Hostname: page-component-cd9895bd7-gvvz8 Total loading time: 0 Render date: 2024-12-22T13:27:31.712Z Has data issue: false hasContentIssue false

Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers

Published online by Cambridge University Press:  19 October 2023

Jingyi Huang
Affiliation:
Department of Urology, Ruijin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai , China
Da Huang
Affiliation:
Department of Urology, Ruijin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai , China
Xiaohao Ruan
Affiliation:
Department of Urology, Ruijin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai , China
Yongle Zhan
Affiliation:
Department of Surgery, School of Clinical Medicine, The University of Hong Kong, Hong Kong, Hong Kong
Stacia T.-T. Chun
Affiliation:
Department of Surgery, School of Clinical Medicine, The University of Hong Kong, Hong Kong, Hong Kong
Ada T.-L. Ng
Affiliation:
Division of Urology, Department of Surgery, Queen Mary Hospital, The University of Hong Kong, Hong Kong, Hong Kong
Rong Na*
Affiliation:
Department of Surgery, School of Clinical Medicine, The University of Hong Kong, Hong Kong, Hong Kong
*
Corresponding author: Rong Na; Email: narong.hs@gmail.com
Rights & Permissions [Opens in a new window]

Abstract

The aim of liquid biopsies is to obtain tumor information via the molecular interrogation of liquid samples, including blood and urine. As a minimally invasive procedure, liquid biopsies have attracted attention. A series of studies have reported associations of biomarkers such as circulating tumor DNA, cell-free DNA and extracellular vesicles with urological cancers, especially prostate cancer (PCa), and demonstrated the promising potential of liquid biopsies. In this review, we summarize recent clinical translational studies of liquid biopsies in PCa and other urological cancers, including bladder cancer and renal cell carcinoma. The number of translational studies was limited, and most of the studies focused on PCa. Biomarkers isolated from blood by different detection methods could be applied in clinical practice to predict prognosis and treatment response in advanced PCa. The other applications in urological cancers identified in previous studies remain to be explored further. Current studies are limited due to the lack of ideal standard detection methods for biomarkers. In the future, with advances in methodology, more translational studies will be conducted to identify potential applications of liquid biopsies in urological cancers.

Topics structure

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

Impact statement

Liquid biopsies have promising potential to ameliorate cancer diagnosis and treatment, whose aim is to obtain tumor information via the molecular interrogation of liquid samples, including blood and urine. As minimally invasive procedures, liquid biopsies have attracted attention. This review summarizes current clinical translational studies of liquid biopsy in PCa and other urological cancers, involving circulating tumor DNA, cell-free DNA and extracellular vesicles. Biomarkers isolated from blood by different detection methods could be applied in clinical practice to predict prognosis and treatment response in advanced PCa. The other applications in urological cancers identified in previous studies remain to be explored further. Current studies are limited due to the lack of ideal standard detection methods for biomarkers, which deserves further exploration.

Introduction

The concept of the liquid biopsy was first raised about 10 years ago when circulating tumor cell (CTC) was introduced (Pantel and Alix-Panabières, Reference Pantel and Alix-Panabières2010). This technique aims to obtain tumor-derived information via the molecular interrogation of liquid samples, including blood, urine and so on (Nikanjam et al., Reference Nikanjam, Kato and Kurzrock2022). With the rapid development of gene detection and cell separation technologies, the potential of liquid biopsies is constantly being explored. The factors detected in liquid biopsies include circulating tumor DNA (ctDNA), cell-free DNA (cfDNA), tumor-educated platelets and extracellular vesicles (EVs) (Nikanjam et al., Reference Nikanjam, Kato and Kurzrock2022).

Compared with traditional tissue biopsies, liquid biopsies are minimally invasive procedures and available at all status of disease. From a pathological point of view, liquid biomarkers provide an evaluation of the entire tumor, while tissue biopsy only involves part of the tumor, which may lead to severe bias due to tumor heterogeneity (Cimadamore et al., Reference Cimadamore, Gasparrini, Massari, Santoni, Cheng, Lopez-Beltran, Scarpelli and Montironi2019). Liquid biopsies are expected to replace some invasive examinations and to be applied at various stages during cancer diagnosis, follow-up and treatment.

For urologic cancers, liquid biopsies have also emerged as a promising strategy, especially for prostate cancer (PCa), bladder cancer (BCa) and renal cell carcinoma (RCC). Several blood and urine biomarkers have been demonstrated to be related to risk or prognosis in PCa (Crocetto et al., Reference Crocetto, Russo, Di Zazzo, Pisapia, Mirto, Palmieri, Pepe, Bellevicine, Russo, La Civita, Terracciano, Malapelle, Troncone and Barone2022b). For example, small RNAs carried in urinary EVs might be useful for PCa diagnosis (Rönnau et al., Reference Rönnau, Verhaegh, Luna-Velez and Schalken2014). Increased CTCs in blood after chemotherapy might be related to poor response to treatment (Zapatero et al., Reference Zapatero, Gómez-Caamaño, Cabeza Rodriguez, Muinelo-Romay, Martin de Vidales, Abalo, Calvo Crespo, Leon Mateos, Olivier and Vega Piris2020). Urinary biomarkers were more comprehensively studied in BCa because of their direct contact with tumor and their isolation from homeostasis (Crocetto et al., Reference Crocetto, Barone, Ferro, Busetto, La Civita, Buonerba, Di Lorenzo, Terracciano and Schalken2022a). A series of markers related to disease outcome have been revealed based on analyses of genetic abnormalities and epigenetic alterations, such as changes in urine DNA methylation, proteomic and mutation profiles (Matuszczak et al., Reference Matuszczak, Kiljańczyk and Salagierski2022). For RCC, both blood and urine biomarkers have been found to be valuable for predicting progression risk and indicating the efficiency of treatment (Li et al., Reference Li, Li, Zheng, Li, Li, Wang and Chen2023).

An increasing number of biomarkers were proposed and discovered as the liquid biopsy concept is getting more and more important in recent years. However, a few of them were actually applied in clinical management due to the lack of translational research evidence to indicate how to use liquid biopsies to ameliorate clinical strategy. Translational research functions as a bridge between basic research and clinical practice (Dragani et al., Reference Dragani, Castells, Kulasingam, Diamandis, Earl, Iams, Lovly, Sedelaar and Schalken2016). To promote the application of liquid biopsies, several translational studies have been carried out in different diseases, such as hepatobiliary cancer, lung cancer and urological cancers (von Felden et al., Reference von Felden, Garcia-Lezana, Schulze, Losic and Villanueva2020; Malapelle et al., Reference Malapelle, Pisapia, Addeo, Arrieta, Bellosillo, Cardona, Cristofanilli, De Miguel-Perez, Denninghoff, Durán, Jantus-Lewintre, Nuzzo, O’Byrne, Pauwels, Pickering, Raez, Russo, Serrano, Gandara, Troncone and Rolfo2021).

In this review, we summarize the present studies regarding the clinical translational researches for the application of liquid biopsies on urological cancers, including PCa, BCa and RCC. We aimed to cover the studies with clinical application potentials. We also delineated challenges and perspectives of future development of translational research for liquid biopsies.

Evidence synthesis

We searched published research articles using the keywords “liquid biopsy”, “translational research” and urological cancers (including “PCa,” “BCa,” and “RCC”) in the PubMed and Embase databases. To refine the search and make it comprehensive, “liquid biopsy” was replaced by “CTC,” “ctDNA,” “cfDNA,” “EV” and “exosome.” A total of 57 results were found. After review of the abstracts and full articles, 10 original research articles that were confirmed to be clinical translational research studies were ultimately included in this review (Table 1). In addition, 13 original research articles reported the translational potential of liquid biopsies.

Table 1. Summary of clinical translational studies of liquid biopsy for PCa

ACCEPT, automated CTC Classification Enumeration and PhenoTyping; cfDNA, cell-free DNA; CTC, circulating tumor cell; ddPCR, droplet digital PCR; EV, extracellular vesicle; mCRPC, metastatic castrate-resistant prostate cancer.

Enumeration and assessment of CTCs

CTCs are cancer cells separated from the primary tumor or metastatic foci. CTCs are rare; at most, one tumor cell can be found in a hundred million cells circulating in the blood (Nelson, Reference Nelson2010). Given the broad range of technologies used to capture CTCs, CTC detection has become more efficient; thus, various clinical translational studies of CTCs have been conducted. Presently, CellSearch (Menarini Silicon Biosystems) is the only clinical CTC enumeration method that has received Food and Drug Administration (FDA) approval (Riethdorf et al., Reference Riethdorf, O’Flaherty, Hille and Pantel2018).

The number of CTCs in blood determined by flow cytometry might predict the prognosis of metastatic castration-resistant prostate cancer (mCRPC). Higher CTC counts were associated with worse radiographic progression-free survival and OS according to the results of translational research (Di Lorenzo et al., Reference Di Lorenzo, Zappavigna, Crocetto, Giuliano, Ribera, Morra, Scafuri, Verde, Bruzzese, Iaccarino, Costabile, Onofrio, Viggiani, Palmieri, De Placido, Marretta, Pietroluongo, Luce, Abate, Navaeiseddighi, Caputo, Celentano, Longo, Ferro, Morelli, Facchini, Caraglia, De Placido and Buonerba2021). Similarly, for patients with mCRPC starting abiraterone acetate or enzalutamide therapy, higher CTCs at baseline and an increase in CTCs at follow-up were independent predictors of worse prognosis (De Laere et al., Reference De Laere, Oeyen, Van Oyen, Ghysel, Ampe, Ost, Demey, Hoekx, Schrijvers, Brouwers, Lybaert, Everaert, Van Kerckhove, De Maeseneer, Strijbos, Bols, Fransis, Beije, de Kruijff, van Dam, Brouwer, van Dam, Van den Eynden, Rutten, Sleijfer, Vandebroek, Van Laere and Dirix2018). A few years later, the same group reanalyzed the previous images using an image analysis tool called the automated CTC Classification Enumeration and PhenoTyping (ACCEPT) tool (Oeyen et al., Reference Oeyen, Liégeois, De Laere, Buys, Strijbos, Dirix and Dirix2021). The results showed that beyond enumeration, high CTC phenotypic heterogeneity was also related to worse survival outcome in mCRPC. With regard to the CTC phenotype, in 2016, Lindsay et al. established a routine for the clinical testing of Ki67 and vimentin expression in CTCs and demonstrated that the presence of Ki67 and vimentin expression in CTCs was related with poor outcome in mCRPC (Lindsay et al., Reference Lindsay, Le Moulec, Billiot, Loriot, Ngo-Camus, Vielh, Fizazi, Massard and Farace2016). Peripheral blood (7.5 mL) from patients with mCRPC was collected and tested for Ki67 and vimentin. The results showed a significant reduction in OS in patients with Ki67- or vimentin-positive CTCs. It is the presence of expression but not the exact number or proportion of Ki67- or vimentin-positive CTCs which was associated with OS. In addition to mCRPC, Mandel et al. focused on oligometastatic hormone-sensitive prostate cancer (HSPC), an earlier stage of PCA. For patients with oligometastatic HSPC who underwent cytoreductive radical prostatectomy, higher CTC numbers both before and 6 months after surgery indicated shorter PFS to CRPC. Interestingly, with regard to the prognostic value, CTC number was a better biomarker than lactate dehydrogenase, prostate-specific antigen (PSA) and bone-specific alkaline phosphatase (Mandel et al., Reference Mandel, Huland, Tiebel, Haese, Salomon, Budäus, Tilki, Chun, Heinzer, Graefen, Pantel, Riethdorf and Steuber2021).

Assessment of CTCs has also been used to predict treatment response. Abiraterone is a novel first-line hormonal therapy, and enzalutamide, an oral second-generation anti-androgen receptor (AR), was shown to be effective for patients with mCRPC before or after chemotherapy. A prospective, multicenter, translational study was conducted and showed that a higher androgen receptor splice variant 7 (AR-V7) positive CTC count in blood predicted a poorer response to enzalutamide (Di Lorenzo et al., Reference Di Lorenzo, Zappavigna, Crocetto, Giuliano, Ribera, Morra, Scafuri, Verde, Bruzzese, Iaccarino, Costabile, Onofrio, Viggiani, Palmieri, De Placido, Marretta, Pietroluongo, Luce, Abate, Navaeiseddighi, Caputo, Celentano, Longo, Ferro, Morelli, Facchini, Caraglia, De Placido and Buonerba2021). Furthermore, Antonarakis et al. (Reference Antonarakis, Lu, Luber, Wang, Chen, Zhu, Silberstein, Taylor, Maughan, Denmeade, Pienta, Paller, Carducci, Eisenberger and Luo2017) categorized samples from 202 patients with mCRPC receiving abiraterone or enzalutamide into three groups: CTC−, CTC+/AR-V7- and CTC+/AR-V7+. It was demonstrated that the treatment response and survival were the best for CTC− patients and the worst for CTC+/AR-V7+ patients.

In addition, the Spanish Oncology Genito-Urinary Group performed a prospective translational study of a cohort of 45 patients with mCRPC who were treated with radium-223 (Carles et al., Reference Carles, Castellano, Méndez-Vidal, Mellado, Saez, González Del Alba, Perez-Gracia, Jimenez, Suárez, Sepúlveda, Manneh, Porras, López, Morales-Barrera and Arranz2018). The results indicated that patients with CTC counts ≤5/7.5 mL before radium-223 treatment responded better and were more likely to continue therapy. Additionally, the survival outcomes were better in patients with few CTC counts.

Few translational studies of CTCs in RCC and BCa exist. It was supposed that the lack of translational evidence about CTC in RCC was probably owing to limitations related to the CTC isolation method. The CellSearch system mentioned above is based on the detection of epithelial cell adhesion molecule (EpCAM) and cytokeratin. However, RCC tumor cells have low EpCAM and low cytokeratin expression. Therefore, the standard methods of CTC detection might not be optimal for RCC (Li et al., Reference Li, Li, Zheng, Li, Li, Wang and Chen2023). Cappelletti et al. (Reference Cappelletti, Verzoni, Ratta, Vismara, Silvestri, Montone, Miodini, Reduzzi, Claps, Sepe, Daidone and Procopio2020) reported an efficient, marker-independent approach that assesses the expression of EpCAM, MUC1 and ERBB2 to detect CTCs in RCC. Although the predictive value of CTCs in RCC was not clear in this study due to the limited sample size, it was confirmed that the existence of CTCs with epithelial markers was correlated with shorter PFS.

Some clinical translational studies have explored CTCs, the first marker derived from liquid biopsies, to identify their predictive effect in urologic cancers. Enumerating CTCs in blood and assessing the expression of certain biomarkers can aid prognosis prediction and the development of personalized therapy in mCRPC and mHSPC. Few studies have illustrated the predictive effect of CTCs in RCC and BCa. Additionally, all the existing studies have used blood.

Cell-free DNA and circulation tumor DNA

Circulating cfDNA molecules are extracellular, short fragments of nucleic acids circulating in body fluids and are approximately 134–144 bp (Lu et al., Reference Lu, Delijani, Mecum and Goldkorn2019). ctDNA is a type of cfDNA derived from tumor cells. The quantity of ctDNA depends on the overall tumor volume. With the development of ddPCR and next-generation sequencing, cfDNA can be very sensitively quantified such that even rare mutations and recently methylated sequences can be identified (Poulet et al., Reference Poulet, Massias and Taly2019). cfDNA detection has potential applications in disease screening, prognostic prediction and evaluation of treatment response.

Similar to CTCs, ctDNAs were explored more in PCa among urological cancers by translational studies. The concentration and fragment size of seminal cfDNA were significantly higher in PCa patients than benign prostate hyperplasia (BPH) patients or healthy controls, which indicated that seminal cfDNA might function as a screening biomarker (Poulet et al., Reference Poulet, Massias and Taly2019). Furthermore, ctDNA could also be used to evaluate the prognosis of castration-resistant prostate cancer (CRPC). An analysis of 663 plasma samples from 140 CRPC patients showed that ctDNA was related to worse survival outcome (Choudhury et al., Reference Choudhury, Werner, Francini, Wei, Ha, Freeman, Rhoades, Reed, Gydush, Rotem, Lo, Taplin, Harshman, Zhang, O’Connor, Stover, Parsons, Getz, Meyerson, Love, Hahn and Adalsteinsson2018). Interestingly, the proportion of ctDNA was positively correlated with PSA and ALP and negatively correlated with hemoglobin. It was reported that methylation of SRD5A2 and CYP11A1 DNA in blood cfDNA was associated with a higher risk of biochemical recurrence in patients with HSPC after radical prostatectomy (Horning et al., Reference Horning, Awe, Wang, Liu, Lai, Wang, Jadhav, Louie, Lin, Kroczak, Chen, Jin, Abboud-Werner, Leach, Hernandez, Thompson, Saranchuk, Drachenberg, Chen, Mai and Huang2015).

Regarding value for predicting therapy response, a prospective translational study was conducted in a cohort of 28 patients with oligometastatic HSPC undergoing stereotactic body radiotherapy (SBRT) (Colosini et al., Reference Colosini, Bernardi, Foroni, Pasinetti, Guerini, Russo, Bresciani, Tomasi, Magrini, Bardoscia and Triggiani2022). Deep targeted cfDNA sequencing analysis revealed the molecular heterogeneity of metastatic PCa and helped to identify the exact characteristics to develop a specific therapeutic strategy. For instance, BRCA1 mutation in ctDNA was associated with SBRT failure.

The application of ctDNAs presented translational potential in clinical management of BCa and RCC. Shallow-depth bisulfite sequencing of urinary cfDNA by methylation deconvolution and analysis of global hypomethylation and copy number aberrations (CNAs) has been proposed as a method to detect BCa, with a sensitivity of 93.5% and a specificity of 95.8% (Cheng et al., Reference Cheng, Jiang, Teoh, Heung, Tam, Sun, Lee, Ni, Chan, Ng, Chan, Chiu and Lo2019). Furthermore, the levels of methylation and CNAs might reflect disease stage. A multiomic urinary cfDNA analysis strategy proposed by Chauhan et al. was also proven to be capable of detecting molecular residual disease of BCa (Chauhan et al., Reference Chauhan, Shiang, Alahi, Sundby, Feng, Gungoren, Nawaf, Chen, Babbra, Harris, Qaium, Hatscher, Antiporda, Brunt, Mayer, Shern, Baumann, Kim, Reimers, Smith and Chaudhuri2023). Additionally, for patients with metastatic clear cell RCC, lower cfDNA levels in the bloodstream were associated with a better response to treatment and longer PFS, but further study is required for confirmation (Del Re et al., Reference Del Re, Crucitta, Paolieri, Cucchiara, Verzoni, Bloise, Ciampi, Mercinelli, Capuano, Sportiello, Martinetti, Procopio, Galli, Porta, Bracarda and Danesi2022).

In summary, cfDNA has broad diagnostic and prognostic utility mainly for PCa and BCa. The sources of liquid samples in studies have varied greatly, including blood, seminal fluid and urine. Additionally, there are many aspects of cfDNA that are worth exploring, such as cfDNA quantity, mutations, and methylation patterns.

Extracellular vesicles and exosomes

EVs are lipid bilayer membrane-enclosed nanometer to micrometer vesicles secreted continuously by almost all mammalian cells into the extracellular space (Théry et al., Reference Théry, Witwer, Aikawa, Alcaraz, Anderson, Andriantsitohaina, Antoniou, Arab, Archer, Atkin-Smith, Ayre, Bach, Bachurski, Baharvand, Balaj, Baldacchino, Bauer, Baxter, Bebawy, Beckham, Bedina Zavec, Benmoussa, Berardi, Bergese, Bielska, Blenkiron, Bobis-Wozowicz, Boilard, Boireau, Bongiovanni, Borràs, Bosch, Boulanger, Breakefield, Breglio, Brennan, Brigstock, Brisson, Broekman, Bromberg, Bryl-Górecka, Buch, Buck, Burger, Busatto, Buschmann, Bussolati, Buzás, Byrd, Camussi, Carter, Caruso, Chamley, Chang, Chen, Chen, Cheng, Chin, Clayton, Clerici, Cocks, Cocucci, Coffey, Cordeiro-da-Silva, Couch, Coumans, Coyle, Crescitelli, Criado, D’Souza-Schorey, Das, Datta Chaudhuri, de Candia, De Santana, De Wever, Del Portillo, Demaret, Deville, Devitt, Dhondt, Di Vizio, Dieterich, Dolo, Dominguez Rubio, Dominici, Dourado, Driedonks, Duarte, Duncan, Eichenberger, Ekström, El Andaloussi, Elie-Caille, Erdbrügger, Falcón-Pérez, Fatima, Fish, Flores-Bellver, Försönits, Frelet-Barrand, Fricke, Fuhrmann, Gabrielsson, Gámez-Valero, Gardiner, Gärtner, Gaudin, Gho, Giebel, Gilbert, Gimona, Giusti, Goberdhan, Görgens, Gorski, Greening, Gross, Gualerzi, Gupta, Gustafson, Handberg, Haraszti, Harrison, Hegyesi, Hendrix, Hill, Hochberg, Hoffmann, Holder, Holthofer, Hosseinkhani, Hu, Huang, Huber, Hunt, Ibrahim, Ikezu, Inal, Isin, Ivanova, Jackson, Jacobsen, Jay, Jayachandran, Jenster, Jiang, Johnson, Jones, Jong, Jovanovic-Talisman, Jung, Kalluri, Kano, Kaur, Kawamura, Keller, Khamari, Khomyakova, Khvorova, Kierulf, Kim, Kislinger, Klingeborn, Klinke, Kornek, Kosanović, Kovács Á, Krämer-Albers, Krasemann, Krause, Kurochkin, Kusuma, Kuypers, Laitinen, Langevin, Languino, Lannigan, Lässer, Laurent, Lavieu, Lázaro-Ibáñez, Le Lay, Lee, Lee, Lemos, Lenassi, Leszczynska, Li, Liao, Libregts, Ligeti, Lim, Lim, Linē, Linnemannstöns, Llorente, Lombard, Lorenowicz, Lörincz Á, Lötvall, Lovett, Lowry, Loyer, Lu, Lukomska, Lunavat, Maas, Malhi, Marcilla, Mariani, Mariscal, Martens-Uzunova, Martin-Jaular, Martinez, Martins, Mathieu, Mathivanan, Maugeri, McGinnis, McVey, Meckes, Meehan, Mertens, Minciacchi, Möller, Møller Jørgensen, Morales-Kastresana, Morhayim, Mullier, Muraca, Musante, Mussack, Muth, Myburgh, Najrana, Nawaz, Nazarenko, Nejsum, Neri, Neri, Nieuwland, Nimrichter, Nolan, Nolte-’t Hoen, Noren Hooten, O’Driscoll, O’Grady, O’Loghlen, Ochiya, Olivier, Ortiz, Ortiz, Osteikoetxea, Østergaard, Ostrowski, Park, Pegtel, Peinado, Perut, Pfaffl, Phinney, Pieters, Pink, Pisetsky, Pogge von Strandmann, Polakovicova, Poon, Powell, Prada, Pulliam, Quesenberry, Radeghieri, Raffai, Raimondo, Rak, Ramirez, Raposo, Rayyan, Regev-Rudzki, Ricklefs, Robbins, Roberts, Rodrigues, Rohde, Rome, Rouschop, Rughetti, Russell, Saá, Sahoo, Salas-Huenuleo, Sánchez, Saugstad, Saul, Schiffelers, Schneider, Schøyen, Scott, Shahaj, Sharma, Shatnyeva, Shekari, Shelke, Shetty, Shiba, Siljander, Silva, Skowronek, Snyder, Soares, Sódar, Soekmadji, Sotillo, Stahl, Stoorvogel, Stott, Strasser, Swift, Tahara, Tewari, Timms, Tiwari, Tixeira, Tkach, Toh, Tomasini, Torrecilhas, Tosar, Toxavidis, Urbanelli, Vader, van Balkom, van der Grein, Van Deun, van Herwijnen, Van Keuren-Jensen, van Niel, van Royen, van Wijnen, Vasconcelos, Vechetti, Veit, Vella, Velot, Verweij, Vestad, Viñas, Visnovitz, Vukman, Wahlgren, Watson, Wauben, Weaver, Webber, Weber, Wehman, Weiss, Welsh, Wendt, Wheelock, Wiener, Witte, Wolfram, Xagorari, Xander, Xu, Yan, Yáñez-Mó, Yin, Yuana, Zappulli, Zarubova, Žėkas, Zhang, Zhao, Zheng, Zheutlin, Zickler, Zimmermann, Zivkovic, Zocco, Zuba-Surma and Zuba-Surma2018). They were first regarded as a means for cells to release waste. However, it was proven that EVs play an important role in intracellular communication. EVs are very heterogeneous in terms of size and characteristics, with various sizes, methods of biogenesis, origins, biological characteristics and release mechanisms. Exosomes are the most commonly studied subgroup of EVs of endocytic origin, and they range in size from 30 to 100 nm (Becker et al., Reference Becker, Thakur, Weiss, Kim, Peinado and Lyden2016), while oncosomes, as larger vesicles, can be up to 10 μm in diameter. EVs exist in different biological fluids, such as serum, plasma, urine and saliva, with various cargos, such as DNA, RNA, proteins and lipids. MicroRNAs (miRNAs) are the most frequent cargo. Tumor cells were found to release more EVs than other cells (Li et al., Reference Li, Lin, Jiang and Yu2018). Recently, EVs, especially exosomes, have been proven to contain tumor information and function in the progression and metastasis of cancer (Casanova-Salas et al., Reference Casanova-Salas, Athie, Boutros, Del Re, Miyamoto, Pienta, Posadas, Sowalsky, Stenzl, Wyatt and Mateo2021). The potential of EVs as diagnostic and prognostic markers has attracted much attention.

Centrifugation-based approaches are applied to isolate EVs, and ultracentrifugation is considered the standard method (Théry et al., Reference Théry, Witwer, Aikawa, Alcaraz, Anderson, Andriantsitohaina, Antoniou, Arab, Archer, Atkin-Smith, Ayre, Bach, Bachurski, Baharvand, Balaj, Baldacchino, Bauer, Baxter, Bebawy, Beckham, Bedina Zavec, Benmoussa, Berardi, Bergese, Bielska, Blenkiron, Bobis-Wozowicz, Boilard, Boireau, Bongiovanni, Borràs, Bosch, Boulanger, Breakefield, Breglio, Brennan, Brigstock, Brisson, Broekman, Bromberg, Bryl-Górecka, Buch, Buck, Burger, Busatto, Buschmann, Bussolati, Buzás, Byrd, Camussi, Carter, Caruso, Chamley, Chang, Chen, Chen, Cheng, Chin, Clayton, Clerici, Cocks, Cocucci, Coffey, Cordeiro-da-Silva, Couch, Coumans, Coyle, Crescitelli, Criado, D’Souza-Schorey, Das, Datta Chaudhuri, de Candia, De Santana, De Wever, Del Portillo, Demaret, Deville, Devitt, Dhondt, Di Vizio, Dieterich, Dolo, Dominguez Rubio, Dominici, Dourado, Driedonks, Duarte, Duncan, Eichenberger, Ekström, El Andaloussi, Elie-Caille, Erdbrügger, Falcón-Pérez, Fatima, Fish, Flores-Bellver, Försönits, Frelet-Barrand, Fricke, Fuhrmann, Gabrielsson, Gámez-Valero, Gardiner, Gärtner, Gaudin, Gho, Giebel, Gilbert, Gimona, Giusti, Goberdhan, Görgens, Gorski, Greening, Gross, Gualerzi, Gupta, Gustafson, Handberg, Haraszti, Harrison, Hegyesi, Hendrix, Hill, Hochberg, Hoffmann, Holder, Holthofer, Hosseinkhani, Hu, Huang, Huber, Hunt, Ibrahim, Ikezu, Inal, Isin, Ivanova, Jackson, Jacobsen, Jay, Jayachandran, Jenster, Jiang, Johnson, Jones, Jong, Jovanovic-Talisman, Jung, Kalluri, Kano, Kaur, Kawamura, Keller, Khamari, Khomyakova, Khvorova, Kierulf, Kim, Kislinger, Klingeborn, Klinke, Kornek, Kosanović, Kovács Á, Krämer-Albers, Krasemann, Krause, Kurochkin, Kusuma, Kuypers, Laitinen, Langevin, Languino, Lannigan, Lässer, Laurent, Lavieu, Lázaro-Ibáñez, Le Lay, Lee, Lee, Lemos, Lenassi, Leszczynska, Li, Liao, Libregts, Ligeti, Lim, Lim, Linē, Linnemannstöns, Llorente, Lombard, Lorenowicz, Lörincz Á, Lötvall, Lovett, Lowry, Loyer, Lu, Lukomska, Lunavat, Maas, Malhi, Marcilla, Mariani, Mariscal, Martens-Uzunova, Martin-Jaular, Martinez, Martins, Mathieu, Mathivanan, Maugeri, McGinnis, McVey, Meckes, Meehan, Mertens, Minciacchi, Möller, Møller Jørgensen, Morales-Kastresana, Morhayim, Mullier, Muraca, Musante, Mussack, Muth, Myburgh, Najrana, Nawaz, Nazarenko, Nejsum, Neri, Neri, Nieuwland, Nimrichter, Nolan, Nolte-’t Hoen, Noren Hooten, O’Driscoll, O’Grady, O’Loghlen, Ochiya, Olivier, Ortiz, Ortiz, Osteikoetxea, Østergaard, Ostrowski, Park, Pegtel, Peinado, Perut, Pfaffl, Phinney, Pieters, Pink, Pisetsky, Pogge von Strandmann, Polakovicova, Poon, Powell, Prada, Pulliam, Quesenberry, Radeghieri, Raffai, Raimondo, Rak, Ramirez, Raposo, Rayyan, Regev-Rudzki, Ricklefs, Robbins, Roberts, Rodrigues, Rohde, Rome, Rouschop, Rughetti, Russell, Saá, Sahoo, Salas-Huenuleo, Sánchez, Saugstad, Saul, Schiffelers, Schneider, Schøyen, Scott, Shahaj, Sharma, Shatnyeva, Shekari, Shelke, Shetty, Shiba, Siljander, Silva, Skowronek, Snyder, Soares, Sódar, Soekmadji, Sotillo, Stahl, Stoorvogel, Stott, Strasser, Swift, Tahara, Tewari, Timms, Tiwari, Tixeira, Tkach, Toh, Tomasini, Torrecilhas, Tosar, Toxavidis, Urbanelli, Vader, van Balkom, van der Grein, Van Deun, van Herwijnen, Van Keuren-Jensen, van Niel, van Royen, van Wijnen, Vasconcelos, Vechetti, Veit, Vella, Velot, Verweij, Vestad, Viñas, Visnovitz, Vukman, Wahlgren, Watson, Wauben, Weaver, Webber, Weber, Wehman, Weiss, Welsh, Wendt, Wheelock, Wiener, Witte, Wolfram, Xagorari, Xander, Xu, Yan, Yáñez-Mó, Yin, Yuana, Zappulli, Zarubova, Žėkas, Zhang, Zhao, Zheng, Zheutlin, Zickler, Zimmermann, Zivkovic, Zocco, Zuba-Surma and Zuba-Surma2018). However, the efficiency is disagreeable due to its low throughput and poor specificity (Gerdtsson et al., Reference Gerdtsson, Setayesh, Malihi, Ruiz, Carlsson, Nevarez, Matsumoto, Gerdtsson, Zurita, Logothetis, Corn, Aparicio, Hicks and Kuhn2021). To improve the efficiency and specificity, several methods have been explored for the detection and characterization of EVs.

Three translational studies on the use of exosomes in PCa were identified with the present search strategy. Each of the studies developed EV measurement methods. Kim et al. (Reference Kim, van der Pol, Arafa, Thapa, Britton, Kosti, Song, Joshi, R, Ali and Lucien2022) first proposed a systematic method using standardized and calibrated flow cytometry for the quantification of PCa-derived EVs from blood and urine with detailed methodologies, instrument characteristics and acquisition settings. Their study validated the effectiveness of this method and demonstrated that PSMA+ EVs and STEAP+ EVs might be surrogate markers for metastatic PCa. Reverse-phase protein microarrays, as an antibody-based proteomic technology, have also been applied to analyze EV cargo and were used to identify a series of potential biomarkers for EV-based PCa diagnosis, such as PD-1 and survivin (Signore et al., Reference Signore, Alfonsi, Federici, Nanni, Addario, Bertuccini, Simone, Costantini, Crinò, Rossi, Tabolacci, Diociaiuti, Merlino, Gallucci, Sentinelli, Papalia, De Maria and Bonci2021). The last translational study was mentioned in the CTC section. When Oeyen et al. (Reference Oeyen, Liégeois, De Laere, Buys, Strijbos, Dirix and Dirix2021) reanalyzed CellSearch images of patients with mCRPC with ACCEPT software, EVs were efficiently detected as well. It was demonstrated that a higher baseline EV level was associated with shorter PFS of patient with mCRPC, which is in line with the prognostic value of CTCs.

In addition to the translational studies mentioned above, evidence from a number of nonexplicit translational studies was reviewed, also supporting the translational value of EVs and exosomes. As early as 2012, the prognostic value of exosomes in PCa was explored. After isolation by centrifugation, the number of plasma exosomes in PCa patients was significantly higher than that in BPH patients or healthy controls. Survivin is an inhibitor of apoptosis family proteins that is associated with PCa development, and exosomal survivin was also found to be higher in PCa plasma. No difference was observed between patients with PCa with high and low Gleason scores (Khan et al., Reference Khan, Jutzy, Valenzuela, Turay, Aspe, Ashok, Mirshahidi, Mercola, Lilly and Wall2012) However, the number of plasma prostate microparticles, a kind of EV, could identify PCa patients with Gleason score ≥ 4 + 4 by nanoscale flow cytometry (Biggs et al., Reference Biggs, Siddiqui, Al-Zahrani, Pardhan, Brett, Guo, Yang, Wolf, Power, Durfee, MacMillan, Townson, Brinker, Fleshner, Izawa, Chambers, Chin and Leong2016). In addition to their screening value, EVs might also serve as prognostic biomarkers. Two blood-based exosomal miRNAs (miR-1290 and miR-375) were identified as biomarkers that could predict the prognosis of mCRPC (Huang et al., Reference Huang, Yuan, Liang, Du, Xia, Dittmar, Wang, See, Costello, Quevedo, Tan, Nandy, Bevan, Longenbach, Sun, Lu, Wang, Thibodeau, Boardman, Kohli and Wang2015). In addition, significant alteration of exosomal miRNA and protein cargos was observed as neuroendocrine differentiation occurred in PCa, and neuroendocrine prostate cancer has poor survival outcomes with limited treatment options (Bhagirath et al., Reference Bhagirath, Liston, Akoto, Lui, Bensing, Sharma and Saini2021). With regard to value for predicting treatment response, AR-V7 carried in blood exosomes could serve as a reliable biomarker of resistance to hormonal therapy (Del Re et al., Reference Del Re, Biasco, Crucitta, Derosa, Rofi, Orlandini, Miccoli, Galli, Falcone, Jenster, van Schaik and Danesi2017).

Few definite translational studies have focused on EVs in BCa or RCC, though EVs have translational value for these two cancers (Zeuschner et al., Reference Zeuschner, Linxweiler and Junker2020). For example, exosomal miR-1233 and miR-210 in blood were significantly increased in RCC patients compared with healthy controls (Zhang et al., Reference Zhang, Ni, Su, Wang, Zhu, Zhao and Li2018). Regarding the prognosis of RCC, higher miR-224 levels in serum EVs were related to poorer survival outcomes (Du et al., Reference Du, Giridhar, Tian, Tschannen, Zhu, Huang, Kilari, Kohli and Wang2017). For BCa, different studies showed that a series of long noncoding RNAs were increased in urinary EVs of BCa patients compared with healthy controls (Zhan et al., Reference Zhan, Du, Wang, Jiang, Zhang, Li, Yan, Duan, Zhao, Wang, Wang and Wang2018; Xue et al., Reference Xue, Chen and Li2021), while several cargo molecules in blood EVs, such as LNMAT2, could predict the prognosis of advanced BCa (Becker et al., Reference Becker, Thakur, Weiss, Kim, Peinado and Lyden2016).

In summary, EVs and exosomes have been well studied and shown to have strong translational potential for screening and predicting outcome. However, to date, a standard methodology with high efficiency and sensitivity to detect EVs is still lacking.

Perspective and future directions

In the past decade, a variety of studies have revealed the association between the development of urological cancer and factors detected in liquid biopsies, including CTCs, cfDNA and EVs. Undoubtedly, liquid biopsies can be used to detect promising biomarkers that can be applied for disease diagnosis and prognosis and treatment response prediction in PCa and other urological cancers. Currently, traditional tissue biopsy is still the gold standard for disease diagnosis and serves to guide the therapy strategy. Compared with tissue biopsies, liquid biopsies have their own advantages. First, due to tumor heterogeneity, tissue biopsies may not reflect the comprehensive situation of the disease, while liquid biopsies can help to provide a general assessment. Second, with advances in clinical practice, it is important to avoid unnecessary invasive procedures. The application of liquid biopsies may greatly reduce the number of invasive biopsies. For example, because of the limited specificity of PSA as a screening biomarker for PCa, some patients undergo unnecessary prostate biopsy (Duffy, Reference Duffy2020). The clinical application of liquid biopsies when appropriate would efficiently ameliorate this situation. Second, the liquid biopsy is a minimally invasive procedure with a relatively rapid and simple process, making it a better option for patients. Liquid biopsies are also generally less of an economic and socioeconomic burden than tissue biopsies. Third, liquid biopsies can be performed at all stages and thus can be used to stratify patients after radical surgery. Dynamic assessment of liquid biomarkers can be used to guide long-term clinical decisions.

Clinical translational studies function as a bridge between basic studies and clinical use, providing supporting evidence and directing actual application. We reviewed clinical translational studies of liquid biopsies in PCa, BCa and RCC. As the most frequent urological cancer, PCa has received the most attention. In PCa, CTCs and cfDNA from blood have been shown to be able to predict survival outcome and therapy response in CRPC and metastatic HSPC. Interestingly, most studies on CTCs have used the CellSearch platform, which was approved by the FDA as a method to detect CTCs, while two translational studies on cfDNA employed different methods for detection. Studies of EVs have used various detection methods.

To date, the number of specific clinical translational studies is limited and further exploration is warranted. The lack of an ideal standard method for the isolation of targeted biomarkers is one of the main reasons for the limited performance in relevant translational studies. As mentioned above, the CellSearch system is an FDA-approved method for detecting CTCs. However, it is expensive and not suitable for certain cancers, such as RCC (Li et al., Reference Li, Li, Zheng, Li, Li, Wang and Chen2023). With regard to cfDNA and EVs, there is also no standardized method. Without a standardized detection protocol, it is difficult to assess the true utility of liquid biopsies and to apply relevant strategies in the clinic. Therefore, it is essential to explore standardized methods and comprehensive protocols for the identification of different biomarkers. In addition, recent translational research has not explored the utility of liquid biopsy analysis for the selection of therapy. For example, the expression of AR-V7 in blood CTCs or EVs was found to be associated with resistance to second-generation anti-androgen receptor and hormone therapy (Del Re et al., Reference Del Re, Biasco, Crucitta, Derosa, Rofi, Orlandini, Miccoli, Galli, Falcone, Jenster, van Schaik and Danesi2017; Oeyen et al., Reference Oeyen, Liégeois, De Laere, Buys, Strijbos, Dirix and Dirix2021). Therefore, it remains to be determined whether the expression of AR-V7 can guide the selection of second-generation anti-androgen receptor therapy or chemotherapy. Finally, there is still plenty of potential for translational research on liquid biopsies. Recent translational studies have focused on biomarkers in blood, while other fluid biomarkers may also be valuable. Seminal cfDNA levels are much higher (almost 100 times higher) than blood cfDNA levels in PCa patients (Ponti et al., Reference Ponti, Maccaferri, Percesepe, Tomasi and Ozben2021). Urinary biomarkers might have potential in BCa because they have direct contact with tumors.

Conclusion

The strong potential of liquid biopsy factors, including CTCs, cfDNA and EVs, in urological cancer, especially PCa, has been proven by a series of clinical translational studies. As assessed by different detection methods, biomarkers isolated from blood can be applied in clinical practice to predict prognosis and treatment response in advanced PCa. Other applications of liquid biopsies in urological cancers remain to be further explored based on the results of previous studies.

Open peer review

To view the open peer review materials for this article, please visit http://doi.org/10.1017/pcm.2023.19.

Author contribution

Conception and design: R.N., D.H., J.H., S.T.-T.C., A.T.-L.N.; Literature review: J.H., D.H., X.R. Y.Z.; Manuscript writing: R.N., J.H., D.H., X.R.

Competing interest

The authors declare none.

References

Antonarakis, ES, Lu, C, Luber, B, Wang, H, Chen, Y, Zhu, Y, Silberstein, JL, Taylor, M, Maughan, BL, Denmeade, SR, Pienta, KJ, Paller, CJ, Carducci, MA, Eisenberger, MA and Luo, J (2017) Clinical significance of androgen receptor splice variant-7 mRNA detection in circulating tumor cells of men with metastatic castration-resistant prostate cancer treated with first- and second-line abiraterone and enzalutamide. Journal of Clinical Oncology 35, 21492156.CrossRefGoogle ScholarPubMed
Becker, A, Thakur, BK, Weiss, JM, Kim, HS, Peinado, H and Lyden, D (2016) Extracellular vesicles in cancer: Cell-to-cell mediators of metastasis. Cancer Cell 30, 836848.CrossRefGoogle ScholarPubMed
Bhagirath, D, Liston, M, Akoto, T, Lui, B, Bensing, BA, Sharma, A and Saini, S (2021) Novel, non-invasive markers for detecting therapy induced neuroendocrine differentiation in castration-resistant prostate cancer patients. Scientific Reports 11, 8279.CrossRefGoogle ScholarPubMed
Biggs, CN, Siddiqui, KM, Al-Zahrani, AA, Pardhan, S, Brett, SI, Guo, QQ, Yang, J, Wolf, P, Power, NE, Durfee, PN, MacMillan, CD, Townson, JL, Brinker, JC, Fleshner, NE, Izawa, JI, Chambers, AF, Chin, JL and Leong, HS (2016) Prostate extracellular vesicles in patient plasma as a liquid biopsy platform for prostate cancer using nanoscale flow cytometry. Oncotarget 7, 88398849.CrossRefGoogle ScholarPubMed
Cappelletti, V, Verzoni, E, Ratta, R, Vismara, M, Silvestri, M, Montone, R, Miodini, P, Reduzzi, C, Claps, M, Sepe, P, Daidone, MG and Procopio, G (2020) Analysis of single circulating tumor cells in renal cell carcinoma reveals phenotypic heterogeneity and genomic alterations related to progression. International Journal of Molecular Sciences 21, 1475.CrossRefGoogle ScholarPubMed
Carles, J, Castellano, D, Méndez-Vidal, MJ, Mellado, B, Saez, MI, González Del Alba, A, Perez-Gracia, JL, Jimenez, J, Suárez, C, Sepúlveda, JM, Manneh, R, Porras, I, López, C, Morales-Barrera, R and Arranz, J (2018) Circulating tumor cells as a biomarker of survival and response to Radium-223 therapy: Experience in a cohort of patients with metastatic castration-resistant prostate Cancer. Clinical Genitourinary Cancer 16, e1133e1139.CrossRefGoogle Scholar
Casanova-Salas, I, Athie, A, Boutros, PC, Del Re, M, Miyamoto, DT, Pienta, KJ, Posadas, EM, Sowalsky, AG, Stenzl, A, Wyatt, AW and Mateo, J (2021) Quantitative and qualitative analysis of blood-based liquid biopsies to inform clinical decision-making in prostate cancer. European Urology 79, 762771.CrossRefGoogle ScholarPubMed
Chauhan, PS, Shiang, A, Alahi, I, Sundby, RT, Feng, W, Gungoren, B, Nawaf, C, Chen, K, Babbra, RK, Harris, PK, Qaium, F, Hatscher, C, Antiporda, A, Brunt, L, Mayer, LR, Shern, JF, Baumann, BC, Kim, EH, Reimers, MA, Smith, ZL and Chaudhuri, AA (2023) Urine cell-free DNA multi-omics to detect MRD and predict survival in bladder cancer patients. NPJ Precision Oncology 7, 6.CrossRefGoogle ScholarPubMed
Cheng, THT, Jiang, P, Teoh, JYC, Heung, MMS, Tam, JCW, Sun, X, Lee, WS, Ni, M, Chan, RCK, Ng, CF, Chan, KCA, Chiu, RWK and Lo, YMD (2019) Noninvasive detection of bladder cancer by shallow-depth genome-wide bisulfite sequencing of urinary cell-free DNA for methylation and copy number profiling. Clinical Chemistry 65, 927936.CrossRefGoogle ScholarPubMed
Choudhury, AD, Werner, L, Francini, E, Wei, XX, Ha, G, Freeman, SS, Rhoades, J, Reed, SC, Gydush, G, Rotem, D, Lo, C, Taplin, ME, Harshman, LC, Zhang, Z, O’Connor, EP, Stover, DG, Parsons, HA, Getz, G, Meyerson, M, Love, JC, Hahn, WC and Adalsteinsson, VA (2018) Tumor fraction in cell-free DNA as a biomarker in prostate cancer. JCI Insight 3, e122109.CrossRefGoogle ScholarPubMed
Cimadamore, A, Gasparrini, S, Massari, F, Santoni, M, Cheng, L, Lopez-Beltran, A, Scarpelli, M and Montironi, R (2019) Emerging molecular technologies in renal cell carcinoma: Liquid biopsy. Cancers (Basel) 11, 196.CrossRefGoogle ScholarPubMed
Colosini, A, Bernardi, S, Foroni, C, Pasinetti, N, Guerini, AE, Russo, D, Bresciani, R, Tomasi, C, Magrini, SM, Bardoscia, L and Triggiani, L (2022) Stratification of oligometastatic prostate cancer patients by liquid biopsy: Clinical insights from a pilot study. Biomedicine 10, 1321.Google ScholarPubMed
Crocetto, F, Barone, B, Ferro, M, Busetto, GM, La Civita, E, Buonerba, C, Di Lorenzo, G, Terracciano, D and Schalken, JA (2022a) Liquid biopsy in bladder cancer: State of the art and future perspectives. Critical Reviews in Oncology/Hematology 170, 103577.CrossRefGoogle ScholarPubMed
Crocetto, F, Russo, G, Di Zazzo, E, Pisapia, P, Mirto, BF, Palmieri, A, Pepe, F, Bellevicine, C, Russo, A, La Civita, E, Terracciano, D, Malapelle, U, Troncone, G and Barone, B (2022b) Liquid biopsy in prostate cancer management-current challenges and future perspectives. Cancers (Basel) 14, 3272.CrossRefGoogle ScholarPubMed
De Laere, B, Oeyen, S, Van Oyen, P, Ghysel, C, Ampe, J, Ost, P, Demey, W, Hoekx, L, Schrijvers, D, Brouwers, B, Lybaert, W, Everaert, E, Van Kerckhove, P, De Maeseneer, D, Strijbos, M, Bols, A, Fransis, K, Beije, N, de Kruijff, I, van Dam, V, Brouwer, A, van Dam, PJ, Van den Eynden, G, Rutten, A, Sleijfer, S, Vandebroek, J, Van Laere, S and Dirix, L (2018) Circulating tumor cells and survival in abiraterone- and enzalutamide-treated patients with castration-resistant prostate cancer. Prostate 78, 435445.CrossRefGoogle ScholarPubMed
Del Re, M, Biasco, E, Crucitta, S, Derosa, L, Rofi, E, Orlandini, C, Miccoli, M, Galli, L, Falcone, A, Jenster, GW, van Schaik, RH and Danesi, R (2017) The detection of androgen receptor splice variant 7 in plasma-derived exosomal RNA strongly predicts resistance to hormonal therapy in metastatic prostate cancer patients. European Urology 71, 680687.CrossRefGoogle ScholarPubMed
Del Re, M, Crucitta, S, Paolieri, F, Cucchiara, F, Verzoni, E, Bloise, F, Ciampi, R, Mercinelli, C, Capuano, A, Sportiello, L, Martinetti, A, Procopio, G, Galli, L, Porta, C, Bracarda, S and Danesi, R (2022) The amount of DNA combined with TP53 mutations in liquid biopsy is associated with clinical outcome of renal cancer patients treated with immunotherapy and VEGFR-TKIs. Journal of Translational Medicine 20, 371.CrossRefGoogle ScholarPubMed
Di Lorenzo, G, Zappavigna, S, Crocetto, F, Giuliano, M, Ribera, D, Morra, R, Scafuri, L, Verde, A, Bruzzese, D, Iaccarino, S, Costabile, F, Onofrio, L, Viggiani, M, Palmieri, A, De Placido, P, Marretta, AL, Pietroluongo, E, Luce, A, Abate, M, Navaeiseddighi, Z, Caputo, VF, Celentano, G, Longo, N, Ferro, M, Morelli, F, Facchini, G, Caraglia, M, De Placido, S and Buonerba, C (2021) Assessment of total, PTEN(−), and AR-V7(+) circulating tumor cell count by flow cytometry in patients with metastatic castration-resistant prostate cancer receiving enzalutamide. Clinical Genitourinary Cancer 19, e286e298.CrossRefGoogle ScholarPubMed
Dragani, TA, Castells, A, Kulasingam, V, Diamandis, EP, Earl, H, Iams, WT, Lovly, CM, Sedelaar, JP and Schalken, JA (2016) Major milestones in translational oncology. BMC Medicine 14, 110.CrossRefGoogle ScholarPubMed
Du, M, Giridhar, KV, Tian, Y, Tschannen, MR, Zhu, J, Huang, CC, Kilari, D, Kohli, M and Wang, L (2017) Plasma exosomal miRNAs-based prognosis in metastatic kidney cancer. Oncotarget 8, 6370363714.CrossRefGoogle ScholarPubMed
Duffy, MJ (2020) Biomarkers for prostate cancer: Prostate-specific antigen and beyond. Clinical Chemistry and Laboratory Medicine 58, 326339.CrossRefGoogle ScholarPubMed
Gerdtsson, AS, Setayesh, SM, Malihi, PD, Ruiz, C, Carlsson, A, Nevarez, R, Matsumoto, N, Gerdtsson, E, Zurita, A, Logothetis, C, Corn, PG, Aparicio, AM, Hicks, J and Kuhn, P (2021) Large extracellular vesicle characterization and association with circulating tumor cells in metastatic castrate resistant prostate cancer. Cancers (Basel) 13, 1056.CrossRefGoogle ScholarPubMed
Horning, AM, Awe, JA, Wang, CM, Liu, J, Lai, Z, Wang, VY, Jadhav, RR, Louie, AD, Lin, CL, Kroczak, T, Chen, Y, Jin, VX, Abboud-Werner, SL, Leach, RJ, Hernandez, J, Thompson, IM, Saranchuk, J, Drachenberg, D, Chen, CL, Mai, S and Huang, TH (2015) DNA methylation screening of primary prostate tumors identifies SRD5A2 and CYP11A1 as candidate markers for assessing risk of biochemical recurrence. Prostate 75, 17901801.CrossRefGoogle ScholarPubMed
Huang, X, Yuan, T, Liang, M, Du, M, Xia, S, Dittmar, R, Wang, D, See, W, Costello, BA, Quevedo, F, Tan, W, Nandy, D, Bevan, GH, Longenbach, S, Sun, Z, Lu, Y, Wang, T, Thibodeau, SN, Boardman, L, Kohli, M and Wang, L (2015) Exosomal miR-1290 and miR-375 as prognostic markers in castration-resistant prostate cancer. European Urology 67, 3341.CrossRefGoogle ScholarPubMed
Khan, S, Jutzy, JM, Valenzuela, MM, Turay, D, Aspe, JR, Ashok, A, Mirshahidi, S, Mercola, D, Lilly, MB and Wall, NR (2012) Plasma-derived exosomal survivin, a plausible biomarker for early detection of prostate cancer. PLoS One 7, e46737.CrossRefGoogle ScholarPubMed
Kim, Y, van der Pol, E, Arafa, A, Thapa, I, Britton, CJ , Kosti, J, Song, S, Joshi, VB, R, ME, Ali, H and Lucien, F (2022) Calibration and standardization of extracellular vesicle measurements by flow cytometry for translational prostate cancer research. Nanoscale 14, 97819795.CrossRefGoogle ScholarPubMed
Li, M, Li, L, Zheng, J, Li, Z, Li, S, Wang, K and Chen, X (2023) Liquid biopsy at the frontier in renal cell carcinoma: Recent analysis of techniques and clinical application. Molecular Cancer 22, 37.CrossRefGoogle ScholarPubMed
Li, SP, Lin, ZX, Jiang, XY and Yu, XY (2018) Exosomal cargo-loading and synthetic exosome-mimics as potential therapeutic tools. Acta Pharmacologica Sinica 39, 542551.CrossRefGoogle ScholarPubMed
Lindsay, CR, Le Moulec, S, Billiot, F, Loriot, Y, Ngo-Camus, M, Vielh, P, Fizazi, K, Massard, C and Farace, F (2016) Vimentin and Ki67 expression in circulating tumour cells derived from castrate-resistant prostate cancer. BMC Cancer 16, 168.CrossRefGoogle ScholarPubMed
Lu, YT, Delijani, K, Mecum, A and Goldkorn, A (2019) Current status of liquid biopsies for the detection and management of prostate cancer. Cancer Management and Research 11, 52715291.CrossRefGoogle ScholarPubMed
Malapelle, U, Pisapia, P, Addeo, A, Arrieta, O, Bellosillo, B, Cardona, AF, Cristofanilli, M, De Miguel-Perez, D, Denninghoff, V, Durán, I, Jantus-Lewintre, E, Nuzzo, PV, O’Byrne, K, Pauwels, P, Pickering, EM, Raez, LE, Russo, A, Serrano, MJ, Gandara, DR, Troncone, G and Rolfo, C (2021) Liquid biopsy from research to clinical practice: Focus on non-small cell lung cancer. Expert Review of Molecular Diagnostics 21, 11651178.CrossRefGoogle ScholarPubMed
Mandel, PC, Huland, H, Tiebel, A, Haese, A, Salomon, G, Budäus, L, Tilki, D, Chun, F, Heinzer, H, Graefen, M, Pantel, K, Riethdorf, S and Steuber, T (2021) Enumeration and changes in circulating tumor cells and their prognostic value in patients undergoing cytoreductive radical prostatectomy for oigometastatic prostate cancer-translational research results from the prospective ProMPT trial. European Urology Focus 7, 5562.CrossRefGoogle ScholarPubMed
Matuszczak, M, Kiljańczyk, A and Salagierski, M (2022) A liquid biopsy in bladder cancer-the current landscape in urinary biomarkers. International Journal of Molecular Sciences 23, 8597.CrossRefGoogle ScholarPubMed
Nelson, NJ (2010) Circulating tumor cells: Will they be clinically useful? Journal of the National Cancer Institute 102, 146148.CrossRefGoogle ScholarPubMed
Nikanjam, M, Kato, S and Kurzrock, R (2022) Liquid biopsy: Current technology and clinical applications. Journal of Hematology & Oncology 15, 131.CrossRefGoogle ScholarPubMed
Oeyen, S, Liégeois, V, De Laere, B, Buys, A, Strijbos, M, Dirix, P, and Dirix, L (2021) Automated enumeration and phenotypic characterization of CTCs and tdEVs in patients with metastatic castration resistant prostate cancer. Prostate Cancer and Prostatic Diseases 24, 499506.CrossRefGoogle ScholarPubMed
Pantel, K and Alix-Panabières, C (2010) Circulating tumour cells in cancer patients: Challenges and perspectives. Trends in Molecular Medicine 16, 398406.CrossRefGoogle ScholarPubMed
Ponti, G, Maccaferri, M, Percesepe, A, Tomasi, A and Ozben, T (2021) Liquid biopsy with cell free DNA: New horizons for prostate cancer. Critical Reviews in Clinical Laboratory Sciences 58, 6076.CrossRefGoogle ScholarPubMed
Poulet, G, Massias, J and Taly, V (2019) Liquid biopsy: General concepts. Acta Cytologica 63, 449455.CrossRefGoogle ScholarPubMed
Riethdorf, S, O’Flaherty, L, Hille, C and Pantel, K (2018) Clinical applications of the CellSearch platform in cancer patients. Advanced Drug Delivery Reviews 125, 102121.CrossRefGoogle ScholarPubMed
Rönnau, CG, Verhaegh, GW, Luna-Velez, MV and Schalken, JA (2014) Noncoding RNAs as novel biomarkers in prostate cancer. BioMed Research International 2014, 591703.CrossRefGoogle ScholarPubMed
Signore, M, Alfonsi, R, Federici, G, Nanni, S, Addario, A, Bertuccini, L, Simone, G, Costantini, M, Crinò, L, Rossi, S, Tabolacci, C, Diociaiuti, M, Merlino, T, Gallucci, M, Sentinelli, S, Papalia, R, De Maria, R and Bonci, D (2021) Diagnostic and prognostic potential of the proteomic profiling of serum-derived extracellular vesicles in prostate cancer. Cell Death & Disease 12, 636.CrossRefGoogle ScholarPubMed
Théry, C, Witwer, KW, Aikawa, E, Alcaraz, MJ, Anderson, JD, Andriantsitohaina, R, Antoniou, A, Arab, T, Archer, F, Atkin-Smith, GK, Ayre, DC, Bach, JM, Bachurski, D, Baharvand, H, Balaj, L, Baldacchino, S, Bauer, NN, Baxter, AA, Bebawy, M, Beckham, C, Bedina Zavec, A, Benmoussa, A, Berardi, AC, Bergese, P, Bielska, E, Blenkiron, C, Bobis-Wozowicz, S, Boilard, E, Boireau, W, Bongiovanni, A, Borràs, FE, Bosch, S, Boulanger, CM, Breakefield, X, Breglio, AM, Brennan, M, Brigstock, DR, Brisson, A, Broekman, ML, Bromberg, JF, Bryl-Górecka, P, Buch, S, Buck, AH, Burger, D, Busatto, S, Buschmann, D, Bussolati, B, Buzás, EI, Byrd, JB, Camussi, G, Carter, DR, Caruso, S, Chamley, LW, Chang, YT, Chen, C, Chen, S, Cheng, L, Chin, AR, Clayton, A, Clerici, SP, Cocks, A, Cocucci, E, Coffey, RJ, Cordeiro-da-Silva, A, Couch, Y, Coumans, FA, Coyle, B, Crescitelli, R, Criado, MF, D’Souza-Schorey, C, Das, S, Datta Chaudhuri, A, de Candia, P, De Santana, EF, De Wever, O, Del Portillo, HA, Demaret, T, Deville, S, Devitt, A, Dhondt, B, Di Vizio, D, Dieterich, LC, Dolo, V, Dominguez Rubio, AP, Dominici, M, Dourado, MR, Driedonks, TA, Duarte, FV, Duncan, HM, Eichenberger, RM, Ekström, K, El Andaloussi, S, Elie-Caille, C, Erdbrügger, U, Falcón-Pérez, JM, Fatima, F, Fish, JE, Flores-Bellver, M, Försönits, A, Frelet-Barrand, A, Fricke, F, Fuhrmann, G, Gabrielsson, S, Gámez-Valero, A, Gardiner, C, Gärtner, K, Gaudin, R, Gho, YS, Giebel, B, Gilbert, C, Gimona, M, Giusti, I, Goberdhan, DC, Görgens, A, Gorski, SM, Greening, DW, Gross, JC, Gualerzi, A, Gupta, GN, Gustafson, D, Handberg, A, Haraszti, RA, Harrison, P, Hegyesi, H, Hendrix, A, Hill, AF, Hochberg, FH, Hoffmann, KF, Holder, B, Holthofer, H, Hosseinkhani, B, Hu, G, Huang, Y, Huber, V, Hunt, S, Ibrahim, AG, Ikezu, T, Inal, JM, Isin, M, Ivanova, A, Jackson, HK, Jacobsen, S, Jay, SM, Jayachandran, M, Jenster, G, Jiang, L, Johnson, SM, Jones, JC, Jong, A, Jovanovic-Talisman, T, Jung, S, Kalluri, R, Kano, SI, Kaur, S, Kawamura, Y, Keller, ET, Khamari, D, Khomyakova, E, Khvorova, A, Kierulf, P, Kim, KP, Kislinger, T, Klingeborn, M, Klinke, DJ II, Kornek, M, Kosanović, MM, Kovács Á, F, Krämer-Albers, EM, Krasemann, S, Krause, M, Kurochkin, IV, Kusuma, GD, Kuypers, S, Laitinen, S, Langevin, SM, Languino, LR, Lannigan, J, Lässer, C, Laurent, LC, Lavieu, G, Lázaro-Ibáñez, E, Le Lay, S, Lee, MS, Lee, YXF, Lemos, DS, Lenassi, M, Leszczynska, A, Li, IT, Liao, K, Libregts, SF, Ligeti, E, Lim, R, Lim, SK, Linē, A, Linnemannstöns, K, Llorente, A, Lombard, CA, Lorenowicz, MJ, Lörincz Á, M, Lötvall, J, Lovett, J, Lowry, MC, Loyer, X, Lu, Q, Lukomska, B, Lunavat, TR, Maas, SL, Malhi, H, Marcilla, A, Mariani, J, Mariscal, J, Martens-Uzunova, ES, Martin-Jaular, L, Martinez, MC, Martins, VR, Mathieu, M, Mathivanan, S, Maugeri, M, McGinnis, LK, McVey, MJ, Meckes, DG Jr., Meehan, KL, Mertens, I, Minciacchi, VR, Möller, A, Møller Jørgensen, M, Morales-Kastresana, A, Morhayim, J, Mullier, F, Muraca, M, Musante, L, Mussack, V, Muth, DC, Myburgh, KH, Najrana, T, Nawaz, M, Nazarenko, I, Nejsum, P, Neri, C, Neri, T, Nieuwland, R, Nimrichter, L, Nolan, JP, Nolte-’t Hoen, EN, Noren Hooten, N, O’Driscoll, L, O’Grady, T, O’Loghlen, A, Ochiya, T, Olivier, M, Ortiz, A, Ortiz, LA, Osteikoetxea, X, Østergaard, O, Ostrowski, M, Park, J, Pegtel, DM, Peinado, H, Perut, F, Pfaffl, MW, Phinney, DG, Pieters, BC, Pink, RC, Pisetsky, DS, Pogge von Strandmann, E, Polakovicova, I, Poon, IK, Powell, BH, Prada, I, Pulliam, L, Quesenberry, P, Radeghieri, A, Raffai, RL, Raimondo, S, Rak, J, Ramirez, MI, Raposo, G, Rayyan, MS, Regev-Rudzki, N, Ricklefs, FL, Robbins, PD, Roberts, DD, Rodrigues, SC, Rohde, E, Rome, S, Rouschop, KM, Rughetti, A, Russell, AE, Saá, P, Sahoo, S, Salas-Huenuleo, E, Sánchez, C, Saugstad, JA, Saul, MJ, Schiffelers, RM, Schneider, R, Schøyen, TH, Scott, A, Shahaj, E, Sharma, S, Shatnyeva, O, Shekari, F, Shelke, GV, Shetty, AK, Shiba, K, Siljander, PR, Silva, AM, Skowronek, A, Snyder, OL II, Soares, RP, Sódar, BW, Soekmadji, C, Sotillo, J, Stahl, PD, Stoorvogel, W, Stott, SL, Strasser, EF, Swift, S, Tahara, H, Tewari, M, Timms, K, Tiwari, S, Tixeira, R, Tkach, M, Toh, WS, Tomasini, R, Torrecilhas, AC, Tosar, JP, Toxavidis, V, Urbanelli, L, Vader, P, van Balkom, BW, van der Grein, SG, Van Deun, J, van Herwijnen, MJ, Van Keuren-Jensen, K, van Niel, G, van Royen, ME, van Wijnen, AJ, Vasconcelos, MH, Vechetti, IJ Jr., Veit, TD, Vella, LJ, Velot, É, Verweij, FJ, Vestad, B, Viñas, JL, Visnovitz, T, Vukman, KV, Wahlgren, J, Watson, DC, Wauben, MH, Weaver, A, Webber, JP, Weber, V, Wehman, AM, Weiss, DJ, Welsh, JA, Wendt, S, Wheelock, AM, Wiener, Z, Witte, L, Wolfram, J, Xagorari, A, Xander, P, Xu, J, Yan, X, Yáñez-Mó, M, Yin, H, Yuana, Y, Zappulli, V, Zarubova, J, Žėkas, V, Zhang, JY, Zhao, Z, Zheng, L, Zheutlin, AR, Zickler, AM, Zimmermann, P, Zivkovic, AM, Zocco, D, and Zuba-Surma, EK and Zuba-Surma, EK (2018) Minimal information for studies of extracellular vesicles 2018 (MISEV2018): A position statement of the International Society for Extracellular Vesicles and update of the MISEV2014 guidelines. Journal of Extracellular Vesicles 7, 1535750.CrossRefGoogle ScholarPubMed
von Felden, J, Garcia-Lezana, T, Schulze, K, Losic, B and Villanueva, A (2020) Liquid biopsy in the clinical management of hepatocellular carcinoma. Gut 69, 20252034.CrossRefGoogle ScholarPubMed
Xue, M, Chen, W and Li, X (2021) Extracellular vesicle-transferred long noncoding RNAs in bladder cancer. Clinica Chimica Acta 516, 3445.CrossRefGoogle ScholarPubMed
Zapatero, A, Gómez-Caamaño, A, Cabeza Rodriguez, M, Muinelo-Romay, L, Martin de Vidales, C, Abalo, A, Calvo Crespo, P, Leon Mateos, L, Olivier, C and Vega Piris, LV (2020) Detection and dynamics of circulating tumor cells in patients with high-risk prostate cancer treated with radiotherapy and hormones: A prospective phase II study. Radiation Oncology 15, 137.CrossRefGoogle ScholarPubMed
Zeuschner, P, Linxweiler, J and Junker, K (2020) Non-coding RNAs as biomarkers in liquid biopsies with a special emphasis on extracellular vesicles in urological malignancies. Expert Review of Molecular Diagnostics 20, 151167.CrossRefGoogle ScholarPubMed
Zhan, Y, Du, L, Wang, L, Jiang, X, Zhang, S, Li, J, Yan, K, Duan, W, Zhao, Y, Wang, L, Wang, Y and Wang, C (2018) Expression signatures of exosomal long non-coding RNAs in urine serve as novel non-invasive biomarkers for diagnosis and recurrence prediction of bladder cancer. Molecular Cancer 17, 142.CrossRefGoogle ScholarPubMed
Zhang, W, Ni, M, Su, Y, Wang, H, Zhu, S, Zhao, A and Li, G (2018) MicroRNAs in serum exosomes as potential biomarkers in clear-cell renal cell carcinoma. European Urology Focus 4, 412419.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Summary of clinical translational studies of liquid biopsy for PCa

Author comment: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R0/PR1

Comments

June 15th, 2023

Editor-in-chief: Professor Dame Anna Dominiczak,

Cambridge Prisms: Precision Medicine

Dear Prof. Dominiczak:

Please find enclosed manuscript entitled “Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers” which we would like to submit for publication as a review to Precision Medicine. The work described has not been previously published and is not currently submitted for review to any other journal.

Liquid biopsy has promising potential to ameliorate cancer diagnosis and treatment. Its aim is to obtain tumor information via the molecular interrogation of liquid samples, including blood and urine. As a minimally invasive procedure, liquid biopsy has attracted attention. A series of studies have reported associations of biomarkers such as circulating tumor DNA (ctDNA), cell-free DNA (cfDNA) and extracellular vesicles (EVs) with urological cancers, especially prostate cancer (PCa). In this review, we summarized current clinical translational studies of liquid biopsy in PCa and other urological cancers. Biomarkers isolated from blood by different detection methods could be applied in clinical practice to predict prognosis and treatment response in advanced PCa. The other applications in urological cancers identified in previous studies remain to be explored further. Current studies are limited due to the lack of ideal standard detection methods for biomarkers, which deserves further exploration.

We declare no potential conflicts of interest. All the authors listed have approved the manuscript that is enclosed, and are free to offer suggestions of suitable expert reviewers.

We hope that you find our manuscript informative. Please feel free to contact us with any questions or concerns.

Sincerely yours,

Rong Na, M.D., Ph. D.

Consultant, Associate Professor

Division of Urology, Department of Surgery, Queen Mary Hospital

The University of Hong Kong

102 Pok Fu Lam Road, Hong Kong

Tel: (86) 021-64370045

E-mail: narong.hs@gmail.com

Review: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R0/PR2

Conflict of interest statement

Reviewer declares none.

Comments

The manuscript entitled "Clinical translational research of liquid biopsy applications

in prostate cancer and other urological cancers" highlighted thatCurrent studies are limited due to the lack of ideal standard detection methods for biomarkers. In the future, with advances in methodology, more translational studies will be conducted to identify potential applications of liquid biopsy in urological cancers.

Minor comments:

- The AUthors should provide the expand forms for all acronyms, i

Review: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R0/PR3

Conflict of interest statement

Reviewer declares none.

Comments

Rong et al. wrote this review to discuss and summarize available clinical translational research of liquid biopsies in urological cancers, specifically prostate cancer (PCa), bladder cancer (BCa), and renal cell carcinoma (RCC). The review explains liquid biopsies, the different materials that can be used, and the different types of biomarkers that can be found in liquid biopsies. The main body of the review is organized by three big biomarkers found in liquid biopsies. The authors explain their methods for finding the clinical translational research, summarize/connect the findings of those papers, and provide what they believe to be the next steps the scientific community should take to further bridge the basic studies to clinical use of liquid biopsies.

In my opinion, this review is well-organized and well-written. It provides a thorough explanation of the topic at hand. The review’s conclusion and future directions are relevant and necessary to further the research in liquid biopsies.I would accept this review after some suggested minor revisions. The revisions mainly pertain to the structure of paragraphs and the grammar of the paper.

Some revisions are:

• “Liquid Biopsy” is sometimes singular and sometimes plural. In most cases/sentences, I believe “liquid biopsy” should be in its plural form.

○ Example: On page 1 line 12, there is a singular “liquid biopsy” and then a couple of words down on the same line is the plural form. I believe both should be in the plural form.

• On page 7, the second to last paragraph and last paragraph of the “Enumeration and assessment of CTCs” section glosses over BCa until the very end of line 47. Including an individual sentence before the conclusion paragraph on how there wasn’t any relevant research in BCa found at the current moment might be helpful.

• The “Cell-free DNA and circulation tumor DNA” section has paragraphs that feel very disorganized/detached. It jumps around between the three cancers and the liquid biopsy material. I suggest following the same order of cancers as listed in the other sections, as well as making which liquid biopsy material is being discussed more obvious between sentences.

○Example: On the first paragraph of page 8, most of the paragraph goes over BCa liquid biopsy of urine, but then jumps into PCa liquid biopsy of seminal fluid without indication of the change until the end of the sentence, making it seem disconnected.

• On page 8, line 57, the word “waist” was used, and I believe it was meant to be “waste.”

• On page 9, lines 11-12, the sentence about EVs is awkward grammatically. Instead of “to function in,” remove “to.”

• In the conclusion column of Table 1, the text is currently hard to separate based on the rows of research. Implementing some barriers or separating the text more will help properly divide the information.

Recommendation: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R0/PR4

Comments

No accompanying comment.

Decision: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R0/PR5

Comments

No accompanying comment.

Author comment: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R1/PR6

Comments

July 27th, 2023

Editor-in-chief: Professor Dame Anna Dominiczak,

Cambridge Prisms: Precision Medicine

Dear Professor Dominiczak,

We would like to thank the reviewers for their careful and thorough consideration of our manuscript, and their enthusiasm for this review.

We have considered and responded to each point raised by each reviewer, as described below. We have substantially revised the manuscript as a result and feel our paper is greatly improved.

Response to Reviewers:

Reviewer 1:

Comment 1: The Authors should provide the expand forms for all acronyms.

Our response: Thanks for your advice. We summarized a list of abbreviations and acronyms to make it clear.

Reviewer 2:

Comment 1: “Liquid Biopsy” is sometimes singular and sometimes plural. In most cases/sentences, I believe “liquid biopsy” should be in its plural form.

Example: On page 1 line 12, there is a singular “liquid biopsy” and then a couple of words down on the same line is the plural form. I believe both should be in the plural form.

Our response: We agree that it’s appropriate to use the plural form for “liquid biopsy”. The forms of “liquid biopsy” in the manuscript were checked and verified.

Comment 2: On page 7, the second to last paragraph and last paragraph of the “Enumeration and assessment of CTCs” section glosses over BCa until the very end of line 47. Including an individual sentence before the conclusion paragraph on how there wasn’t any relevant research in BCa found at the current moment might be helpful.

Our response: Thank you for your advice.We modified the second to last paragraph in the section of “Enumeration and assessment of CTCs” and stated the lack of translational researched of CTC in BCa, so that this section became more comprehensive.

Comment 3: The “Cell-free DNA and circulation tumor DNA” section has paragraphs that feel very disorganized/detached. It jumps around between the three cancers and the liquid biopsy material. I suggest following the same order of cancers as listed in the other sections, as well as making which liquid biopsy material is being discussed more obvious between sentences.

Example: On the first paragraph of page 8, most of the paragraph goes over BCa liquid biopsy of urine, but then jumps into PCa liquid biopsy of seminal fluid without indication of the change until the end of the sentence, making it seem disconnected.

Our response: Thank you for your comment, according to which, we adjusted the structure of the “Cell-free DNA and circulation tumor DNA” section. The clinical translational evidences of cfDNA and ctDNA were reviewed following the order of different diseases. We hope you find this section clearer and better organized.

Comment 4:On page 8, line 57, the word “waist” was used, and I believe it was meant to be “waste.” On page 9, lines 11-12, the sentence about EVs is awkward grammatically. Instead of “to function in,” remove “to.”

Our response: We are sorry for these grammatic mistakes. We reviewed the manuscript carefully again and corrected the mistakes.

Comment 5: In the conclusion column of Table 1, the text is currently hard to separate based on the rows of research. Implementing some barriers or separating the text more will help properly divide the information.

Our response: Thank you for this advice. We separated adjacent rows by different colors to make it easier to read.

Yours sincerely,

Rong Na

Consultant, Associate Professor

Division of Urology, Department of Surgery, Queen Mary Hospital

The University of Hong Kong

Review: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R1/PR7

Conflict of interest statement

None.

Comments

The Authors have addressed all my concerns and I have no further comments

Review: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R1/PR8

Conflict of interest statement

Reviewer declares none.

Comments

The authors have adequately addressed my critiques. The sections “Enumeration and assessment of CTCs” and “Cell-free DNA and circulation tumor DNA” read well and feel organized when discussing the 3 different urological cancers. All insistences of “Liquid Biopsy” have been changed to its proper form. Table 1 has a nice separation of the rows and is well organized, making it easier to read and understand the material. The manuscript is much improved over the original submission. I have no further critiques for this manuscript and would recommend acceptance by Cambridge Prism: Precision Medicine.

Recommendation: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R1/PR9

Comments

No accompanying comment.

Decision: Clinical translational research of liquid biopsy applications in prostate cancer and other urological cancers — R1/PR10

Comments

No accompanying comment.