Minimal residual disease in canine lymphoma: An objective marker to assess tumour cell burden in remission

Accepted Manuscript Title: Minimal residual disease in canine lymphoma: An objective marker to assess tumour cell burden in remission Author: Masahiko Sato, Jumpei Yamazaki, Yuko Goto-Koshino, Asuka Setoguchi, Masashi Takahashi, Kenji Baba, Yasuhito Fujino, Koichi Ohno, Hajime Tsujimoto PII: DOI: Reference:

S1090-0233(16)30064-8 http://dx.doi.org/doi: 10.1016/j.tvjl.2016.05.012 YTVJL 4821

To appear in:

The Veterinary Journal

Accepted date:

24-5-2016

Please cite this article as: Masahiko Sato, Jumpei Yamazaki, Yuko Goto-Koshino, Asuka Setoguchi, Masashi Takahashi, Kenji Baba, Yasuhito Fujino, Koichi Ohno, Hajime Tsujimoto, Minimal residual disease in canine lymphoma: An objective marker to assess tumour cell burden in remission, The Veterinary Journal (2016), http://dx.doi.org/doi: 10.1016/j.tvjl.2016.05.012. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Review Article

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Minimal residual disease in canine lymphoma: An objective marker to assess tumour

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cell burden in remission

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Masahiko Sato a, Jumpei Yamazaki b, Yuko Goto-Koshino c, Asuka Setoguchi d, Masashi

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Takahashi c, Kenji Baba e, Yasuhito Fujino f, Koichi Ohno f, Hajime Tsujimoto c,f,*

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a

Department of Clinical Sciences, College of Veterinary Medicine and Biomedical Sciences,

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Colorado State University, Fort Collins, CO 80523, USA

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b

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University, Sapporo, Hokkaido 060-0818, Japan

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c

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University of Tokyo, Bunkyo-ku, Tokyo 113-8657, Japan

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d

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Kagoshima University, Kagoshima, Kagoshima 890-0065, Japan

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e

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University, Yamaguchi, Yamaguchi 753-8515, Japan

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f

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Sciences, The University of Tokyo, Bunkyo-ku, Tokyo 113-8657, Japan

Laboratory of Molecular Medicine, Graduate School of Veterinary Medicine, Hokkaido Veterinary Medical Centre, Graduate School of Agricultural and Life Sciences, The Laboratory of Small Animal Internal Medicine, Joint Faculty of Veterinary Medicine, Department of Veterinary Medicine, Joint Faculty of Veterinary Medicine, Yamaguchi Department of Veterinary Internal Medicine, Graduate School of Agricultural and Life

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* Corresponding author: Tel.: +81 3 58415402. E-mail address: [email protected] (H. Tsujimoto). Highlights 

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Minimal residual disease (MRD) can be measured in the peripheral blood of dogs with lymphoma (lymphosarcoma).

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The efficacy of chemotherapy in canine lymphoma can be objectively compared by detection of MRD.

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The level of MRD is predictive of relapse and prognosis of canine lymphoma.

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MRD monitoring by real-time quantitative PCR will be of value in evaluating novel

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therapies for canine lymphoma. Abstract

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Lymphoma is the most common haematopoietic malignancy in dogs. Since a high

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proportion of dogs with lymphoma achieve remission soon after initiation of chemotherapy,

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an objective marker assessing treatment efficacy is required. Following clinical remission, the

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residual population of tumour cells can be referred to as the minimal residual disease (MRD).

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MRD traditionally has been detected by cytology and flow cytometry; however, if the burden

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of malignant cells is low, these methods might not be sufficiently sensitive to detect MRD. As

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an extension of the development of PCR for antigen receptor gene rearrangements (PARR) in

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dogs, there has been recent progress in the application of real-time quantitative PCR

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(RT-qPCR) to canine lymphoma. With the RT-qPCR system, a very high sensitivity (1 cell per

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10,000 cells) has been achieved by preparing allele-specific oligonucleotide primers and

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probes designed from neoplastic clones of each dog. A series of MRD diagnostics studies

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employing the RT-qPCR system have revealed its usefulness as a prognostic indicator, an

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objective marker of treatment efficacy and a predictor of relapse for dogs with lymphoma

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receiving chemotherapy. Introduction of the MRD monitoring system will provide an

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innovative scientific tool in the development of superior treatments and monitoring strategies

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for canine lymphoma.

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Keywords: Canine; Lymphoma; Chemotherapy; Minimal residual disease; Real-time

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quantitative PCR

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Introduction Lymphoma (lymphosarcoma), the most common haematopoietic malignancy in

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dogs, is characterised by the clonal proliferation of lymphoid cells. In most cases, such as in

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high grade multicentric B cell lymphoma, the disease is initially responsive to chemotherapy.

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However, high rates of relapse and mortality are evident in nearly all cases as a result of

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disease progression.

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Cyclophosphamide, doxorubicin, vincristine and prednisolone (CHOP)-based

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protocols were introduced in the treatment of canine lymphoma (Greenlee et al., 1990; Keller

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et al., 1993) as a superior alternative to COP-based protocols (Cotter et al., 1983). The

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combination of CHOP-based protocols with L-asparaginase as adjunct therapy is referred to

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as L-CHOP. Overall response (OR) rate, progression-free survival (PFS) and overall survival

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(OS) in dogs with lymphoma treated with L-CHOP-based protocols (Greenlee et al., 1990;

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Keller et al., 1993; Vail et al., 1996; Myers et al., 1997; Zemann et al., 1998; Khanna et al.,

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1998) were 69-87%, 7.3-12.8 months and 10.1-17.0 months, respectively. In these protocols,

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antineoplastic agents were continuously administered for up to 2-3 years; however,

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subsequent studies have indicated that similar treatment outcomes were achievable with

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maintenance-free L-CHOP-based protocols in up to 25 weeks (Garrett et al., 2002;

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MacDonald et al., 2005; Simon et al., 2006; Hosoya et al., 2007; Burton et al., 2012; Curran

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and Thamm, 2015). The influence of L-asparaginase on the efficacy of the CHOP/COP

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protocols was investigated in dogs with multicentric high grade lymphoma in two

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independent studies, in which outcomes following use of a multi-agent chemotherapy

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protocol, with or without the addition of L-asparaginase (depending on commercial

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availability), were compared (Jeffreys et al., 2005; MacDonald et al., 2005). Both of these

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studies suggested that addition of L-asparaginase to CHOP/COP protocols may not improve

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treatment outcomes, suggesting that L-asparaginase could be reserved for rescue protocols.

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Recent studies on the clinical application of chemoimmunotherapy (i.e.

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chemotherapy combined with an autologous tumour cell vaccine) revealed clinical benefits

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without incidents of increased toxicity in dogs with B cell lymphomas (Aresu et al., 2014;

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Marconato et al., 2014). Most of the dogs enrolled in these studies had multicentric high

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grade B cell lymphomas. However, many studies have reported poorer prognoses for high

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grade T cell lymphomas, indicating the need for alternative protocols. For T cell lymphomas,

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the use of alkylating agent-based protocols, such as L-asparaginase combined with

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mechlorethamine, oncovin, procarbazine and prednisone (L-asparaginase-MOPP) was

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superior to a classic CHOP-based protocol (Brodsky et al., 2009). However, another study

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reported that the use of a generally applied CHOP-based protocol to dogs with T cell

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lymphoma produced results comparable to those for B cell lymphomas (Rebhun et al., 2011).

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L-CHOP can induce complete remission (CR) rapidly in a large proportion of dogs

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with lymphoma; the median time from the first day of L-CHOP to CR was 11 days (Simon et

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al., 2006). After achieving CR, chemotherapy is usually continued for a certain period, e.g. up

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to 25 weeks in UW-25 protocol (Garrett et al., 2002). However, most dogs experience relapse

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after termination of, or during, the protocol. This is indicative of a small, residual, population

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of malignant tumour cells that persist within the body, referred to as the minimal residual

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disease (MRD), which are implicated as the source of tumour relapses. In general, following

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initiation of chemotherapy, the amount of detectable malignant cells within the body

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decreases to subthreshold detection limits of clinical diagnostic techniques (clinical

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remission) (Fig. 1). Detection of MRD is facilitated by a sensitive, molecular biological

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technique that may be subject to, in some cases, further subthreshold decreases to levels

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below that of its detection limit (molecular remission) following successful remission

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induction therapy or consolidation therapy. Consequently, the residual malignant cells

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proliferate after a certain period, resulting in molecular relapse leading to clinical relapse (Fig.

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1).

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In human haematological malignancies, the quantity of MRD after treatment can be

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indicative of treatment outcome. High MRD after chemotherapy indicates a poor prognosis

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for follicular lymphoma (Rambaldi et al., 2002), mantle cell lymphoma (Pott et al., 2006),

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adult acute lymphoblastic leukaemia (Bruggemann et al., 2006), and acute promyelocytic

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leukaemia (Miller et al., 1993). Several reports have documented the usefulness of MRD in

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the molecular assessment of treatment efficacy for diffuse large B cell lymphoma (DLBCL)

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in human beings (Mitterbauer et al., 2001; Uchiyama et al., 2003; Yashima et al., 2003).

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DLBCL is the most common histological subtype of canine lymphoma (Valli et al., 2011) and

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comparative studies between human and canine populations would be possible for this type of

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lymphoma. MRD diagnostics is of high clinical relevance to human patients affected with B

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cell non-Hodgkin lymphomas. This may serve as a surrogate parameter in the evaluation of

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treatment effectiveness and long term prognosis (Ladetto et al., 2013). Subsequently, MRD

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diagnostics performed by real-time quantitative PCR (RT-qPCR) is now the gold-standard

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and currently the most sensitive and broadly applied method for the staging, classification and

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treatment response assessment of human non-Hodgkin lymphoma (Pott et al., 2013; Rosolen

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et al., 2015; Sandlund et al., 2015).

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The assessment of MRD in human patients with lymphoid malignancies has shown

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that the prognoses of patients were strongly influenced by the MRD quantities following

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chemotherapy (or other therapeutic modalities), but were unrelated to the tumour cell burden

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prior to treatment (Mitterbauer et al., 2001; Rambaldi et al., 2002; Pott et al., 2006; Ladetto et

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al., 2013). Although available data for canine lymphomas are limited, there are several studies

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comparing the prognostic values of tumour cell burden amounts before and after

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chemotherapy. Results of the qualitative status (positive or negative) in the PCR for antigen

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receptor gene rearrangements (PARR) before chemotherapy were not related to the prognosis

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of dogs with lymphoma (Lana et al., 2006). Similarly, a correlative, prognostic significance

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for tumour cell burden prior to the initiation of RT-qPCR-assessed chemotherapy for the

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immunoglobulin heavy chain (IgH) gene was lacking in dogs with multicentric high grade B

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cell lymphoma (Sato et al., 2013). However, MRD quantities as assessed by RT-qPCR at

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weeks 11 and 25 of a standard CHOP protocol (UW-25) (Garrett et al., 2002) were correlated

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with prognosis in dogs with lymphoma (Yamazaki et al., 2010; Sato et al., 2013). On the basis

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of these observations, MRD quantity after treatment for a certain period (e.g. 11 weeks or

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more with the UW-25 protocol) could be used as an objective prognostic marker in canine

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lymphoma.

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Molecular biological detection of tumour cells in lymph nodes and the peripheral

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blood of dogs with lymphoid neoplasia has been reported using PARR, resulting in the

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assessment of clonality and T/B cell lineage of the lymphoid cells (Burnett et al., 2003; Keller

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et al., 2004; Calzolari et al., 2006; Tamura et al., 2006; Valli et al., 2006; Lana et al., 2006;

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Yagihara et al., 2007). PARR has also been used for the detection of MRD in dogs with

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lymphoma that achieved remission after chemotherapy (Thilakaratne et al., 2010; Manachai et

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al., 2014). Aresu et al. (2014) reported that the combination of PARR and flow cytometry for

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large CD21+ cells was more sensitive than either technique alone in predicting outcomes of

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dogs with DLBCL after chemotherapy. All of these studies employed the conventional PCR

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method using universal primers to detect for the rearrangements of antigen receptor genes.

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The sensitivity for detecting neoplastic lymphoid cells was shown to be ~1 per 100 (Burnett et

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al., 2003). Therefore, it is conceivable that tumour cells with clonal rearrangement can

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become undetectable during remission.

156 157

In a study by Yamazaki et al. (2008), MRD in the peripheral blood was successfully

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detected and quantified by RT-qPCR using allele-specific primers and probes in most canine

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lymphoma patients in CR after chemotherapy. Subsequent studies using RT-qPCR procedures

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enabled the dynamic exploration of tumour cell burden in dogs with lymphoma before, during

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and after chemotherapy, as well as prior to and during episodes of relapse (Yamazaki et al.,

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2010; Sato et al., 2011a, b, 2013).

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Quantitative assessment of minimal residual disease in canine lymphoma

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A quantitative detection system for MRD in canine lymphoma was developed by

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our group using RT-qPCR (Yamazaki et al., 2008). UL-1, a canine T cell lymphoma-derived

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cell line, was used to examine the specificity and sensitivity of the assay for detecting MRD.

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Allele-specific oligonucleotide primers and probes were designed based on the rearranged T

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cell receptor γ chain (TCRγ) gene sequence of UL-1 cells in conjunction with its downstream

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sequence obtained from the dog genome database. The RT-qPCR system used for plasmid

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DNA containing the TCRγ gene cassette derived from UL-1 cells revealed that the system was

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accurate for 10-100,000 copies per reaction and that its sensitivity was 1 cell per 10,000 cells.

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In order to monitor the kinetics of tumour cell numbers in dogs with lymphoma, MRD was

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quantified in the peripheral blood of seven dogs with lymphoma undergoing chemotherapy

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(Yamazaki et al., 2008). Since the lymphoma cells from the seven dogs were shown to be of B

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cell origin, allele-specific oligonucleotide primers and probes were prepared based on the

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sequence of the rearranged IgH gene in each case. In all seven cases, MRD in the peripheral

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blood was detectable, even in cases of CR. The peripheral blood MRD levels were directly

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proportional to lymph node size changes evident during remission induction or at relapse. The

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high instrument sensitivity (1 cell per 10,000 cells) of the RT-qPCR system used in the study

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by Yamazaki et al. (2008) was similar to that of a study by van der Velden et al. (2002) using

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RT-qPCR for detection of MRD in human leukaemia patients. The RT-qPCR system for the

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rearranged IgH/TCR genes was 100 times more sensitive than previous studies using

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conventional PARR with universal primers in dogs with lymphoma (Keller et al., 2004; Lana

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et al., 2006).

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Monitoring minimal residual disease after chemotherapy in dogs with lymphoma

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Using RT-qPCR for monitoring MRD in canine lymphoma (Yamazaki et al., 2008),

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a proof-of-concept pilot study was carried out to understand the clinical utility of a multi-drug

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chemotherapy in dogs with lymphoma (Yamazaki et al., 2010). Peripheral blood MRD was

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monitored in seven dogs with lymphoma, all of which were treated with a CHOP-based

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protocol (UW-25) (Garrett et al., 2002). The sample of seven dogs included one dog at stage

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V (presence of lymphoma cells in peripheral blood) prior to chemotherapy. In this case, the

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clone-specific RT-qPCR revealed a similar number of tumour cells in the peripheral blood to

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that detected by conventional haematological analysis. Although the other six dogs were in

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stage III or IV, the clone-specific RT-qPCR assay clearly indicated the presence and quantity

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of tumour cells in the peripheral blood (4.4-140 cells/µL). MRD in peripheral blood gradually

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decreased after initiation of the UW-25 protocol in all seven dogs, reaching a minimum of

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<0.019-1.0 cells/µL at weeks 4-17 and remaining at these levels until week 25. MRD at weeks

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4, 9, 17 and 25 was significantly lower than the number of neoplastic lymphoid cells

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measured by RT-qPCR at week 1 (before chemotherapy) in the seven dogs.

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The correlation between MRD at the end of chemotherapy and duration of

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remission after chemotherapy was analysed in 17 dogs that completed UW-25. MRD at the

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end of chemotherapy was negatively correlated with duration of remission from the end of

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chemotherapy until relapse. These results suggested that MRD could be used as an objective

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marker to indicate tumour cell burden in dogs with lymphoma in remission. Furthermore,

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MRD at the end of chemotherapy could be a prognostic factor predicting duration of

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remission after chemotherapy.

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Prognostic significance of minimal residual disease in the early phase of chemotherapy

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in dogs with lymphoma

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Although MRD levels after chemotherapy have prognostic significance in dogs

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with lymphoma (Yamazaki et al., 2010), data at the end of chemotherapy could not be

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obtained in nearly half of the sample population due to the occurrence of progressive disease

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(PD) during the initial of remission induction therapy (Sorenmo et al., 2010). In order to

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apply the MRD monitoring system to the majority of dogs in this prospective study, Sato et al.

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(2013) examined the prognostic significance of MRD levels in the early phases of a multidrug

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chemotherapy protocol in 36 dogs with multicentric high grade B cell lymphoma. Sequences

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of IgH gene fragments from lymphoma cells were amplified and used to design allele-specific

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primers and probes for RT-qPCR. The dogs were treated with a modified UW-25 protocol

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and evaluated for the MRD level at weeks 6 and 11 of UW-25. Of the 31 dogs that remained

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on the protocol by week 11, 14 were MRD negative (less than 10 tumour cells per 105

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peripheral blood mononuclear cells, PBMCs), whereas the other 17 were MRD positive (≥10

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tumour cells per 105 PBMCs). The PFS of dogs with MRD negative status at week 11

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(median 337 days) was significantly longer than that of the MRD positive dogs at the same

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time point (median 196 days; P = 0.0002). These results highlight the clinical significance of

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MRD as a prognostic marker in the early phase of chemotherapy.

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Increase in peripheral blood minimal residual disease before clinical relapse in dogs with

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lymphoma that achieved clinical remission following chemotherapy

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In order to identify the changes in MRD prior to clinical relapse in dogs with

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lymphoma that had achieved CR following chemotherapy, peripheral blood MRD was

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monitored by RT-qPCR, which amplified the rearranged IgH gene in 20 dogs with

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multicentric high grade B cell lymphoma (Sato et al., 2011a). MRD measurement and clinical

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assessment were performed every 2-4 weeks for 28-601 days after completion of

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chemotherapy. An increase in MRD was defined as an increase of more than 0.5, calculated

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by log10 [copy number of MRD per 105 PBMCs], based on the uncertainty level observed in a

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canine lymphoma cell line. During the follow-up period, 15 dogs relapsed in 28-320 days

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(median 120 days) after completion of chemotherapy. An increase in MRD was detected 2

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weeks or more prior to a relapse event in 14/15 dogs. The time from increased MRD to

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clinical relapse was 0-63 days (median 42 days). In contrast, no increase in MRD was

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detected in five dogs that did not experience clinical relapse. This study indicated that an

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increase in MRD can be detected before clinical relapse in dogs with lymphoma. This leads to

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the consideration of applied early re-induction therapy, based on an increase in MRD before

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clinical relapse (MRD-guided therapy), for the improvement of treatment outcome in canine

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lymphoma.

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Cyclophosphamide, doxorubicin, vincristine and prednisolone

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Evaluation of cytoreductive efficacy of vincristine, cyclophosphamide and doxorubicin

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in dogs with lymphoma

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Since a high proportion of dogs with multicentric lymphoma respond well to

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chemotherapy and achieve CR soon after initiation of chemotherapy, there is a difficulty in

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establishing drug efficacy from a standard clinical evaluation during treatment period. The

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cytoreductive efficacy of vincristine, cyclophosphamide and doxorubicin was evaluated in

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dogs with lymphoma that received the UW-25 protocol (Garrett et al., 2002) without

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administration of L-asparaginase at week 1 (because it did not significantly influence

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treatment outcome; MacDonald et al., 2005; Jeffreys et al., 2005). The number of lymphoma

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cells in the peripheral blood was measured from diagnosis to week 11 of the modified UW-25

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in 29 dogs with high grade B cell multicentric lymphoma using clone-specific RT-qPCR to

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amplify IgH gene fragments (Sato et al., 2011b). The number of lymphoma cells after the first

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administration of vincristine, cyclophosphamide and doxorubicin in weeks 1-4 was decreased

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in 29/29 (100%), 15/29 (52%) and 26/27 (96%) dogs, respectively. The cytoreductive efficacy

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of cyclophosphamide was less than that of vincristine, cyclophosphamide and doxorubicin.

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Vincristine, cyclophosphamide and doxorubicin administered in weeks 6-9 were effective in

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5/26 (19%), 5/20 (25%) and 14/19 (74%) dogs, respectively, indicating the sustained

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cytoreductive efficacy of doxorubicin. Cyclophosphamide non-responders were heavier and

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exhibited a shorter first remission than cyclophosphamide responders. The study provided

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several suggestions for the usage of these three chemotherapeutic agents in order to improve

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treatment efficacy. Vincristine use might be preferred in the early phase because of the

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decrease in vincristine cytoreductive efficacy evident in the later phase. Cyclophosphamide

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administration can be reconsidered, especially in large dogs (e.g. dose increase or substitution

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with other agents). Doxorubicin at the dosage used in the current protocol (30 mg/m2 for dogs

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>10 kg; 1 mg/kg for dogs <10 kg) is highly effective; thus, it is considered to be the main

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drug in the combination protocol. Findings obtained in this study would be helpful to

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construct a new or modified chemotherapeutic protocol in order to obtain better treatment

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outcomes in dogs with lymphoma.

277 278

Quantitative MRD evaluation after or during anti-tumour therapy would provide an

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objective evaluation comparing the efficacy of different protocols, especially to indicate an

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advantage of newly introduced modalities, such as high-dose therapy with autologous stem

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cell transplantation (Frimberger et al., 2006) and immunotherapy with monoclonal antibodies

282

directed to lymphoid tumour cells (Ito et al., 2014). Although clinical parameters, such as OR,

283

PFS and OS, should be defined in clinical trials, MDR monitoring could also be used in

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combination with clinical response monitoring, since this will help to evaluate its application

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and give us confidence in the positive utility of the technique.

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Clinical usefulness of minimal residual disease monitoring A series of studies indicating the clinical usefulness of MRD monitoring (Yamazaki

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et al., 2008, 2010; Sato et al., 2011a, 2011b, 2013) has the potential to revolutionise the

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medical control of canine lymphoma. Measurement of MRD levels after chemotherapy can

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function as an objective parameter for the determination of treatment efficacy. This may allow

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clinicians to recommend additional treatment plans to animals with relatively high MRD.

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MRD monitoring results obtained by the newly introduced RT-qPCR technique, in

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comparison with those obtained by conventional PARR, could be used to evaluate the new

295

protocol. Monitoring of MRD during CR after completion of the chemotherapy would be

296

useful in predicting relapses, leading to the potential application of an early re-induction

297

therapy prior to identifying clinical relapse.

298 299

In the studies of Yamazaki et al. (2008, 2010) and Sato et al. (2011a, 2011b, 2013),

300

peripheral blood samples were used to monitor MRD in dogs with lymphoma. Although there

301

is a possibility of using lymph node aspirates as samples for monitoring MRD in these dogs,

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this technique is more demanding and requires additional technical expertise. However, in

303

relatively large dogs, mandibular and popliteal lymph nodes are palpable, even in CR, with

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fresh aspirates from these nodes providing a potentially useful means of evaluating MRD.

305 306

Throughout these studies (Yamazaki et al., 2008, 2010; Sato et al., 2011a, 2011b,

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2013), preparations of allele (clone)-specific oligonucleotides after sequencing the rearranged

308

antigen receptor (IgH or TCR) gene fragments were needed in each dog with lymphoma. This

309

was also the case in recent studies by Gentilini et al. (2010, 2013), who reported successful

310

monitoring of MRD using hairpin-shaped clone-specific primers in dogs with B cell

311

lymphoma. The costs and time required to prepare the allele-specific oligonucleotides can be

312

an obstacle in the application of such sophisticated analytical systems to many canine cases in

313

practice. If more generally applicable procedures using universal primers had reasonable

314

sensitivity in detecting MRD after achieving CR, such techniques may have utility in

315

monitoring dogs with lymphoma under chemotherapy. Currently, preparation of

316

allele-specific oligonucleotides is essential to achieve sufficient sensitivity for quantification

317

of MRD in remission.

318 319

Feline lymphoma is also clinically important due to its high incidence and wide

320

spectrum of clinical manifestations. To aid in the diagnosis of lymphoma, in conjunction with

321

cytological and histological findings, PCR-based clonality assessment via the detection of Ig

322

and TCR gene rearrangements have been developed for use in cats (Moore et al., 2005;

323

Werner et al., 2005). A system for monitoring MRD similarly could be applied to feline

324

lymphomas in the assessment of treatment efficacy and relapse, particularly in nasal and

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gastrointestinal lymphomas, in which routine clinical examination procedures render

326

evaluation of tumour size difficult.

327 328

Conclusions

329

MRD measurement is a useful prognostic indicator, an objective marker of

330

treatment efficacy and a predictor of clinical relapse in dogs with lymphoma under

331

chemotherapy. Introduction of MRD monitoring will provide a tool to aid in the development

332

of improved treatment strategies for canine lymphoma.

333 334

Conflict of interest statement

335

None of the authors of this paper have a financial or personal relationship with

336

other people or organisations that could inappropriately influence or bias the content of the

337

paper.

338 339

References

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Figure legend

586 587

Fig. 1. Kinetics of tumour cell burdens after anti-tumour therapy. The amount of malignant

588

cells within the body decreases after initiation of chemotherapy and reaches subthreshold

589

detection limits of clinically diagnostic techniques. Such residual malignant cells are

590

considered to be the source of tumour relapses and are known as minimal residual disease

591

(MRD). Clinical remission and clinical relapse are defined as the detection limit of the

592

clinical diagnostic techniques. Molecular remission and molecular relapse are defined by the

593

detection limit of the molecular biology techniques.

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