|Year : 2021 | Volume
| Issue : 1 | Page : 60-65
Efficacy of cryogun versus diode laser therapy in the management of oral leukoplakia
K Naga Venkata Sai Praveen1, Gajendra Veeraraghavan2, T Ramesh3, T Navya Teja1, G Upendra4, Y Kalyan3
1 Department of Oral Medicine and Radiology, CKS Theja Dental College, Tirupathi, Andhra Pradesh, India
2 Clinical Practice, Department of Oral Medicine and Radiology, Ireland
3 Department of Oral Medicine and Radiology, Vishnu Dental College, Bhimavaram, Andhra Pradesh, India
4 Department of Oral Medicine and Radiology, Sri Sai Dental College, Srikakulam, Andhra Pradesh, India
|Date of Submission||29-Jun-2020|
|Date of Decision||11-Jan-2021|
|Date of Acceptance||13-Jan-2021|
|Date of Web Publication||26-Mar-2021|
Dr. K Naga Venkata Sai Praveen
Department of Oral Medicine and Radiology, CKS Theja Dental College, Tirupathi
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Background and Aim: This study was aimed to clinically evaluate the effectiveness of 810 nm diode laser and cryosurgery in the management of oral leukoplakia (OL) in terms of healing outcomes. Materials and Methods: Thirty subjects clinically and histo-pathologically diagnosed as having OL were randomly allocated into two groups. Group-1 consisting of 15 subjects each treated with cryotherapy, Group-2 was treated with an 810 nm diode Laser. VAS scale was used for evaluating the postoperative discomfort due to pain and Bates- Jensen Wound Assessment Tool was used to evaluate clinical wound healing. Results: Data analysis was done by using one-way ANOVA for intragroup variations. For intergroup comparisons Paired t- test was used. A statistically significant number of recurrences was noticed in the cryo group compared to the LASER group. Conclusion: This study results suggest that both cryosurgery and laser therapy were effective in terms of patient comfort. However more number of recurrences and mild post operative edema in the cryo group make LASER therapy a better management option.
Keywords: Cryotherapy, Diode LASERs, oral leukoplakia, oral premalignant lesion
|How to cite this article:|
Sai Praveen K N, Veeraraghavan G, Ramesh T, Teja T N, Upendra G, Kalyan Y. Efficacy of cryogun versus diode laser therapy in the management of oral leukoplakia. J Indian Acad Oral Med Radiol 2021;33:60-5
|How to cite this URL:|
Sai Praveen K N, Veeraraghavan G, Ramesh T, Teja T N, Upendra G, Kalyan Y. Efficacy of cryogun versus diode laser therapy in the management of oral leukoplakia. J Indian Acad Oral Med Radiol [serial online] 2021 [cited 2021 Apr 18];33:60-5. Available from: https://www.jiaomr.in/text.asp?2021/33/1/60/312192
| Introduction|| |
Oral cancer, mostly comprising of oral squamous cell carcinoma (OSCC), is the sixth most common cancer in the world with the etiology being multifactorial. Although it is not known if OSCC can occur without premalignant changes in the tissues, at least 20% of OSCCs are documented arising in or associated with a clinically visible precursor lesion, such as oral leukoplakia (OL). One of the new approaches for the control of this cancer is early detection of OL, which is considered to be the most common premalignant oral lesion and is represented in about 60% of patients diagnosed with OSCC.
The term OL was first used by Schwimmer in 1877 to describe a white lesion of the tongue. World health organization in the year 2005 has defined OL as “a white patch of questionable risk having excluded all other known disorders that carry no increased risk for cancer.” Thus, OL is a clinical term used when any other white oral lesion has been excluded. OL is often associated with tobacco smoking, although idiopathic forms are not rare.
Numerous protocols for the management of oral leukoplakia have been proposed which includes a conservative way of management such as Retinoids, antioxidants, and topical bleomycin along with surgical techniques such as scalpel excision, electrocoagulation, cryosurgery, and laser therapy. A consensus considered that surgery is the first choice in the management of OL.,
The word LASER is an acronym for Light Amplification by the Stimulated Emission of Radiation. Lasers are devices that produce intense beams of light that are monochromatic, coherent, and highly collimated. The rate of temperature rise plays a vital role in this effect. Diode lasers – also known as low-level lasers possessing penetration depth of 2 to 3 mm into the tissues (depending on wavelength), causes less damage to the surrounding tissues and are being commonly used in treating oral lesions. Moreover, it has the advantages of a compact and portable design.
Cryosurgery- is controlled and targeted destruction of diseased tissue by the application of cold temperature using a cryogen. It is a simple, cost-effective, efficient, and aesthetically acceptable modality. It is being used in Oral medicine for over 30 years. Several cryogens such as liquid nitrogen, nitrous oxide, carbon dioxide are made available for this technique. Cryosurgery has advantages like the reasonably predictable volume of tissue destruction, with relatively less pain, safe, easy to perform, and inexpensive procedure with less patient discomfort.
Both cryosurgery and laser surgery have added advantages like selective removal of the affected epithelium, minimal damage to surrounding healthy tissue along with minimal postoperative pain, edema, and scarring., The existing literature has shown the individual effectiveness of the modalities in managing OL. Very few studies have shown the comparison and efficacy in the management of oral leukoplakia. On this basis, this study was undertaken to elicit the effectiveness of cryosurgery and laser therapy in the management of oral leukoplakia.
| Materials and Methods|| |
A total of 30 subjects attending the outpatient department of Dental College, Bhimavaram for routine dental treatment, who were clinically and histopathologically diagnosed as having OL were included in the present longitudinal comparative clinical study. The study was conducted after taking clearance from the Institutional Review Board (Institutional Ethical Number: VDC/IEC/2014-21; Date: 22-1-2014). Among these, subjects diagnosed with systemic diseases, that can interfere with healing were excluded from the study.
Sample size estimation
L = allowable error = 20% of P = 16.8
P = prevalence = 84
q = 100-P = 16
z = 1.96
Substituting the values in formula,
With aforementioned calculations, sample size determined is 18 in number. But considering nonresponsive errors/drop out, final sample size derived is 30 in number.
All the subjects (diagnosed cases of oral leukoplakia) enrolled were explained about the purpose of this study in the local vernacular language. Written informed consent was obtained from each subject for the intervention to be conducted on them following Helsinki's declaration. Details of general information, any relevant past dental and medical history were recorded in a specially designed proforma. Patients were counselled to quit tobacco and alcohol habits before treatment. They were randomly allocated into two groups, each group comprising of 15 subjects.
Cryosurgery was performed with a gas expansion cryoprobe using nitrous oxide gas after applying topical anesthetic gel [Figure 1]. The lesion was frozen for 10 seconds and thawed immediately, and this cycle was repeated two times [Figure 2]. For the laser application, a Fotona XD-2 810 nm diode laser was employed [Figure 3]. Both the operator and patient were insisted to put on protective eyewear for safety concerns [Figure 4]. Ablation of the lesion was done in contact mode, and care was taken not to produce excessive charring.
Patients were asked to apply ice packs and an anesthetic mouth wash was also prescribed for 1 week to prevent discomfort at the operated site. All the cases were examined on the first, second, and third successive weeks postoperatively and were recalled for every month for 2 months. Evaluation of postoperative discomfort was done by using a visual analog scale (VAS) scoring while Bates-Jensen Wound Assessment Tool was used to evaluate clinical wound healing [Figure 5] and [Figure 6].
|Figure 5: (a) Pre Operative Treatment Photograph of Cryo Group. (b) Postoperative Treatment Photograph|
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|Figure 6: (a) Pre operative treatment photograph of laser Group. (b) Postoperative treatment photograph|
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Data analysis was done using a one-way ANOVA test for intragroup variations. For intergroup comparisons, Paired t-test was used. A Chi-square test was performed to know the significance of recurrences in both the study groups. Results with a P < 0.05 were considered significant.
| Results|| |
In this study, a one-way ANOVA test was performed to know the postoperative pain in, cryo and LASER group subjects during first, second, third week, second and third month follow-up periods. The results showed a significant decrease in the postoperative pain scores with P = 0.01 for the cryo group and 0.05 for the laser group [Table 1]. In this study, complete healing of the treated site was noticed by the end of the third week and second month follow-up period in cryo and laser groups, respectively [Table 2].
|Table 1: Post-Operative pain in laser and cryo group at different time intervals|
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|Table 2: Wound healing scores in cryo and laser group at different time intervals|
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Paired t-test was used to compare the postoperative pain scores at different time intervals between both the groups. The results revealed a significant difference in postoperative pain scores between the cryo group and the laser group in the first week (P = 0.027) with a mean value of 1.00 in the cryo group and 1.53 in the laser group and P value significant at the level of 0.05. This infers that there was comparatively less discomfort due to postoperative pain in the cryo group than in the laser group. By the end of the third week, there was a complete reduction in postoperative pain (with a score of 0) in both cryo and laser groups. A similar observation was found even during second and third- month follow-up [Graph 1].
A significant difference in wound healing scores between the cryo group and the laser group subjects was noticed in the first, second, third week, second month with a P value of 0.003 in the first week and 0.001 in successive weeks with an insignificant difference during third-month follow-up with a P value of 0.082 was noticed [Graph 2].
A Chi-square test was performed to know the significance of recurrences in both the study groups. Of the total 15 subjects in both the groups a total of 4 cases (26.7%) and 1 case (6.7%) of recurrence was noticed by the end of the third month in cryo and Laser groups respectively. A statistically significant number of recurrences were noticed in the cryo group (p-value: 0.021) by the end of this third-month follow-up [Graph 3].
| Discussion|| |
Oral cancer often begins as potentially malignant disorders that can be best characterized as lesions in which there is a risk for uncontrolled cellular growth and transformation into cancer, followed by the disruption of normal functioning tissues., Oral leukoplakia forms part of a set of potentially malignant disorders.
It has been reported that dysplastic OL carries a 5-fold greater risk of malignant transformation than non-dysplastic OL. This malignant potential of OL highlights the importance of early detection and prompt treatment of this lesion. In this study, patients were selected based on the histopathological dysplastic features of the lesion similar to studies conducted by Ishii et al. and Chuan-Hang Yu et al.
Various non-surgical and surgical modalities have been reported in the management of oral leukoplakia but, currently, there is no consensus on which is the best. This could be attributed to the fact that the outcome seems to vary and long-term follow-up studies are very few. Management of OL is primarily directed towards the elimination of possible causative factors, like tobacco and alcohol usage, followed by other modalities. According to Kundoor et al. non-surgical means of management failed to prevent malignant transformation and achieve recurrence-free treatment.
Surgical management include conventional surgery, electrocoagulation, cryosurgery, and laser surgery (excision or evaporation). Most of the time, the treatment of OL is always directed towards the patient's comfort. Both Cryosurgery and Laser therapy have advantages like the reasonably predictable volume of tissue destruction, with relatively less pain, safe, easy to perform, and inexpensive technique with less patient discomfort., Till date there are very few studies regarding the comparison of diode laser (810 nm) and cryosurgery in the management of OL.
When the postoperative pain was analyzed based on findings, all the subjects of cryo group reported mild pain at the first-week follow-up which regressed completely by their third week. This goes by the observations of Narula et al. Mild pain usually exists in subjects treated with cryotherapy because of the deposition of cellular degradation products that affect the peripheral nerves adjacent to the site of therapy.
Postoperative pain was reduced completely within a short duration of 1 week in the study conducted by Chuan-Hang Yu et al. (2009) which is not by this study. This may be probably due to differences in the cryogen used, size of the lesion, and mode of treatment.
When postoperative pain was analyzed among the laser group, all the 15 subjects reported mild postoperative pain during the first week follow-up period which also subsided completely by the end of the third week. This is in agreement with studies conducted by studies of Pick et al., Pecaro et al., and Frame. The probable reason might be peripheral nerve fiber exposure during the healing process.
Observations of Raval et al. has shown a reduction of postoperative pain by the end of the first week which is dissimilar to our study. This may be due to the difference in the power of Laser used.
In a comparison of postoperative pain in both the study groups significant difference was observed at first-week follow-up with less postoperative pain noticed in the Cryo group than in the Laser group. This is attributed to the fact that in cryosurgery depth of freezing is variable (i.e., majority of the times superficial depth) depending on the factors such as pressure on the mucosa, length of freezing, and vascularity of tissues, whereas the depth of penetration in laser therapy is fixed which is about 2 to 3 mm and is deeper to a certain extent when compared to cryosurgery.,
Out of 15 subjects treated with cryotherapy, healing was completed by the end of the third week in all the subjects. These study results are similar to observations of Narula et al. Chuan-Hang Yu et al. reported complete healing within 2 weeks which is not per this study. This could be due to a difference in the number of sessions used for the cryotherapy procedure.
Healing was completed by the second month in all the subjects treated using an 810 nm Diode Laser. These observations are following the studies of Akbulut et al. and Kapoor et al. Observations of Kundoor et al., and Sarkar et al. has shown complete regression of treated site by the end of the third week.
In a comparison of postoperative healing in both the study groups significant difference was observed at first, second, third week and second-month follow-up with less duration for healing noticed in the Cryo group than Laser group. As described elsewhere, the depth of penetration plays a key role in postoperative healing. In cryo group where the depth of penetration is very low and superficial will result in less damage and consequently results in faster healing.
On comparison rate of recurrence in both, the study groups revealed a significant number of recurrences noticed in the Cryo group than in the Laser group which was not per the findings of Varun Kumar et al. This could be best explained as the depth of freezing achieved by the application of cryotherapy varies from 2 mm to several centimeters.
Limitations and future prospects
Limitations of cryotherapy include lack of precision in the procedure, making it difficult to judge the final volume of tissue necrosis. Disadvantages of LASER surgery include prolonged healing time and ocular damage of the operator if not used with appropriate eyewear. Inadequate destruction of lesions and continuation of tobacco usage habit results in a higher rate of recurrence. Due to this, future studies should monitor smoking cessation and a much more extended follow-up period to attain better results.,
| Conclusion|| |
Treatment with cryosurgery has advantages like the selective removal of the affected epithelium and minimal damage to surrounding healthy tissue, resulting in excellent wound healing with no or minimal scar tissue and a good functional result. Similarly, laser surgery also has its advantages in that it results in minimal postoperative edema, pain, inflammation, and scarring. Thus, both of these treatment modalities can be tried as an alternative to conventional treatment. Nevertheless owing to the patient's comfort, laser therapy is quite advantageous over cryosurgery.
Declaration of patient consent
The authors certify that they have obtained all appropriate patient consent forms. In the form the patient(s) has/have given his/her/their consent for his/her/their images and other clinical information to be reported in the journal. The patients understand that their names and initials will not be published and due efforts will be made to conceal their identity, but anonymity cannot be guaranteed.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
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[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6]
[Table 1], [Table 2]