pISSN 2005-9159
eISSN 2093-0569

Clinical Research Article

Korean J Pain 2022; 35(2): 183-190

Published online April 1, 2022 https://doi.org/10.3344/kjp.2022.35.2.183

Copyright © The Korean Pain Society.

Comparison of ultrasound guided pulsed radiofrequency of genicular nerve with local anesthetic and steroid block for management of osteoarthritis knee pain

Babita Ghai1 , Muthu Kumar1 , Jeetinder Kaur Makkar1 , Vijay Goni2

1Department of Anaesthesia and Intensive Care, Postgraduate Institute of Medical Education and Research, Chandigarh, India
2Department of Orthopedics, Postgraduate Institute of Medical Education and Research, Chandigarh, India

Correspondence to:Jeetinder Kaur Makkar
Department of Anaesthesia and Intensive Care, Postgraduate Institute of Medical Education and Research, Madhya Marg, Sector 12, Chandigarh 160012, India
Tel: +8847288105
Fax: +0091-172-2744401
E-mail: jeet1516@gmail.com

Handling Editor: Eunsoo Kim

Received: May 18, 2021; Revised: November 15, 2021; Accepted: December 7, 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Background: To compare ultrasound-guided pulsed radiofrequency (PRF) of the genicular nerve with the genicular nerve block using local anesthetic and steroid for management of osteoarthritis (OA) knee pain.
Methods: Thirty patients with OA knee were randomly allocated to receive either ultrasound-guided PRF of the genicular nerve (PRF group) or nerve block with bupivacaine and methylprednisolone acetate (local anesthetic steroid [LAS] group). Verbal numeric rating scale (VNRS) and Western Ontario McMaster Universities Osteoarthritis Index (WOMAC) scores were measured at pre-procedure and 1-, 4-, and 12-weeks post-procedure.
Results: VNRS scores decreased significantly (P < 0.001) in both the groups at 12 weeks and other follow up times compared to baseline. Seventy-three percent of patients in the PRF group and 66% in the LAS group achieved effective pain relief (≥ 50% pain reduction) at 12 weeks (P > 0.999). There was also a statistically significant (P < 0.001) improvement in WOMAC scores in both groups at all follow up times. However, there was no intergroup difference in VNRS (P = 0.893) and WOMAC scores (P = 0.983). No complications were reported.
Conclusions: Both ultrasound-guided PRF of the genicular nerve and blocks of genicular nerve with local anesthetic and a steroid provided comparable pain relief without any complications. However, PRF of the genicular nerve is a procedure that takes much more time and equipment than the genicular nerve block.

Keywords: Anesthetics, Local, Chronic Pain, Knee, Nerve Block, Osteoarthritis, Pain Management, Pulsed Radiofrequency Treatment, Steroids, Ultrasonography, Interventional.

Knee pain secondary to osteoarthritis (OA) is a common problem in elderly patients. Symptomatic disease is found in 10% of men and in 13% of women more than 60 years of age [1,2]. In India, this disease is the most common cause of chronic pain with a prevalence of 23%–39% [3]. Various treatment modalities include conservative treatment and interventional procedures. Conservative therapy consists of nonpharmacologic modalities in the form of physiotherapy, orthoses, weight reduction, and use of pharmacologic options like acetaminophen, oral nonsteroidal anti-inflammatory drugs (NSAIDs), topical NSAIDs, and opioids [4,5]. Interventional procedures include non-surgical methods like intraarticular steroids, nerve blocks, etc. [6,7]. However, no modality has been proven to be superior in treating OA knee pain.

The knee joint is mainly supplied by four genicular nerves (GN): the superior medial genicular nerve (SMGN), the inferior medial genicular nerve (IMGN), the superior lateral genicular nerve (SLGN), and the inferior lateral genicular nerve (ILGN) [8]. These can be blocked with a combination of corticosteroid and local anesthetic (LA) or a radiofrequency (RF) treatment. RF can be done using conventional radiofrequency (CRF) or pulsed radiofrequency (PRF) [9]. In the CRF technique, tissue temperature reaches up to 60°C–80°C which causes lysis of the nerves with chances of motor fiber damage and deafferentation. On the other hand, in PRF, tissue temperature reaches up to a maximum of 42°C, and thus, there is no irreversible damage to the nerve, and less risk of deafferentation [1012].

CRF of the GN for the management of OA knee pain has resulted in significant pain reduction and functional improvement in randomised controlled trials [13,14]. On the other hand, PRF of the GN has been evaluated in a case series of 9 patients with 69% of patients reporting a > 50% reduction of their visual analogue scale (VAS) scores at 12 weeks [15].

GN block with CRF or local anesthetic steroid (LAS) block has been known as an effective interventional technique for patients with knee OA with or without total knee arthroplasty (TKA) in previous studies [1618]. However, head-to-head comparison of CRF to LAS has been done in only one study [18]. There is a knowledge gap in the comparison of the efficacy of PRF and LAS.

Hence, we decided to conduct this study to compare the effectiveness of PRF and LAS block of the targeted GN under ultrasonography (USG) guidance in OA knee patients not responding to conservative therapy for 12 weeks.

After the approval of the Institute Ethics Committee (approval number: NK/7153) and registration with Clinical Trials Registry - India (registration number: 014956), this study was conducted at a tertiary care center in northern India (Post Graduate Institute of Medical Education and Research, Chandigarh, India) from July 2017 to September 2018. After obtaining written informed consent, adult patients of either gender more than 18 years of age with knee pain were examined to ascertain their eligibility. Eligible patients with chronic knee pain of moderate/greater intensity, that is, a verbal numeric rating scale (VNRS) pain score > 5 for more than 3 months, a KL (Kellgren and Lawrence) Grade of 2 or more (Grade I: unlikely narrowing of the joint space, possible osteophytes, Grade II: small osteophytes, possible narrowing of the joint, Grade III: multiple, moderately sized osteophytes, definite joint space narrowing, and Grade IV: multiple large osteophytes, severe joint space narrowing), which does not respond to other treatment modalities were enrolled in this randomized controlled double-blinded study. Patients with acute knee pain, prior knee surgery, uncontrolled hypertension and diabetes, connective tissue disorders, neurological or psychiatric disorders, patients receiving intra-articular knee injection with steroid or hyaluronic acid within three months, and those with a history of bleeding disorder were excluded.

1. Pre-procedure evaluation and preparation

Consenting patients were evaluated pre-procedure to assess them for the proposed procedure. Patients were informed about probable risks and benefits as well as the importance of maintaining a pain diary. The patient was also informed about the VNRS for pain (0–10, 0 represents no pain and 10 represents the worst imaginable pain) and Western Ontario McMaster Universities Osteoarthritis Index (WOMAC) score. Demographic data including age, gender, body mass index, and duration of illness were recorded.

The WOMAC score has three categories: pain (five questions, possible subscale score 0–20), stiffness (two questions, 0–8), and physical functioning (17 questions, 0–68), with a minimum score of 0, and a maximum score of 96 [19].

2. Randomization and blinding

Patients were randomly allocated into two groups (the PRF group and the LAS group) using computer-generated random numbers, which were kept in sealed, opaque envelopes, numbered sequentially, and opened just before the procedure. In the PRF group, PRF of the targeted nerve was performed. In the LAS group, targeted nerves were blocked using bupivacaine and methyl prednisolone. The physician, who performed the procedure (BG/JKM), as well as the patient, were unaware of the group assigned. A blinding screen was placed between the patient’s head and the procedure shelf. An RF cannula was used for localization of the GN in both the groups. Sensory and motor stimulation was done in both the groups. In the PRF group, a RF probe was connected to a RF generator and PRF at the target nerves was performed for 3 cycles of 2 minutes each. In the LAS group, the start button was not initiated and the investigator waited for the same duration. Light music was played in both the groups to mask the RF machine alarm sound. Thereafter, patients in the PRF group received 2 mL of saline while in the LAS group patients received 2 mL of drug solution. Both the syringes were covered with silver foil. Further follow-up of the patients was carried out in the pain clinic by another investigator blinded to the group assigned (MK).

3. Localization of the GN

All procedures were performed in a pain operating theater under sterile conditions in the supine position. Appropriate monitoring (electrocardiography, pulse oximetry, and non-invasive blood pressure) was attached. Intravenous access was secured. To avoid discomfort to the patient, support was maintained under the popliteal fossa. Knees were scanned using a 5–12 MHz linear transducer (M-Turbo; FUJIFILM Sonosite Inc., Bothwell, WA). The SMGN, IMGN, and SLGN were located. The SMNG curves around the shaft of the femur and passes in between the adductor magnus tendon and femoral medial epicondyle then descends 1 cm anteriorly to the adductor tubercle. The IMGN is located horizontally around the tibial medial epicondyle and the insertion of the medial collateral ligament on the tibia.

The SLGN consistently travels in the superolateral side of the popliteal fossa in the horizontal course of the sciatic nerve to reach the medial aspect of the biceps femoris tendon and approximately 2.6 cm proximal to the lateral femoral epicondyle tip. During the procedure, the linear USG probe was kept sagittal to the medial side of the partially flexed knee and then the anatomic landmarks were imaged. For the SMGN, the transducer was placed sagittally over the femoral lateral epicondyle with the corresponding arterial pulsation of the superior lateral genicular artery. SLGN was targeted around 2.6 cm proximal to the lateral femoral epicondyle tip. The ILGN was not targeted due to its proximity to the common peroneal nerve, which might have resulted in the risk of motor blockade [20]. Before proceeding, a LA was infiltrated at each of the marked points using 25-gauge insulin needles, loaded with 1 mL of 2% lidocaine.

4. The PRF group

After localization of the SMGN, IMGN, and SLGN using USG guidance, a 22-gauge, 10 cm RF cannula (Cosman CannulaTM; Cosman Medical Inc., Burlington, MA) with a 10 mm active tip was progressively advanced at the corresponding target point described using an in-plane approach. An RF electrode was introduced into each cannula and was connected to an RF generator (Cosman G 4 generator; Cosman Medical Inc.). Sensory stimulation (50 Hz) of up to 1.0 V was performed at each targeted nerve separately. Similarly, the motor response was checked by application of motor stimulation (2 Hz) at 2 V to each cannula. PRF of the target nerves at 42°C and 45 V was performed for 3 cycles of 2 minutes each at all three GN. Two cubic centimeters of normal saline was then injected in a syringe covered with silver foil.

5. The LAS group

Following GN localization using an RF needle, the probe was introduced. Sensory and motor stimulation was applied. The operator waited for the same duration without activating the RF generator and 2 mL of a solution consisting of 1.5 mL of 0.5% bupivacaine and 0.5 mL (20 mg) of methylprednisolone (1 mL = 40 mg, DEPO-MEDROLTM injection; Pfizer products India Pvt. Ltd, Mumbai, India) was injected in a syringe covered with silver foil.

Patients were assessed for any adverse event during the procedure such as intravascular injection, paresthesia as well as sensory and motor deficits.

6. Follow up

Patients were sent home with analgesics (aceclofenac 100 mg twice daily) for three days. All patients were advised to do stretches and strengthening exercises initially, and endurance training later, by a physical therapist. After 3 days, a fixed-dose combination of tramadol (37.5) + paracetamol (375 mg) was used as rescue analgesia. Patients were advised to maintain a pain diary and rescue analgesia diary. Patients were followed up for a period of 12 weeks at intervals of 2-, 4-, 8-, and 12-weeks post-procedure for VNRS and WOMAC scores. Any adverse events including deafferentation pain was screened via history taking and examination at follow up visits.

7. Primary and secondary objectives

The primary objective of the study was the difference in VNRS scores at 12 weeks as compared to the baseline. Secondary outcome variables were VNRS and WOMAC scores at 2, 4, and 8 weeks, proportion of patients achieving effective pain relief (at least a 50% reduction in VNRS scores at 12 weeks), rescue analgesia, and any adverse event.

8. Statistical analysis

1) Sample size calculation

Thirteen patients per group were required to detect a mean difference of 1.7 with a standard deviation (SD) of 1.73, i.e., a variance of 3 (square of the SD) at a confidence interval of 95% and a power of 80%. We enrolled 15 patients per group taking into account possible dropouts [18].

The distribution of the variables was tested with Kolmogorov–Smirnov tests for normality. Continuous data that were not normally distributed were reported as median and interquartile range (IQR). Categorical variables were reported as counts and percentages. Proportions were compared using the chi-square test or Fisher’s exact test.

For normally distributed data, a Student’s t-test was applied to compare 2 groups. For skewed data, Mann–Whitney U-test was applied. A related-samples Friedman’s two-way analysis of variance was used to analyse the VNRS and WOMAC scores over time. When the difference was identified, the Bonferroni’s post-test was performed. A P value < 0.05 was considered statistically significant. Analysis was conducted using SPSS statistics (version 22.0; IBM Co., Armonk, NY).

The flow of participants is represented in Fig. 1. Sixty patients visiting a pain clinic with a chief complaint of knee pain were screened for eligibility. Of these, 40 patients fulfilled the eligibility criteria. Eight patients did not provide consent for the study after a detailed explanation of the procedure. Thirty-two patients were enrolled to receive treatment as per the study protocol. There was loss to follow up in one patient. Protocol violation occurred in one patient. Therefore, the data were analysed for 30 patients. Demographic data was comparable between the two groups (Table 1).

Table 1 Demographic characteristics

VariablePRF group
(n = 15)
LAS group
(n = 15)
P value
Age (yr)60.8 ± 12.757.4 ± 9.70.419
Man6 (40.0)3 (20.0)
Woman9 (60.0)12 (80.0)
Body mass index (kg/m2)26.9 ± 4.026.6 ± 5.20.851
Side of interventiona0.215
Right13 (86.7)10 (66.7)
Left2 (13.3)5 (33.3)
VNRS score8.0 (8-9)8.0 (8-9)0.909
WOMAC score53.0 (47-63)50 (43-54)0.405
Controlled hypertension6 (40.0)5 (33.3)0.724
Controlled hypothyroidism2 (13.3)1 (6.7)0.612
Duration of pain (mo)17 ± 7.919.3 ± 7.90.432
Kellgren–Lawrence gradinga
22 (13.3)2 (13.3)> 0.999
313 (86.7)13 (86.7)

Values are presented as mean ± standard deviation, number (%), or median (interquartile range).

PRF: pulsed radiofrequency, LAS: local anesthetic steroid, VNRS: verbal numeric rating scale, WOMAC: Western Ontario McMaster Universities Osteoarthritis Index.

t-test was performed. achi-square test was performed.

P value < 0.05 significant.

Figure 1. CONSORT (Consolidated Standards of Reporting Trials) diagram showing flow of patients.

The baseline VNRS score (median IQR) of group PRF was 8.0 (8–9) and for group LAS was 8.0 (8–9) before treatment. At 12 weeks, no difference was found in the VNRS scores between the two groups (P = 0.724). VNRS scores improved significantly over time in both groups as compared to baseline (group PRF 4 [3–4], P < 0.001; group LAS 4.0 [3–5]; P < 0.001). The baseline WOMAC scores (median IQR) of group PRF was 53.0 (47–63) and group LAS was 50.0 (43–54) before treatment. There was no difference in WOMAC scores between the two groups at 12 weeks (P = 0.983). WOMAC scores improved significantly over time in both groups as compared to baseline (group PRF 34.0 [21–37], P = 0.001; group LAS 32.0 [22–43]; P = 0.001).

The results of Friedman’s two ways analysis of variance revealed a significant difference between the VNRS scores measured at baseline, 2 weeks, 4 weeks, 8 weeks, and 12 weeks (degree of freedom [df] [4] = 35.34, P < 0.001 for group PRF and df [4] = 38.17, P < 0.001 for group LAS). Within the groups pairwise analysis revealed that VNRS scores decreased at all-time intervals compared with baseline in both groups (Fig. 2). Similarly, within-group pairwise analysis revealed that WOMAC scores significantly decreased at all-time intervals compared with baseline in both groups (Fig. 3).

Figure 2. Box plot analysis of VNRS scores at various time intervals. Boxplots show the median, interquartile range and outliers. Box edge indicates 25th and 75th percentiles, Whiskers indicate 5th and 95th percentiles. Red/blue dots represent outliers. Within group comparison, VNRS score were significant in both the PRF group and LAS group at various time interval of follow-up. Error bars indicate 95% confidence interval. VNRS: verbal numeric rating scale, PRF: pulsed radiofrequency, LAS: local anesthetic steroid. * indicates P < 0.001 compared to baseline in PRF group. $ indicates P < 0.001 compared to baseline in LAS group.
Figure 3. Box plot analysis of WOMAC score at various time intervals. Boxplots show the median, interquartile range and outliers. Box edge indicates 25th and 75th percentiles, Whiskers indicate 5th and 95th percentiles. Red/blue dots represent outliers. Within group comparison, WOMAC score were significant in both the PRF group and LAS group at various time interval of follow-up. Error bars indicate 95% confidence interval. WOMAC: Western Ontario and McMaster Universities Arthritis Index, PRF: pulsed radiofrequency, LAS: local anesthetic steroid. * indicates P < 0.05 compared to baseline in PRF group. $ indicates P < 0.05 compared to baseline in LAS group.

The proportion of patients achieving effective pain relief (whose VNRS value decreased by at least 50%) at 12 weeks was comparable (70% in the PRF group and 66% in the LAS group, P > 0.999). Six patients required rescue analgesia in the PRF group as compared to four patients in the LAS group (P = 0.700, chi-square test). We did not encounter any bleeding, localized swelling, motor weakness, sensory deficit, deafferentation pain, or any other complication in any of our patients immediately after the procedure or during the follow up period.

We conducted this study to compare ultrasound-guided PRF of the GN with GN block using LAS for management of OA knee pain. The VNRS score decreased significantly in both groups at 12 weeks and other follow up time intervals as compared to baseline. There was also a significant improvement in the WOMAC score in both groups. There was no difference in VNRS and WOMAC scores between the two groups. Eleven patients (73%) in group PRF and ten patients (66%) in group LAS had effective pain relief (≥ 50% reduction in pain) at 12 weeks. We did not come across any adverse effects during the procedure or follow-up.

RF neurotomy was first used in the treatment of chronic pain patients who failed to respond to conservative treatment modalities. Following good results with RF neurotomy in trigeminal neuralgia, it was applied to the sacroiliac and facet joints for chronic pain [21,22]. The technique was later applied to the cervical facet, discogenic pain, and cancer pain treatment [23]. In the management of OA knee pain, CRF ablation was applied for the first time by Choi et al. [14]. Thirty eight patients with positive diagnostic GN block were randomised into a CRF or control group. Ten patients (59%) in the RF group achieved a primary outcome of at least 50% knee pain relief at 12 weeks. In a similar study conducted by Pineda et al. [24] to reproduce the effects of RF genicular neurotomy described by Choi et al. [14], the authors reported an 88% reduction in short term VAS scores, which decreased to 32% at the end of one year. In another study by Qudsi-Sinclair et al. [18], CRF was used, and its efficacy was compared with LAS in patients experiencing pain more than six months after TKA. Twenty-eight patients were followed up over a period of one year. Significant pain relief and knee function improvement was observed with similar results in both the groups. The best results were obtained during the first 6 months, worsening afterwards [18]. Authors recommended that patients of knee OA should undergo regular follow ups to evaluate need for timely repetition of procedure.

In the CRF technique, tissue temperature reaches up to 60°C–80°C which causes lysis of the nerves with a chance of motor fiber damage and deafferentation. With the purpose of finding an equally effective and less destructive technique, PRF was invented. In PRF, the pulse generator creates pulses with an amplitude of 45 V lasting 20 milliseconds followed by a 480-millisecond silent phase. This allows heat to spread and tissue temperature does not exceed a maximum of 42°C. As temperature does not reach the damage threshold (45ºC–50ºC), no irreversible tissue damage occurs [10,25]. The basic principle of PRF is a neuromodulation effect at the target tissue caused by stopping nociceptive (A-δ and C-fibers) pain input from the periphery to the central nervous system without destroying the motor or sensory (A-β) fibers, whereas high-temperature ablation may result in neuromas and deafferentation [25].

Studies on use of PRF in GN block are limited to only two case series [15,26]. Results obtained are promising and support the outcome of our study. In a preliminary case series by Kesikburun et al. [15], the efficacy of PRF was evaluated using USG guidance in 9 patients. PRF was performed only to the SMGN and IMGN in patients who experienced pain on the medial side of the knee. The study revealed significant pain reduction in 66% (6/9) of patients and knee function improvement throughout the study period of 12 weeks. However, the study was limited by the lack of a control group and short follow-up [15]. Further, only patients with pain on the medial side of the knee were enrolled. In another case series of 10 patients, USG-guided PRF of the composite nerves of the knee (saphenous, femoral, common peroneal, and tibial nerves along with the plexus of the popliteal, sub sartorial, and peripatellar nerves) was performed in OA knee patients. The authors reported sustained pain relief and muscle relaxation that enabled patients to optimize physiotherapy, possibly due to reduced peripheral and central sensitization [26]. With the purpose of elucidating the efficacy of the technique further, the authors conducted this study. The results showed that 73% (11/15) of patients had effective pain relief in the PRF group and 63% (10/15) in the LAS group at the 12 weeks follow-up. Our study had an active control group in the form of an LAS group, thus eliminating the risk of bias. We also found a significant reduction in VNRS and WOMAC scores with the use of PRF in OA knee pain management.

The decision to administer a corticosteroid in addition to LA for peripheral nerve block is limited by local or systemic side effects associated with the use of steroids and with their short-term effects [17,27]. Adding a steroid to LA may prolong the duration of the LA effect and also inhibits the transmission of afferent c-fibers that are mainly involved in the pain pathway [17]. Steroids alter the nociceptive and neuropathic brain pathway mechanism responsible for the integration of pain.

Previous studies have reported contradictory results on the effectiveness of LAS for GN block [17,18,27]. Authors found that a GN block administered with LAS is as effective as CRF of the GN in post-knee arthroplasty patients [18]. In a case series of two brain-injured patients who developed heterotropic ossification in the knee joint, USG-guided GN block administered with lignocaine and betamethasone led to a decrease in VAS scores at the 3rd month of follow-up [17]. On the other hand, Kim et al. [27], compared USG-guided GN block with LAS vs LA alone and found no added advantage from adding a steroid to the local anaesthetic, as clinically significant improvement in both the VAS and Oxford knee score was observed only up to 2 weeks and 1 week respectively in both groups. The authors used 20 mg of triamcinolone acetonide mixed with 6 mL of lignocaine in 3 divided doses at the target site. It is possible that the total dose of steroid used was less, resulting in subclinical pain relief. In the presence of contradictory literature, the authors decided to evaluate the effect of PRF with LAS in the management of pain for OA knee patients. They used 60 mg of methylprednisolone acetate in 3 divided at the target site.

GN block can be performed using ultrasound or fluoroscopic guidance. USG allows the direct visualization of soft-tissue structures such as the nerve bundles and blood vessels. USG also has the advantage of causing no exposure to ionizing radiation, as with the fluoroscopic technique [28]. Application of USG for GN RF was found to be easier and safer than fluoroscopy [28]. Sari et al. [28] studied fluoroscopy and USG as an imaging modality for the application of CRF on the GN. They found a similar reduction in VNRS and WOMAC scores at three months with a shorter procedure time with USG (20.2 ± 6.4 minutes) as compared to fluoroscopy (25.0 ± 4.8 minutes) [28]. In the present study, we didn’t encounter any complications during either the procedure or follow-up at various time intervals.

Our study has a few limitations. Firstly, we did not give any diagnostic blocks. At this point, there is no evidence-based recommendations for performing a diagnostic nerve block to ensure a proper selection of patients for RF treatment [29]. McCormick et al. [29] randomized 29 participants (36 knees) to receive a prognostic GN block or no block prior to cooled RF treatment and reported ≥ 50% pain relief in 64% of patients in the no block group at six months. Secondly, follow-up was done until 12 weeks. This was due to logistic constrains with many patients coming from remote areas. Long term follow-up would have allowed documentation of the duration of the interventions and time period after which repeated procedures might be required. Thirdly, the study is limited by a small sample size. Further studies with larger sample sizes are warranted.

To conclude, both USG-guided PRF of the GN and LAS block of the GN provided a comparable reduction in pain and improvement in WOMAC scores up to 12 weeks of follow-up in patients with OA knee pain without any complication. We cannot recommend one treatment option over the other, but PRF can avoid corticosteroid usage and possible complications, especially in older patients. However, PRF of the GN is a procedure that takes more time and equipment than the GN block using LAS.

Babita Ghai: Investigation; Muthu Kumar: Writing/manuscript preparation; Jeetinder Kaur Makkar: Writing/manuscript preparation; Vijay Goni: Writing/manuscript preparation.

No potential conflict of interest relevant to this article was reported.

  1. Garstang SV, Stitik TP. Osteoarthritis: epidemiology, risk factors, and pathophysiology. Am J Phys Med Rehabil 2006; 85(11 Suppl): S2-11.
    Pubmed CrossRef
  2. Bijlsma JW, Berenbaum F, Lafeber FP. Osteoarthritis: an update with relevance for clinical practice. Lancet 2011; 377: 2115-26.
    Pubmed CrossRef
  3. Dureja GP, Jain PN, Shetty N, Mandal SP, Prabhoo R, Joshi M, et al. Prevalence of chronic pain, impact on daily life, and treatment practices in India. Pain Pract 2014; 14: E51-62.
    Pubmed CrossRef
  4. Kess M, Stärke C, Henle P. [Unloading with insoles, orthotics and braces: pre-operative leg axis correction or independent treatment?]. Orthopade 2017; 46: 575-82. German.
    Pubmed CrossRef
  5. Bozimowski G. A review of nonsteroidal anti-inflammatory drugs. AANA J 2015; 83: 425-33.
  6. Bellamy N, Campbell J, Robinson V, Gee T, Bourne R, Wells G. Intraarticular corticosteroid for treatment of osteoarthritis of the knee. Cochrane Database Syst Rev 2006; 2: CD005328.
    Pubmed CrossRef
  7. Rönn K, Reischl N, Gautier E, Jacobi M. Current surgical treatment of knee osteoarthritis. Arthritis 2011; 2011: 454873.
    Pubmed KoreaMed CrossRef
  8. Hirasawa Y, Okajima S, Ohta M, Tokioka T. Nerve distribution to the human knee joint: anatomical and immunohistochemical study. Int Orthop 2000; 24: 1-4.
    Pubmed KoreaMed CrossRef
  9. Vallejo R, Tilley DM, Williams J, Labak S, Aliaga L, Benyamin RM. Pulsed radiofrequency modulates pain regulatory gene expression along the nociceptive pathway. Pain Physician 2013; 16: E601-13.
    Pubmed CrossRef
  10. Karaman H, Tüfek A, Kavak GÖ, Yildirim ZB, Uysal E, Celik F, et al. Intra-articularly applied pulsed radiofrequency can reduce chronic knee pain in patients with osteoarthritis. J Chin Med Assoc 2011; 74: 336-40.
    Pubmed CrossRef
  11. Chua NH, Vissers KC, Sluijter ME. Pulsed radiofrequency treatment in interventional pain management: mechanisms and potential indications-a review. Acta Neurochir (Wien) 2011; 153: 763-71.
    Pubmed KoreaMed CrossRef
  12. Bhatia A, Peng P, Cohen SP. Radiofrequency procedures to relieve chronic knee pain: an evidence-based narrative review. Reg Anesth Pain Med 2016; 41: 501-10.
    Pubmed CrossRef
  13. Kirdemir P, Çatav S, Alkaya Solmaz F. The genicular nerve: radiofrequency lesion application for chronic knee pain. Turk J Med Sci 2017; 47: 268-72.
    Pubmed CrossRef
  14. Choi WJ, Hwang SJ, Song JG, Leem JG, Kang YU, Park PH, et al. Radiofrequency treatment relieves chronic knee osteoarthritis pain: a double-blind randomized controlled trial. Pain 2011; 152: 481-7.
    Pubmed CrossRef
  15. Kesikburun S, Yaşar E, Uran A, Adigüzel E, Yilmaz B. Ultrasound-guided genicular nerve pulsed radiofrequency treatment for painful knee osteoarthritis: a preliminary report. Pain Physician 2016; 19: E751-9.
    Pubmed CrossRef
  16. Demir Y, Güzelküçük Ü, Tezel K, Aydemir K, Taşkaynatan MA. A different approach to the management of osteoarthritis in the knee: ultrasound guided genicular nerve block. Pain Med 2017; 18: 181-3.
    Pubmed CrossRef
  17. Adiguzel E, Uran A, Kesikburun S, Köroğlu Ö, Demir Y, Yaşar E. Knee pain relief with genicular nerve blockage in two brain injured patients with heterotopic ossification. Brain Inj 2015; 29: 1736-9.
    Pubmed CrossRef
  18. Qudsi-Sinclair S, Borrás-Rubio E, Abellan-Guillén JF, Padilla Del Rey ML, Ruiz-Merino G. A comparison of genicular nerve treatment using either radiofrequency or analgesic block with corticosteroid for pain after a total knee arthroplasty: a double-blind, randomized clinical study. Pain Pract 2017; 17: 578-88.
    Pubmed CrossRef
  19. Baron G, Tubach F, Ravaud P, Logeart I, Dougados M. Validation of a short form of the Western Ontario and McMaster Universities Osteoarthritis Index function subscale in hip and knee osteoarthritis. Arthritis Rheum 2007; 57: 633-8.
    Pubmed CrossRef
  20. Yasar E, Kesikburun S, Kılıç C, Güzelküçük Ü, Yazar F, Tan AK. Accuracy of ultrasound-guided genicular nerve block: a cadaveric study. Pain Physician 2015; 18: E899-904.
    Pubmed CrossRef
  21. Sweet WH, Wepsic JG. Controlled thermocoagulation of trigeminal ganglion and rootlets for differential destruction of pain fibers. 1. Trigeminal neuralgia. J Neurosurg 1974; 40: 143-56.
    Pubmed CrossRef
  22. Chang MC, Ahn SH. The effect of intra-articular stimulation by pulsed radiofrequency on chronic sacroiliac joint pain refractory to intra-articular corticosteroid injection: a retrospective study. Medicine (Baltimore) 2017; 96: e7367.
    Pubmed KoreaMed CrossRef
  23. Kapural L, Vrooman B, Sarwar S, Krizanac-Bengez L, Rauck R, Gilmore C, et al. A randomized, placebo-controlled trial of transdiscal radiofrequency, biacuplasty for treatment of discogenic lower back pain. Pain Med 2013; 14: 362-73.
    Pubmed CrossRef
  24. Santana Pineda MM, Vanlinthout LE, Moreno Martín A, van Zundert J, Rodriguez Huertas F, Novalbos Ruiz JP. Analgesic effect and functional improvement caused by radiofrequency treatment of genicular nerves in patients with advanced osteoarthritis of the knee until 1 year following treatment. Reg Anesth Pain Med 2017; 42: 62-8.
    Pubmed CrossRef
  25. Byrd D, Mackey S. Pulsed radiofrequency for chronic pain. Curr Pain Headache Rep 2008; 12: 37-41.
    Pubmed KoreaMed CrossRef
  26. Vas L, Pai R, Khandagale N, Pattnaik M. Pulsed radiofrequency of the composite nerve supply to the knee joint as a new technique for relieving osteoarthritic pain: a preliminary report. Pain Physician 2014; 17: 493-506.
    Pubmed CrossRef
  27. Kim DH, Choi SS, Yoon SH, Lee SH, Seo DK, Lee IG, et al. Ultrasound-guided genicular nerve block for knee osteoarthritis: a double-blind, randomized controlled trial of local anesthetic alone or in combination with corticosteroid. Pain Physician 2018; 21: 41-52.
    Pubmed CrossRef
  28. Sarı S, Aydın ON, Turan Y, Şen S, Özlülerden P, Ömürlü İK, et al. Which imaging method should be used for genicular nerve radio frequency thermocoagulation in chronic knee osteoarthritis? J Clin Monit Comput 2017; 31: 797-803.
    Pubmed CrossRef
  29. McCormick ZL, Reddy R, Korn M, Dayanim D, Syed RH, Bhave M, et al. A prospective randomized trial of prognostic genicular nerve blocks to determine the predictive value for the outcome of cooled radiofrequency ablation for chronic knee pain due to osteoarthritis. Pain Med 2018; 19: 1628-38.
    Pubmed CrossRef