a blood sample from these patients may only contain 1–10 cancer cells in a sea of blood cells [16]. The sensitivity and specificity of the detection techniques for CTCs, which have not yet been developed, must be standardized to obtain reliable and reproducible findings. Isolation of pure populations of CTCs is needed for accurate molecular characterization needed for useful clinical evaluation of CTCs. The technologies required for CTC detection pivot on a large volume of blood and this impedes clinical use in daily practice [17].

However, tumor-derived CTCs in the bloodstream are a heterogeneous population, and therefore, more likely than a tissue sample to reflect the composition of the whole tumor in terms of phenotypic and genetic makeup [18,19].

The methodology used to isolate or detect CTCs is divided into physical and biological procedures (see Fig. 2).

Fig. 2.

Isolation methods for CTCs. (A) Physical methods use multiple filters based on size, density, migratory capacity, deformability, electric charge, and polarity. (B) Biological methods depend on antigen–antibody binding and antibodies against tumor-specific epitopes including epithelial cell adhesion molecule (EpCAM), human epidermal growth factor receptor 2 (Her2), and prostate-specific antigen (PSA) are typically used in CTCs purification.

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Physical procedures rely primarily on the CTCs physical properties, such as size, density, migratory capacity, deformability, and electric charge; newer methods are also based on polarity, which has recently been shown to be critical for adhesion, attachment, migration, and metastasis of CTCs [20,21]. These methods employ centrifugation and filter or flow devices with channels of different sizes and/or properties and can be used to separate and isolate both normal and cancer cells [22]. Most CTCs originate from epithelial tumors and must be separated from much greater numbers of cells in the mix of blood samples, and for that reason, several filtration-based techniques have been developed [23,24] since this methodology allows to process large volumes of blood. There are substantial differences in cell size among cancer patients [25], new techniques with several filters were developed to isolate a wide range of CTCs sizes [26]. Vona et al. first used the isolation by size of epithelial tumor cells (ISET) method to detect CTCs in HCC patients. ISET is a low-cost method that involves the binding of CTCs to membranes and does not require special equipment. However, a potential problem with ISET devices may be a difficulty to completely release bound CTCs from the membranes used in the isolation process, which may yield invalid genetic analyses of the cell populations prepared by this method [22]. Some devices isolate cancer cells based on their size and deformability. For example, Mohamed et al. made an apparatus with narrow channels that filter only cancer cells from other blood cells circulating [27].

Using physical isolation methods followed by cytomorphologic analysis it was shown that the patterns of spontaneous circulating CTCs and circulating tumor microemboli (CTM) in peripheral blood reflect tumor development and metastasis in HCC patients. Also, the numbers of CTCs and CTM were associated with survival in time in HCC patients [20].

Biological methods for CTC isolation depend on antigen-antibody union using antibodies against tumor-specific epitopes. Examples that have been used for CTC purification include epithelial cell adhesion molecule (EpCAM), prostate-specific antigen (PSA), and human epidermal growth factor receptor 2 (Her2) [28]. EpCAM is the most generally used in CTCs purification because its expression is global in cells of epithelial origin, but it is missing in other blood cells. The US Food and Drug Administration (FDA) has only approved EpCAM analysis for use in patients with prostate, breast and colorectal cancer. Cell-Search system (Veridex LLC, NJ, USA) is the most commonly used CTC platform for EpCAM analysis. In this platform, EpCAM antibodies coated with immunomagnetic beads are used to seize CTCs that are then immunostained with two positive markers (cytokeratins 8/18/19 and 4′6′-diaminidino-2-phenylindolehydrochloride) and a negative marker (CD45) [29–34]. Using the Cell-Search system, Sun et al., and Guo et al., proposed EpCAM+CTCs in early decision-making treatment, monitoring treatment response, and to indicate in HCC recurrence [35,36]. Using antibody-based procedures Sun et al. compared CTCs isolated from peripheral veins, portal vein, and hepatic vein, before HCC resection. The greatest number of CTCs was detected in the hepatic vein exiting the liver, with a dramatic reduction in peripheral vessels after passage through the lungs. Furthermore, characterization of CTCs confirmed phenotypic heterogeneity across vascular sites, with a predominantly epithelial phenotype in the hepatic vein, versus an epithelial-mesenchymal transition (EMT) type (associated with Smad2 and beta-catenin) of CTCs isolated from the peripheral veins [37]. The liquid biopsy also offers the opportunity to characterize CTC interactions with circulating immune cells, and the combination of elevated EpCAM-positive CTCs and an increased number of regulatory CD4+ T cells have been reported to be indicative of early HCC recurrence and poor clinical outcome [38].

An alternative method for CTC isolation that offers high sensitivity and specificity is a microfluidic-based CTC-chip platform. In this platform, CTCs may be isolated accurately from limited volumes of blood by flow through microposts coated with EpCAM antibodies. The advantage of this method is that it enhances the interactions between CTCs and the antibody-coated surface and dynamic flows to ban nonspecific binding [39,11]. More alternatives implemented are the CTC-chip to improve the CTCs purification followed by an off-chip enzymatic treatment to enhance the pureness rate, along with a ligand-receptor binding assay to increase the capture rate [40,41]. Also, Wang et al. suggested that the CTC-chip platform might be a convenient method for the efficient and simple detection of CTCs in HCC patients. They created a CTC-BioT-Chip, consisting of a biocompatible and transparent HA/CTS (hydroxyapatite/chitosan) nanofilm coated by sLex-AP (aptamer for carbohydrate sialyl Lewis X) and demonstrated that it could be useful to predict patients prognosis [42]. Most recently, Oklu et al. introduce an antigen-agnostic cell sorting instrument called the iChip, which confines CECs protecting high-quality RNA content and cell viability. Liver-specific RNA markers combined with the iChip made possible a two-step assay for the enrichment and detection of CECs in HCC and CLD [43].

The most relevant clinical applications that have been demonstrated, until now, are presented below. Matsumura et al., using real-time polymerase chain reaction (RT-PCR) demonstrated that alfa fetoprotein (AFP) mRNA in CTCs could be a predictor of outcome in HCC patients [44]. Mou et al. predict the relapse and prognosis of HCC patients using melanoma-associated antigens, MAGE-1 and MAGE-3 mRNAs, as markers of CTCs in the blood [45]. Yao et al. demonstrated that the overexpression of glypican protein-3 (GPC-3) mRNA is useful as a clinical biomarker from early detection and evaluating metastasis on HCC [46]. CD44 and K19 mRNAs have been shown as cancer stem-cell markers in HCC, used as a prognostic factor demonstrated by Choi et al. [47]. Liu et al., and Bahnassy et al., established that intracellular adhesion molecule 1 (ICAM-1), cytokeratin 19, CD133, CD90, and telomerase in HCC blood samples have prognostic value in HCC [48,49]. In the case of benign diseases, Kelley et al., described the detection of CTCs’ DNA in patients with HCC, to a level of at least two cells per 7.5ml, but not in patients with CLD without HCC [50].

CTCs may have a persistent interaction with blood cells that enables them to escape immunosurveillance. Even though certain blood cells are thought to be a key factor in cancer defense, their interactions with CTCs may be a mechanism to escape immune surveillance at times. For example, interactions with T cells can protect CTCs and promote their survival [19]. This can occur when β1-integrins are expressed on CTC surfaces; this facilitates CTC capture by neutrophil extracellular traps (NETs) and has the effect of developing a metastatic niche [51]. Another mechanism by which CTCs escape immune surveillance is their binding to receptors glycoprotein Ib (GPIb) on platelets which promotes tumor cell extravasation that results in metastatic colonization [52].

About 20% of genomic DNA does not have a biochemical function; instead, it is transcribed into several noncoding RNAs (ncRNAs) that are very important for many cellular actions related to the synthesis of proteins from the genome coding regions [86,87]. There are two general types of ncRNAs based on size, long (IncRNAs) and short (SncRNAs) non-coding molecules, both of which are involved in gene expression regulation.

About 10 different IncRNAs are perceptible in HCC patients’ blood work. Metastasis Associated Lung Adenocarcinoma Transcript 1 (MALAT1) and Sprouty Receptor Tyrosine Kinase Signaling Antagonist 4-Intronic Transcript 1 (SPRY4-1T1) IncRNAs levels increase with the grade of HCC and resection of the tumor leads to their decrease in the circulation [88,89]. Differences in plasma levels of the following lncRNAs (XLOC014172,LINC00152, and RP11-160H22.5) can distinguish HCC from chronic hepatitis, cirrhosis or normal liver [90].

For circulating SncRNAs, miRNAs have generated special attention, these are generated in the bloodstream both by active secretion and cell lysis [91]. A given miRNA may regulate gene expression to control several cellular processes, including development, differentiation, metabolism, and cell death; in some cases, specific miRNAs appear to function like oncogenes or tumor suppressor genes [92,93] and in HCC more than 70 miRNAs found in the circulation have been suggested to be useful as biomarkers. Li et al. illustrated that miRNAs serum profiling work as biomarkers to discriminate between HBV infection and HBV-positive HCC [94]. Nakamura et al. showed that the circulating miR-122 level in combination with Wisteria floribunda agglutinin-positive Mac-2 binding protein achieves 47% sensitivity and 87% specificity in detecting advanced fibrosis related to HBV infection [95]. High serum levels of miR-221 have also been linked to tumor size, degree of cirrhosis, and tumor stage in HCC patients [96] (Table 1).

Measurements of miRNAs have also been studied in the context of therapeutic monitoring. Zheng et al. concluded that the serum levels of miR-17-5p could be a prognostic marker for HCC patients past their surgical resection, and Cho et al. showed that patients with HBV-related HCC who underwent radiofrequency ablation (RFA) had low overall survival rates if associated with high plasma miR-122 expression [100,125]. Yamamoto et al. indicated that miR-500 is an oncofetal miRNA found abundantly in the serum of HCC patients, levels return to normal after successful surgery [126]. For unresectable HCC, Liu et al. displayed that miR-200a was an independent prognostic factor linked to survival rate after trans-arterial chemoembolization (TACE) [121]. PTEN, Stathmin1, RUNX3, Rho-kinase 2, Mcl-1, SOX9, FNDC3B, p21/E2F5, VEGF, TP53INP1, ADAM17, ISRE, CDKN1B/p27, CDKN1C/p57, TIMP3, HDAC4, mTOR, and LIN28B have cancer-related functions, certain miRNAs in patients with HCC are targeted by these [98,8,100,102,115,121,127].

In attempts to improve the accuracy of diagnosis, some researchers have measured multiple miRNAs in serum. Zekri et al. could differentiate HCC from healthy, chronic hepatitis B, and cirrhosis by measuring the levels of 7 miRNAs (miR-122, -192, -21, -223, -26a, -27a, and -801) in plasma [100]. More recently, a panel of miR-29b, miR-122, and miR-885 in combination with AFP showed high diagnostic accuracy in detecting HCC within the normal population, while a combination of AFP with miR-22, miR-122, miR-221, and miR-885 was superior at diagnosing of HCC with a background of cirrhosis [128].

In acute liver injury and hepatitis, circulating miRNAs are regulated by intrahepatic oxidative stress, and seem to determine the extent of the damage. miR-122-5p is profusely expressed in hepatocytes and increases in the serum after excessive alcohol intake [129]. Mosedale et al. reported early increases of miR-122-5p are associated with mitochondrial-induced apoptosis and oxidative stress during drug-induced liver injury [130] (Table 2).