Cost-effective, personalized, 3D-printed liver model for preoperative planning before laparoscopic liver hemihepatectomy for colorectal cancer metastases

Although 3D printing technology has been introduced in surgical disciplines as an alternative tool for preoperative planning, it is still not routinely used. Most 3D models are currently constructed as pre-surgical tools in maxillofacial and orthopedic surgery [1], primarily due to low costs and the simple structure of the models. The use of 3D models is expected to be beneficial in general/gastrointestinal surgery. Pre-surgical guides are considered particularly helpful in procedures requiring highly accurate visualization of anatomy and can be more favorable in comparison to standard imaging techniques. Potential advantages include shorter operative time, recovery time [2, 3], reduced blood loss and better resection margins [3, 4]. 3D-printed models have also been shown to be more beneficial in preoperative planning than 3D-rendered images [5].

High cost is a major limitation in the application of three-dimensional (3D) printing to the practice of medicine [6, 7]. This is mainly due to the need for complex models consisting of more than one material type, to be proven useful in planning a demanding surgery. Very expensive (over $200,000 [8]) industrial-grade printers and an insufficient number of experts, familiar with both medical and technological concepts, have prevented healthcare providers from using 3D models in everyday surgical procedures.

We describe the development of a 3D-printed model of the liver of a patient with colorectal cancer metastasis using a cost-effective method, relatively inexpensive materials, commercial-grade printers and open-source and freeware software. Additionally, the methods described herein provide material control and precision comparable to the best current methods. To our best knowledge, this is the first full-sized liver model prepared with innovatory approach described in this article, which allows to create transparent liver models with use of low-cost fused deposition modeling (FDM) printing technique and silicone. So far, the only cost-effective liver models that have been generated have represented single hepatic vessels or portal vein, not showing them as a whole anatomy of the area [9]. Not parenchyma nor tumors have been shown in these early attempts of low-cost 3D liver modeling. Other applications of 3D printing in liver surgery have been based primarily on significantly less affordable PolyJet/MultiJet [6, 10, 15] or selective laser sintering (SLS) [13] techniques.

We present a case of a 52-year-old female patient (BMI 29.5 kg/m\(^{2})\) who underwent laparoscopic colorectal resection (T3N1M0) for colonic adenocarcinoma with adjuvant chemotherapy. In follow-up computed tomography (CT) 2 years after primary resection a single metachronous metastasis has been found. The patient has been submitted to laparoscopic right hemihepatectomy. Prior to surgery a 3D model of the patient’s liver has been printed using the technique described below.

The process of model development consists of four major phases: object segmentation, 3D model computer processing in common view, slicing and 3D printing, finishing and assembly with silicone curing (Fig. 1).

The final outcome of the process was a life-sized liver model with a transparent parenchyma, colorful plastic vessels and a tumor inside (Fig. 5).

The cost of production of a model similar to the one presented in this paper is estimated to be under $150 (Table 1). We estimate a total time of development, from segmentation to final object, to be around 160 h. Model was delivered to the surgical team scheduled to perform the procedure 5 days prior to the surgery. Surgeons had visually and tactilely inspected models and discussed the case, including the operative plan, with the aid of 3D model. The model was also available to the surgeon to be used as a intraoperative guidance tool.

The patient underwent fully laparoscopic right hemihepatectomy. The operative time was 270 min., intraoperative blood loss was 150 ml. Postoperative course was uneventful. Postoperative histopathologic evaluation confirmed R0 resection of the liver metastasis.

Models prepared with the described approach can be used to prepare surgeons for demanding procedures, such as laparoscopic resection of a colorectal cancer metastasis, in this case. Models would also be applicable for education of students and patients. The patient underwent subsequent hemihepatectomy.

This approach utilizes of one of the most affordable 3D-printing methods, FDM, to prepare complex models. Models using previous “standard” techniques had estimated prices of approximately $1000 for a liver model [10] and $500 for a kidney [11] model. Thanks to cost-effective approach, it seems possible to implement this solution in most hospitals worldwide. The technique can be executed by physicians after a relatively short training period.

3D-printed models are used in surgery to plan and prepare for extensive procedures, as a intraoperative guidance as well as an anatomy and pathology training tool [1]. Not only do models help surgeons, but they can also be used in many out-of-surgery applications, including education of students and young doctors in subjects such as anatomy, pathology, and surgery [12, 13] and in patient education [14]. All these make this low-cost method described in this paper feasible and justified among healthcare providers to implement 3D printing in clinical situations, which was previously available only to a limited number of hospitals.

Physical models also may be found more beneficial than 3D-rendered images. Virtual models do not represent structures in 1:1 scale, they also tend to be difficult to interpret in cases with complex anatomy, especially when evaluating the course of blood vessel branches. Although, there are only a few studies on this topic [5].

To date, PolyJet/MultiJet (photopolymer-based) or, more rarely, stereolithography (SLA) technologies have primarily been used to prepare similar models for pre-surgical preparation. However, PolyJet printers are industrial-grade, and their price varies from $6000 (low-end printers) to over $200,000 [8]. The high-end printers have been used to create pre-surgical anatomical models [11, 15]. Desktop 3D FDM printers are generally available starting from few hundred dollars and range up to $5000 for new-generation, relatively sophisticated FDM printers [16].

Accuracy of our model is affected by several factors. First, the resolution of the CT images most likely has the largest effect on the outcome. Some studies report that when a slice thickness of 2.5 mm is used, as in the present case, the liver volume may be underestimated [17]. However, semi-automated segmentation, as was presented in this paper, is reported to slightly overestimate the volume [18]. Computer processing and PLA finishing may have some effect on the volume, as some studies report 3D smoothing contributes to model shrinking [19], similar to coating PLA surfaces with thin layers of resin. Most of the described components mainly affect the parenchyma rather than the vessels or the tumor. Accurate calculations and dimension comparisons should be performed under conditions that allow for the measurement of the actual size of the liver. The ideal scenario for these measurements would be a transplantation surgery.

The accuracy of the model can be improved. For example, different algorithms can be utilized for segmentation, and CT scans with a lower thickness should be tested.

This technique requires creation of multiple parts of one object (for example, the liver parenchyma) to assemble the model, cast the silicone inside, and demount external parts afterward. Printing an entire model from one STL object would result in printouts filled with support material that would be impossible to remove. Additionally, it would not be possible to remove external parts to obtain the liver-shaped silicone parenchyma. This “multipart approach” also avoids limitations of the small printing field. Many 3D printers have printing field sizes smaller than 200\(\,\times \,\)200 mm, which is usually smaller than a full-sized liver. The full size models may be printed due to division. Many previous researchers describe the inevitability of scaling down models due to cost or printer limitations [10]. Moreover, smaller parts are usually easier to print (fewer artifacts and simpler removal of support material).

To date, few reports have described methods to correctly arrange multipart, complex structures, and some have reported the use of positioning joints and pins [20]. Our solution, using Boolean-based parts, is in our opinion accurate and does not disrupt the original structure.

Compared to significantly more expensive methods, our technique is slower (print time of 60–100 h compared to 36–40 h [6, 10]). However, the printing time can be reduced by half or more with the use of multiple printers, which still would be far more cost-effective. In addition, PLA printouts are more fragile than PolyJet-based printouts, especially during postprocessing. In addition, the assembly must be very accurate due to the risk of silicone leakage and the loss of model precision.

Liver malignancies surgery is not the only application of this method or of 3D-printed models. The relatively long printing time may limit the use of this technique in emergency surgeries; however, elective procedures, which represent the majority of hepatic resections [21], can greatly benefit from this 3D printing method.