Alternatives to left lateral sector in paediatric liver transplantation—a systematic review on monosegmental and reduced grafts

Introduction

Liver transplantation is an established method for treating acute and chronic organ failure. Given the obvious difficulties for obtaining suitable grafts in small recipients, the pool of donors was expanded to facilitate access to the waiting list, initially with reduced organs and later on with split grafts (deceased donors) as well as living donor liver transplantation (LDLT) (1), being the commonest modality of transplant in children the left lateral sector (LLS) (2).

Nevertheless, the Gordian Knot of the paediatric liver transplantation (pLT) continues to be the large-for-size scenario, seen when the volume of the graft exceeds the capacity of the abdominal cavity (2-6). The alternatives are using a standard LLS and delaying abdominal wall closure (4,5) or surgically altering the LLS and aiming for a primary closure. In 1992, to confront this problem, Strong et al. (6) published the first monosegmental pLT, implanting the segment 3 from a deceased donor (DD) into a 4-month-old baby [a redo transplant for hepatic artery thrombosis (HAT)]. Larger series with DD appeared later, notably from Srinivasan et al. (7). This technique would be further consolidated by Kasahara et al. (8), whom produced reduced left lateral sector (RLLS) grafts and mono-segments from LDLT.

The aim of the present study is to interrogate the literature to evaluate the existing experience and outcomes of monosegment (MSG), RLLS/hyper-reduced left lateral sector (HRLLS) transplants in small paediatric recipients. We present the following article in accordance with the PRISMA reporting checklist (available at https://hbsn.amegroups.com/article/view/10.21037/hbsn-20-792/rc).

Methods

This systematic review was carried out in accordance with the guidelines set out in the PRISMA checklist (9).

Literature search

A systematic literature search of articles published from inception until May 2020 performed in Embase, MEDLINE (PubMed), Cochrane library, and Google Scholar databases using free text and MeSH terms (liver pediatric transplantation, monosegments, monosegmental). A grey literature search on www.clinicaltrials.gov was also performed. Bibliographies cited in the retrieved articles were manually checked for further analysis. Disagreements between authors were resolved through discussion.

Search terms, inclusion and exclusion criteria

Studies reporting paediatric liver transplantation, monosegments or monosegmental grafts, reduced or hyper-reduced grafts and left lateral sectors grafts were included in this study. Abstracts (summary of the contents of an article or book) and editorials without original data were excluded.

Data extraction and outcomes

Two reviewers (PG and EH) independently extracted demographic data, operative information and patients’ outcomes from the included studies. The data points recorded were: donors’ age and weight, donor status (living or cadaveric), recipient indication for liver transplantation, age and recipient weight, donor-to-recipient weight ratio (DRWR), graft-to-recipient weight ratio (GRWR), surgical techniques used for manipulating LLS, segments implanted, postoperative vascular complications, median follow-up, graft and patient overall survival. Row data is presented with mean and media (range) values as well as percentages. Series with <3 cases were not considered to avoid “overweight” their values (6,10,11).

Definitions

The LLS (1) can be modified into: (I) partially reduced grafts, or (II) monosegments. In addition, it can be done before perfusion (in-situ) or afterwards (ex-situ), from DD or LDLT.

RLLS and/or HRLLS refer to those grafts obtained by transecting along peripheral (horizontal and vertical) section planes of the graft. The references tend to be the outflow, not following the Couinaud’s segmentation, hence some authors name them “non-anatomical”. Those grafts referred as “reduced to segment…” using peripheral planes for transection, were regarded as reduced (12).

Monosegmental liver transplantation refers to any graft including either segment 2 or 3. This technique is characterised by:

• Following inflow landmarks as per anatomical Couinaud’s segmentation.
• There is “disruption” of the Glisson capsule.
• Addresses volume and thickness of the graft.

Query

Two queries were proposed in this systematic review (SR). First, are the overall results of surgically modifying the LLS comparable to the standard LLS pLT? And second, are the different modalities, MSG and RLLS, comparable?

Statistical analysis

The methodological quality of each of the included studies was evaluated for risk of bias using the Risk of Bias in Non-randomized Studies of Interventions (ROBINS-I) which incorporates seven domains: confounding, selection of participants into the study, classification of interventions, deviations from intended interventions, missing data, measurement of outcomes and selection of reported results. An important feature of ROBINS-I is the use of signalling questions to detect the risk of bias and facilitate assessment within seven bias domains (13). In all analyses, the point estimate was considered significant at P<0.05.

Results

Sixteen studies from a pool of sixty-two were selected (6,7,10-12,14-24) (Figure 1 and Table 1). Six articles (25-30) were excluded to avoid repetition as more updated publications from the same institutions were identified. This SR includes 330 pLT with a median follow-up of 39 months ranging from 6 to 87 months (composite of each manuscript).

Figure 1 Diagram of the search strategy.

Quality assessment

The overall quality of the studies included varied from moderate to low. Selection, confounding, underpowered sample, detection, national and institutional bias might have influenced the results (Table S1).

• Overall results (Tables 1,215,21,24). With a median follow-up of 39 (range, 6–87) months, the overall graft and patient survival were 84% and 89%: a total of 35 deaths were reported throughout all publications, some of them due to delayed causes (Table 3).
• Reduced grafts (Table 2): 210/330 were reported as reduced grafts (7), including hyper-reduced (12,14,15,17-19,22,24) and medial (23). Shehata’s (18) and Kitajima’s (24) series comprise MSG and RLLS. Only three of the ten authors performed the reduction in situ (19,23,24) although it represented 49% of the series. Actual median graft weight and GRWR obtained were 205 grs [172–264] and 3.67% (2.8–5.6).
• Monosegmental grafts (Table 2): 120/330 were reported as monosegmental grafts (6,10,11,16,18,20,21,24). The vast majority were LDLT. Recipients were younger and there was a higher DRWR mismatch. Nevertheless, the actual graft weight and GRWR (3.3%) obtained were smaller than RLLS allowing to go below the 4% GRWR mark. Vascular complications (HAT and PVT) were no different nor was overall mortality. Only nine publications reported data regarding abdominal wall closure (177 patients). Primary closure was more frequent in MSG (47/49) (6,12,20,24) than in RLLS (70/103) (7,15,17,19,24), being the medial reduction (25/25) an exception (23).

Discussion

This is the first systematic review that evaluates the existing evidence with monosegmental and reduced LLS grafts in paediatric liver transplantation over the last 25 years. There is a former manuscript published in 2005 focusing on 7 papers and including 27 MSG, arguably labelled as a meta-analysis (29,31-36).

The studies evaluated were quite heterogenous, including single case reports (6,10) and large series. Five of the sixteen studies (18,19,22-24) represented 82% of the total population (Table 1). In addition, the age ranged from 5 days to 22 months. Some studies included only neonates (7,15) while the rest included infants as well.

The overall median weight of this cohort was 5.8 kg (2.6–8 kg) and it clearly represents a complex group of recipients where a significant DRWR mismatch can be expected. This might result not only in a compartment syndrome but can also compromise the inflow and outflow of the graft. Some authors refer to this scenario as a large-for-size syndrome (2-6).

Are the results of surgically manipulating the LLS comparable to the standard LLS?

This cohort of 330 modified LLS, albeit heterogenous, provided an overall graft and patient survival of 84% and 89% with a median FU of 39 months (3 years). The incidence of HAT and PVT were 1.5% and 4.2%. Direct comparison with standard LLS is difficult given historical bias and large series will include a wide range of age and weights. In fact, the comparison should be made against recipients with similar weight (5 kg) receiving a standard-whole LLS. A significant consequence in this later approach would be the need for delayed/secondary abdominal wall closure, bridging the gap with a prosthetic or biological mesh (4,5).

Table 4 presents graft and patient overall survival from large series for comparison. Figures reported are not dissimilar to those in MSG and RLLS.

Are the different modalities for surgically manipulating a LLS comparable?

We found sixteen articles presenting several institutions’ strategies to address the issue of a severe GRWR mismatch. Out of 330 pLT, 37% were MSG and 63% RLLS.

At birth, the liver represents close to 3.5% of our Total Body Weight (range, 2.1–4.7), to then gradually become 2–1.5% (range, 1.8–2.8) in individuals >17-year-old (42). An adult LLS might represent 16% (±4) of the Standard Total Liver Volume (1,518±353 cc), averaging 242±79 cc (31). Accordingly, a 5 kg child receiving a LLS graft, will likely face a GRWR close to 5% (1:1 equivalence between cc and grams). It is well documented that GRWR is a strong predictor of graft survival and the vast majority of reports concur that those grafts exceeding 4% will likely generate a conflict with the abdominal cavity’s capacity (4,5,12,16-20,23,25,43-45). Hence, some groups advocate for altering the LLS, reducing or converting it into a monosegment. One should however avoid adopting a very dogmatic view based only on volume, since several other factors (ascites, sarcopenia and specially graft thickness) will have a role in deciding (the myth of 4?) (46). Even though the first MSG was reported by Strong in 1992, there is a clear preference for this technique in Japan, whereas reduction seems more prevalent in western countries. When both techniques were compared, some differences were encountered (Table 2). Recipients of MSG were younger and lighter with a bigger DRWR mismatch and yet, MSG produced smaller grafts (median of 160 grams), finally achieving a GRWR below 4%. Primary abdominal wall closure was more likely too. The lines of transection for MSG are clearly different from reducing a graft and hence “off-sets” volume and thickness, the only exception being the Medial Reduction described by Hirata et al. (23). Several authors (20,21,23) factor on the direct thickness measurement of the graft (median value 6 cm in this SR) or the GRDR (cm from left hepatic vein to PV bifurcation on preop CT imaging) (21) to select their surgical strategies. Results, in terms of vascular complications and overall survival, were similar (Table 3). In addition, one must take into consideration that MSG were by and large obtained in-situ from LDLT (94%), with all the technical complexity added, in particular shorter and smaller arteries compared with RLLS in DD, where often the celiac axis is left with the LLS.

Limitations

The results of the present study should be interpreted in the context of its limitations. Assessment of bias within the included studies using ROBINS-I tool demonstrated that the overall quality varied from moderate to low and confounding, selection and detection bias might have affected the results. Furthermore, seven out of sixteen studies included less than 10 patients (6,7,10,11,14,17,20). Five studies (three from Japan, India and Argentina) represented the 67% of the total sample (18,19,22,23). The time span of the included studies extended over 25 years period. Therefore, institutional, national, underpowered sample, selectional, detection and learning curve bias might have influenced the results.

Conclusions

The large majority of reports included in this SR would recommend aiming for a GRWR <4% to reduce the risks of a large-for-size scenario. RLLS and MSG are both optimal options to facilitate pLT to a very small recipients with results comparable to standard LLS despite the technical complexities. MSG will be able diminish volume and thickness providing the smallest possible graft, in particular Segment 2. Special mention deserves the Medial Reduction which effectively constitutes a non-anatomical reduction of Segment 3 altering volume and thickness and allowing primary closure.

Experience is paramount and needs to be considered in, for these techniques to be seen as an established modality of treatment.

Acknowledgments

Funding: None.

Footnote

Reporting Checklist: The authors have completed the PRISMA reporting checklist. Available at https://hbsn.amegroups.com/article/view/10.21037/hbsn-20-792/rc

Conflicts of Interest: Both authors have completed the ICMJE uniform disclosure form (available at https://hbsn.amegroups.com/article/view/10.21037/hbsn-20-792/coif). The authors have no conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.

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