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Canadian Urological Association Journal logoLink to Canadian Urological Association Journal
. 2013 Jan 23;7(1-2):E38–E44. doi: 10.5489/cuaj.12018

Review of the efficacy and safety of cryoablation for the treatment of small renal masses

Anil Kapoor *,, Naji J Touma , Regina El Dib §
PMCID: PMC3559618  PMID: 23401737

Abstract

Purpose

Small renal masses are increasingly being discovered incidentally on imaging for another reason. The standard of care of these masses involves excision by open or laparoscopic techniques. Recently, ablative techniques, such as radiofrequency ablation (RFA) and cryoablation, have taken a more prominent role in the treatment algorithm of these masses. We evaluate the effectiveness and safety of cryoablation to treat renal tumours.

Methods:

A review of the literature was conducted. There was no language restriction. Studies were obtained from the following sources: the Cochrane Library, PUBMED, EMBASE and LILACS.

Results:

There was no clinical trial identified in the literature. Thus, we described the results from 23 case series and retrospective studies with a reasonable sample size (number of reported patients in each study ≥30), with a total of 2104 analyzed tumours from 2038 patients. There was wide variability in the outcomes reported, but success rates were generally good. Follow-up was generally short, but some series reported outcomes at 5 years. The most common complications reported were hemorrhage (some of the patients requiring transfusion), perinephric hematoma and urine leaks.

Conclusion:

Cryoablation presents a feasible treatment for patients with small renal masses. Only short-term data are available and, as such, meaningful conclusions regarding long-term cancer control cannot be made. More rigorous studies are needed.

Introduction

In Canada, the incidence of renal cancer is 4500 new cases per year, with 1500 dying of the disease.1 Small renal masses are increasingly being discovered incidentally on imaging for another reason.2,3 The natural history of these incidentally discovered masses remains unclear. When surgically excised, the masses are shown to be 70% to 80% renal cell carcinoma (RCC), and the rest are benign.47

When technically feasible, the standard of care for these masses has been partial and radical nephrectomy. Local and distant oncological control has been well-established with surgical excision.8 In the last 10 years, a minimally invasive approach with laparoscopy has largely supplanted open surgery. The question of whether in situ ablative technologies9,10 can replace excision for the treatment of small renal tumours remains unanswered. The main advantage of ablative techniques would be to offer treatment to patients who are otherwise not candidates for invasive extirpative techniques.11,12

Several ablative technologies have been investigated, including cryoablation (CA), radiofrequency ablation (RFA), microwave,13 high-intensity focused ultrasound,14,15 laser interstitial thermotherapy,16 microwave thermotherapy and radiosurgery.

Cryoablation has been used to treat human cancers since the 19th century, with the use of ice-salt mixtures to treat cervical and breast cancers.17 In urology, CA has long been used to treat prostatic diseases: first for benign prostatic hyperplasia in the 1960s,18 and later for prostate cancer.19 Freezing and thawing causes alteration in various biological processes that ultimately result in cell death. CA targets and kills specific cells and spares surrounding tissue, which can be critical in patients with compromised renal function and small RCC.

In the last few years, several series have reported the results of CA for small renal masses with short to intermediate follow-up. A meta-analysis of case series studies evaluating CA and RFA showed no significant difference regarding clinical efficacy (the authors defined it as cancer-specific survival rate, radiographic success, no evidence of local tumour progression or distant metastases) and intraoperative and postoperative complications rates between both interventions.20

In this review, we examine the efficacy of CA to treat renal tumours. The efficacy of this technology in terms of oncological control and prevention of local recurrence and metastasis is reviewed. Complications and safety concerns as they relate to CA will also be reported.

Methods

There was no language restriction. Trials were obtained from the following sources: Cochrane Central Register of Controlled Trials (Central, The Cochrane Library, issue 1, 2011), US National Library of Medicine (PUBMED; 1966–2011), Excerpta Medica database (EMBASE; 1980–2011), Literatura Latino-Americana e do Caribe em Ciências da Saúde (LILACS; 1982–2011) and the Current Controlled Trials to identify all studies regarding cryoablation in RCC.

The databases were searched using a comprehensive search strategy for kidney cancers and cryoablation, along with MeSH and text words, including an exhaustive list of synonyms (Table 1). The search strategy was adapted for each database to achieve more sensitivity. The bibliographic references in relevant review articles were also examined for eligible trials. The search was performed up to January 2011. In total, 696 titles were identified from the electronic databases. After screening by title and then abstract by two reviewers, full paper copies for 64 studies that were potentially eligible for inclusion in the review were obtained. The remaining 632 were off-topic, animal research, narrative reviews or in vitro studies. No randomized trials were identified, and therefore, the results from case series and retrospective studies with a reasonable sample size (number of reported patients in each study ≥30) were included in this review.

Table 1.

Summary of the bibliographic search strategies for type of clinical situation and intervention of interest.

(Kidney Neoplasm) OR (Renal Neoplasms) OR (Renal Neoplasm) OR (Kidney Neoplasms) OR (Cancer of Kidney) OR (Kidney Cancers) OR (Renal Cancer) OR (Renal Cancers) OR (Cancer of the Kidney) OR (Kidney Cancer) OR (Kidney Cancers) OR (Renal masses) OR (Renal cell carcinoma)) AND (Cryosurgeries OR Cryosurgery OR Cryoablation OR Cryoablations OR Cryotherapy)
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The following clinical outcome measurements were examined: cancer-specific survival, radiographic success, tumour recurrence, local tumour progression or distant metastases, need for repeat ablation, complications, adverse events and renal function.

Results

Table 2 summarizes the characteristics of published studies on CA. Most patients undergoing CA had T1a disease with a mean tumour size ranging from 1.8 to 4.2 cm. The laparoscopic approach was the most commonly used approach, although the percutaneous and open approaches were also employed. The maximum mean and median follow-up reported was 45.7 months and 36 months, respectively.

Table 2.

Case series and retrospective studies on cryoablation for renal tumours

Study Design of study Comparative intervention Patients (n) Tumours (n) Mean tumour size or range on preoperative (cm) Tumour type Exophytic Parenchymal, xcentral, mixed or others Laparoscopic or Percutaneous Cryoablation Follow-up (months)
Atwell 200833 Retrospective N/A 110 115 3.3 56 59 Percutaneous 13.3b
Finley 200834 Retrospective N/A 37 43 2.9 6 36 Percutaneous and laparoscopic 12.8b
Georgiades 200835 Case series N/A 46 40 3.0c NR Percutaneous 28c
Hinshaw 200836 Retrospective N/A 90 90 Perc. 2.1
Lap. 2.5		 NR Percutaneous and laparoscopic Perc. 14.5b
Lap. 16.5b
Lehman 200837 Retrospective N/A 44 51 Group 1d 1.8
Group 2d 4.0		 32 19 Laparoscopic Group 1:9.0b
Group 2: 11.0b
Nguyen 200838 Retrospective comparative RFA CA 14
RFA 22		 CA 25
RFA 38		 CA 3.0
RFA 2.8		 NR Laparoscopic and open NR
Weight 200839 Retrospective comparative RFA CA 176
RFA 88		 CA 192
RFA 109		 CA 2.4
RFA 2.5		 NR CA 30
NR RFA 42		 Laparoscopic 6
Atwell 2007a,b3941 Retrospective N/A 40 40 4.2 15 25 Percutaneous 9b
Bandi 200742 Retrospective N/A 78 88 2.6 NR Percutaneous and laparoscopic 19b
Cestari 200743 Retrospective N/A 86 56 2.3 NR Laparoscopic 24
Littrup 200744 Retrospective N/A 48 49 3.3 30 19 Percutaneous 1.1c
Lokken 200730 Retrospective comparative RFA 253 287 3.0 NR Percutaneous 52
Weld 200745 Case series N/A 31 36 2.1 27 09 Laparoscopic 45.7b
Wright 200729 Retrospective N/A 32 35 1.9 32 03 Laparoscopic 18c
Davol 200646 Retrospective N/A 48 48 2.6 44 04 Laparoscopic and open 64b
Hegarty 200647 Retrospective comparative RFA CA 161
RFA 72		 CA 179
RFA 81		 CA 2.56
RFA 2.51		 NR
NR		 CA 6%
RFA 37%		 Laparoscopic CA 36c
RFA 13c
Lawatsch 200648 Case series N/A 59 81 2.5 NR Laparoscopic 26.8c
Matin 200649 Retrospective comparative RFA CA 8f
RFA 55f 		N 3.85 39% 61% Percutaneous and laparoscopic 24.2b
Schwartz 200650 Retrospective N/A 84 85 2.6 NR Laparoscopic and open 10b
Desai 200551 Retrospective comparative LPN CA 78
LPN
153		 CA 89
LPN 153		 CA 2.05
LPN 2.25		 NR Laparoscopic CA 24.6b
LPN 5.8b
Gill 200527 Case series N/A 56 60 2.3 NR Laparoscopic 36
Cestari 200452 Case series N/A 37 NR 2.5 NR Laparoscopic 20.5b
Gill 200053 Case series N/A 32 34 2.3 NR Laparoscopic 12
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RFA: Radiofrequency ablation; LPN: Laparoscopic partial nephrectomy; CA: cryoablation; N/A: not applicable; NR: not reported.

a

A subset of these patients have been included in 2 prior publications (Atwell 2007a and Atwell 2007b);

b

Mean;

c

Mean;

d

In Group 1 the patients presented with a maximum tumour diameter less than 3.0 cm and, group 2 patients had a maximum tumour diameter of 3.0 cm or larger;

e

Atwell 2007 has two publications with the same participants;

f

Patients with residual or recurrent disease.

Table 3 shows the clinical outcomes and complications reported in the examined CA studies. Cancer-specific survival, recurrence tumour rates and radiographic or technical success were the most commonly used outcomes to evaluate oncological control. Lack of contrast enhancement, decrease in tumour size, or lack of growth on serial imaging were considered signs of complete and successful ablation. The maximal and minimal percentage of cancer-specific survival reported was 100% and 84.3% in a follow-up of 11.4 months (median) and 64 months (mean), respectively. The most commonly reported complications were: hemorrhage (some of the patients requiring transfusion), perinephric hematoma and urinary leak. Nonetheless, the procedures seem to be well-tolerated.

Table 3.

Clinical outcome and complications of each included studied

Outcomes Complications*
Study Clinical outcome studied Occurrence (%) Major complications Minor complications
Atwell 200833 Technical successa following a single ablation session 97% Worsening preexisting hypertension (0.90%); pulmonary edema (0.90%); large hematomas requiring angiography and transfusion of red blood cells (2.7%); pulmonary embolus (0.90%)and hematuria requiring ureteral stent placement (090%)
Finley 200834 CSS among patients with biopsy proven RCC during a median follow-up of 11.4 and 13.4 months
100% and 100% Hemorrhage requiring transfusion (13.5%); blood transfusions (16.2%); internal jugular vein thrombus (2.7%); small bowel injury (2.7%) and loss of kidney (2.7%)
Treatment failure rateb among patients with biopsy proven RCC during a median follow-up of 11.4 and 13.4 months 5.3% and 4.2%
Georgiades 200835 Technical successc 100% Silent, small perinephric hematoma; large, painful perinephric hematomas; intercostal nerve injury; genitofemoral nerve injury;
Overall CRd 97.5%
Hinshaw 200836 Effectiveness ratee for laparoscopic CA 93.3% Severe respiratory distress (1.1%); intraoperative bowel injury (1.1%) and postoperative atrial fibrillation (1.1%) Asymptomatic perinephric hematoma; asymptomatic and self-limited urine leak; self-limited flank paresthesia and neuralgia; and intercostal neurapraxia (4.4%).
Lehman 200837 Tumour recurrences Group 1: 0% Group 1: no complications (0%)
Group 2: 4.8% Group 2 (62%): mortality (4.5%); cerebrovascular accident; myocardial infarction; pulmonary embolism and; hemorrhage with blood transfusion
Nguyen 200838 Tumour recurrences CA 7.4%
RFA 25%		 Intraoperative complications: CA: renal arterial injury (21%);
RFA: no major intraoperative complications reported on this group (0%)		 Intraoperative complications: CA: diaphragmatic injury (7.1%); pleurotomy (requiring chest tube) (7.1%) and peritoneotomy (21%)
RFA: no major intraoperative complications reported on this group (0%)
Postoperative complications: CA: no major postoperative complications reported on this group (0%). Postoperative complications: CA: urinary leak and anephric state (7.1%).
RFA: no major postoperative complications reported on this group (0%). RFA: no major postoperative complications reported on this group (0%).
Weight 200839 Radiographic successf at 6-months follow-up CA 90%
RFA 85%		 NR NR
Radiographic successf with biopsy and 6-months imaging CA 89%
RFA 81%
Atwell 2007a,b40,41 Technical successg 95% Large hemorrhage and transient renal failure (necessitated temporary dialysis) (2.5%)
Bandi 200742 Overall, CSSh and RFSi rates 88.5%, 100% and 98.7%, respectively Atrial fibrillation (1.2%); respiratory failure (1.2%) and; urine leak (1.2%); bleeding (1.2%); bowel injury (1.2%); symptomatic perirenal haematoma (1.2%) and neurophatic pain (1.2%)
Cestari 200743 NR NR Minimal intraoperative blood loss (100%); intraoperative renal fracture (2.3%); postoperative anemia (8.1%); transitory hyperpyrexia (6.9%); hematoma (2.3%); pulmonary edema (1.1%); gross hematuria (1.1%) and ureteropelvic junction obstruction (1.1%)
Littrup 200744 Technical successj 98% Perinephric hematoma; hematuria and ureteral stricture. Major and minor complications were seen in 6% and 22% procedures, respectively
Lokken 200730 Occurrence of applicator track nodules CA 2.7% CA: small perinephric hematoma (0.3%)
RFA 1.7% RFA: self-limited hematuria and small perinephric hematoma (0.3%)
Weld 200745 3-year CSS rate 100% Hemorrhage (3.2%); urinary leak (3.2%); gross hematuria (3.2%); ileus (3.2%); perinephric urinoma (3.2%); hydronephrosis (3.2%); blood clots (3.2%); atrial fibrillation (3.2%); and heart failure (3.2%)
Mean increase of ablation zone size on follow-up CT or MRI at 3 months. 14
Mean decrease of ablation zone size on follow-up CT or MRI at 3 months 71
Wright 200729 Treatment failuresk 6% No major and minor complications were found (0%)
Davol 200646 Complete radiologic resolutionl from a total of 40 patients available in the analysis 85% There were no major adverse events found (0%) There were 7 minor adverse events (14.5%)
Treatment failurem from a total of 40 patients available in the analysis 12.5%
CSS rate in a total of 32 patients 100%
CSS rate after a single CA procedure in a total of 32 patients 84.3%
Hegarty 200647 Radiologic evidence of tumour recurrence or persistence of disease; CA 1.8% CA: congestive heart failure (0.62%); myocardial infarct (0.62%); required thoracotomy for hemothorax (0.62%). CA: required temporary ureteral stent insertion (1.2%)
RFA 11.1%
CSS CA 98% at a median 3-year follow-up RFA: no major complications were reported in the RFA group (0%). RFA: NR
RFA 100% at 1-year median follow-up
Lawatsch 200648 Overall tumour recurrence rate per patient 5.9% in 34 patients Intraoperative complications: open surgery conversion (3.3%); nephrectomy for bleeding (1.6%); myocardial infarction (1.6%); pneumothorax (3,3%)
Recurrence rate per lesion treated in patients with biopsy confirmed RCC 5.1% for 38 lesions Postoperative complications: perinephric hematoma (1.6%); pulmonary embolus (1.6%) and ileus (3.3%)
Matin 200649 Overall survival rate in all patients from both groups 82.5% NR NR
2-year metastasis-free survival rate in all patients from both groups 97.4%
Schwartz 200650 No growth or evidence of recurrence on CT scan or MRI at 3 months 98.18% Renal fracture (1.2%); stroke (1.2%) and hydronephrosis (1.2%)
Radiographic enhancement after the procedure 3.6%
Desai 200551 Local recurrence at a mean follow-up time of 5.8 months in LPN group and 24.6 months in CA group LPN 0.6% LPN associated with greater blood loss and a higher incidence of delayed complications after hospital discharge compared with CA 16.3% versus 2.2%, respectively
CA 3%
Gill 200527 3-year CSS (in a total of 51 patients with sporadicunilateral renal tumour) 98% NR NR
Cestari 200452 Mean reduction of cryolesions on MRI 12 and 18 months of follow-up 73% and 76% (in a total number of patients 32 and 30, respectively) Transitory hyperthermia (8.1%); hematoma (8.1%); gross hematuria (2.7%); low postoperative pain (100%); and ureteropelvic junction obstruction (2.7%)
Gill 200053 Follow-up CT-directed needle negative biopsies at 3 to 6 months in a total of 23 patients 100% Perirenal hematoma (3.1%) and herpes esophagitis (3.1%)
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CSS: cancer-specific survival; RCC: renal cell carcinoma; CR: complete response; CA: cryoablation; RFA: radiofrequency ablation; RFS: recurrence-free survival; CT: computed tomography; MRI: magnetic resonance imaging.

*

Percentages were calculated on a patient number basis;

a

Extension of the ice ball beyond the tumour margin and post-ablation images showing no contrast enhancement in the tumour parenchyma;

b

Not defined;

c

Completion of the cycle of a 10-minute freeze, 8-minute active thaw, and 10-minute repeat freeze with the ice ball covering the entire lesion and extending at least 5 mm beyond its border;

d

Complete lack of enhancement of a previously enhancing mass;

e

Complete ablation of macroscopic tumour as shown at imaging follow-up;

f

No evidence of central or nodular enhancement after treatment;

g

Extension of the ice ball beyond the tumour margin and postablation imaging findings of no contrast enhancement in the area encompassing the original tumour;

h

Absence of death from renal cancer;

i

No evidence of radiographic recurrence at the site of CA, regardless of the lesion pathology;

j

Not defined;

k

Continued contrast enhancement on postoperative CT;

l

An involuted scar or fibrosis without evidence of growth or enhancement on the most recently available imaging study;

m

Growth of a persistent renal mass, as well as the persistence or development of heterogeneous peripheral enhancement within any persistent mass.

Discussion

The principle of tissue freezing with CA involves the Joule Thomson phenomenon, whereby rapid cooling results from the rapid phase change of a highly compressed liquid expanding through a restricted orifice to a gaseous state. The mechanism of cellular injury by CA is a result of direct and indirect physiological processes. When the extracellular fluid freezes, there is an increase in osmotic pressure in the extracellular compartment. The resulting fluid shift causes cellular dehydration, accumulation of toxins within the cells, change in pH and denaturation of proteins. The disruption of the cellular membrane leads to crystallization of the intracellular fluid. In addition, endothelial damage leads to ischemia, thrombosis and coagulative necrosis, synergizing cell death.21,22

Imaging with computed tomography (CT) scans or magnetic resonance imaging (MRI) is the typical follow-up for cryoablated tumours, although a specific follow-up protocol has not been widely accepted. Tumour size may increase in early follow-up due to peri-tumour hemorrhage, and the difficulty in determining tumour margin from surrounding fibrosis and stranding.2325 However, any enhancement on CT scan (>10 HU) or a progressive increase in tumour size is a sign of inadequate ablation. On MRI, 61% of adequately treated tumours are isointense to renal parenchyma on T1-weighted images, and 95% are either isointense or hypointense on T2 weighted images.26 It remains unclear if radiological follow-up either by CT scan or MRI constitutes an adequate surrogate for local cancer control. Preoperative biopsies of these renal masses were uncommon in most series, even less so postoperative biopsies. One exception was the series by Gill and colleagues; the authors routinely performed biopsies at 6 months post-CA. In this series, 2 out of 56 tumours proved to be positive at 6 months post-CA, for a rate of 3.6%.27 In a prostate cancer model, where CA has been more extensively studied, positive biopsies post-CA have been found in up to 23.1% of patients in a post-radiotherapy CA model.28 While it may be stipulated that the prostate cancer model is not necessarily an apt comparison given the multi-focal nature of prostate cancer versus a solid renal neoplasm, the lack of data confirming complete ablation and necrosis of the treated renal tumours leaves this technique open to question regarding equivalence to more accepted extirpative methods.

This review demonstrates a wide variability in the definition of outcomes (i.e., technical success, radiographic success, local recurrence and cancer specific survival). Cancer-specific survival can be as low as 84.3%,29 and radiographic resolution as low as 71%,30 even with relatively short follow-up intervals. When juxtaposed with the fact that 20% to 30% of small renal masses are found to be benign when excised, the true efficacy of CA should be assumed to be lower than reported.47 This highlights the need for longer follow-up, and for comparative trials with partial nephrectomy, or other ablative technologies, such as RFA.

CA is generally well-tolerated, but laparoscopic access is the most common technique. When compared to a partial nephrectomy, it has the advantage of not requiring hilar clamping, vascular and collecting system repair. However, a general anesthetic, and a pneumoperitoneum with all inherent complications remain essential. Hemorrhage, urinary leaks and injury to adjacent organs are all potential adverse events.

From a financial standpoint, CA compares favourably with other modalities for treatment of renal tumours. A financial analysis compared minimally invasive surgery procedures, such as laparoscopic cryoablation, laparoscopic partial nephrectomy and hand-assisted laparoscopic nephrectomy, versus conventional surgery. The open radical nephrectomy had higher total hospital costs ($15 498), followed by laparoscopic partial nephrectomy ($15 458). The lowest total hospital costs was laparoscopic cryoablation ($10 105) for renal tumours smaller or equal than 3.5 cm.31 However, in a more robust Markov model which factored the costs of follow-up and re-treatment, an immediate laparoscopic ablation procedure was found to be dominated by laparoscopic, and open partial nephrectomy for healthy patients less than 74 years old in terms of Quality Adjusted Life Years (QALY). Even in patients with multiple comorbidities, observation followed by possible delayed percutaneous ablation dominated immediate laparoscopic ablation.32

Conclusions

The results of this review show that cryoablation is a feasible treatment for patients with small renal masses. Long-term follow-up is lacking, but the available short-term data demonstrate a significant re-treatment rate. Given the lack of long-term follow-up, the technique should be reserved for elderly patients, or those with significant comorbidities, whose masses have demonstrated growth after a period of observation. Otherwise, partial nephrectomy remains the gold standard.

Continued research on cryoablation in the treatment of small renal tumours is needed, especially comparative trials with partial nephrectomy and other ablative technologies, such as RFA.

Footnotes

Competing interests: None declared.

This paper has been peer-reviewed.

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