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Risk of post-vasectomy infections in 133,044 vasectomies from four international vasectomy practices

ABSTRACT

Objectives:

To estimate the risk of post-vasectomy infections in various settings and across various surgical techniques and sanitization practices.

Patients and Methods:

Retrospective review of the records of 133,044 vasectomized patients from four large practices/network of practices using the no-scalpel vasectomy (NSV) technique in Canada (2011-2021), Colombia (2015-2020), New Zealand (2018-2021), and the United Kingdom (2006-2019). We defined infection as any mention in medical records of any antibiotics prescribed for a genital or urinary condition following vasectomy.

Results:

Post-vasectomy infection risks were 0.8% (219 infections/26,809 procedures), 2.1% (390/18,490), 1.0% (100/10,506), and 1.3% (1,007/77,239) in Canada, Colombia, New Zealand, and the UK, respectively. Audit period comparison suggests a limited effect on the risk of infection of excising a short vas segment, applying topical antibiotic on scrotal opening, wearing a surgical mask in Canada, type of skin disinfectant, and use of non-sterile gloves in New Zealand. Risk of infection was lower in Colombia when mucosal cautery and fascial interposition [FI] were used for vas occlusion compared to ligation, excision, and FI (0.9% vs. 2.1%, p<0.00001). Low level of infection certainty in 56% to 60% of patients who received antibiotics indicates that the true risk might be overestimated. Lack of information in medical records and patients not consulting their vasectomy providers might have led to underestimation of the risk.

Conclusion:

Risk of infection after vasectomy is low, about 1%, among international high-volume vasectomy practices performing NSV and various occlusion techniques. Apart from vasectomy occlusion technique, no other factor modified the risk of post-vasectomy infection.

Keywords:
Vasectomy; Infections; Medical Audit

INTRODUCTION

Vasectomy is a minor surgery with low risk of infectious complications, especially when providers utilize the no-scalpel vasectomy (NSV) technique (11 Li SQ, Goldstein M, Zhu J, Huber D. The no-scalpel vasectomy. J Urol. 1991;145:341-4., 22[No Authors]. World Health Organization -WHO, Department of Reproductive Health and Research (WHO/RHR) and Johns Hopkins Bloomberg School of Public Health/Center for Communication Programs (CCP): Knowledge for Health Project. Family Planning: A Global Handbook for Providers (2018 update). Baltimore and Geneva, CCP and WHO. [Internet]. 2018. Available at. <https://apps.who.int/iris/bitstream/handle/10665/260156/9780999203705-eng.pdf>
https://apps.who.int/iris/bitstream/hand...
). In 2012, the committee members of American Urological Association (AUA) guideline on vasectomy reviewed studies with a sample size greater than 500 patients and ultimately estimated a risk of post-vasectomy infection between 1% and 2% (33 Sharlip ID, Belker AM, Honig S, Labrecque M, Marmar JL, Ross LS, et al. American Urological Association. Vasectomy: AUA guideline. J Urol. 2012;188(6 Suppl):2482-91.). However, the AUA review did not provide a clear definition of post-vasectomy infection, nor did it describe the types of infection that occurred. Additionally, the review did not expand on the variation of the risk of infection in relation to surgical technique and other salient clinical factors.

On June 12, 2021, World Vasectomy Day, an international non-governmental organization supporting male participation in family planning, and the Vasectomy Network, a Google Group of over 600 health professionals, organized a webinar on post-vasectomy infections to address these gaps in clinical research. During the meeting, four of the authors (ML, DT, SS, and GJ) presented the results of audits of post-vasectomy infections conducted in their large vasectomy practices and networks of practices from Canada, Colombia, New Zealand, and the United Kingdom (UK) respectively.

The objectives were to estimate the risk of post-vasectomy infection in these various settings and to assess the risk of infection according to changes in surgical techniques and sanitization practices, level of certainty of infection, vasectomy surgeons, and types of infection. Their findings are presented here.

PATIENTS AND METHODS

Settings

We conducted a retrospective review of the vasectomy records of patients from the four participating practices and networks of practices (henceforth referred to as practices). Table-1 describes the characteristics of the four sites. All where high-volume practices with over 3,000 vasectomies performed each year. All providers utilized the NSV technique or variants of NSV to expose the vas deferens (11 Li SQ, Goldstein M, Zhu J, Huber D. The no-scalpel vasectomy. J Urol. 1991;145:341-4., 44 Chen KC, Peng CC, Hsieh HM, Chiang HS. Simply modified no-scalpel vasectomy (percutaneous vasectomy)--a comparative study against the standard no-scalpel vasectomy. Contraception. 2005;71:153-6., 55 Black T, Francome C. Comparison of Marie Stopes scalpel and electrocautery no-scalpel vasectomy techniques. J Fam Plann Reprod Health Care. 2003;29:32-4. Erratum in: J Fam Plann Reprod Health Care. 2003;29:159.), but differed in their occlusion techniques. With the exception of the Colombia site where patients attended a visit with a general practitioner one-week post procedure, no routine post-op follow-up was required of vasectomy patients in the other three countries.

Table 1
Characteristics of the four vasectomy practices/network of practices.

Infection prevention procedures used in the four settings are also described in Table-1. No patients included in the study received prophylactic antibiotics. Solutions of chlorhexidine or povidone iodine were used to sterilize the skin in all four practices. Clinical protocols for shaving, handwashing, use of sterile gloves, and use of surgical masks varied across time and settings in all four practices.

Data sources and collection

For our analysis, we defined infection as any mention in patient medical records of any antibiotics prescribed for treating a genital or urinary condition following the patient's vasectomy. We excluded the application of topical antibiotics for minor skin infections located at the scrotal opening site. Data sources and collection processes varied across settings. Data collection periods covered 10 years in Canada, 6 years in Colombia, 3 years in New Zealand, and 13 years in the UK (Table-2).

Table 2
Risk of post-vasectomy infections in the four vasectomy practices/network of practices according to changes in clinical practice.

In the Canadian practice, attending physicians routinely documented any post-vasectomy contact with patients using an electronic medical record specifically designed for vasectomy. Author ML identified all patients with post-vasectomy contact and searched for patients with any infectious conditions recorded in the “Diagnosis of complication” field within the electronic medical record. In addition, ML performed a free-text search with following words “infection” and “antibiotic”, as well as “levaquin®”, “clavulin®”, “cipro®” as the most commonly prescribed antibiotics in his practice. Patients with minor localized skin opening infection and an infectious condition with an evidently absent link with the vasectomy procedure (e.g., acute prostatitis 397 days after vasectomy) were excluded.

Once an instance of antibiotic prescription was identified, ML documented the date of the vasectomy, the vasectomy provider, type of infection, presence of hematoma, the date an antibiotic was prescribed, the healthcare provider who authorized the prescription, and certainty of infection (high/low). Certainty of infection was assessed on the attending physician's determination (certain or probable = high; possible = low) or signs, symptoms, and timing described in the record. Patients with fever, scrotal abscess, severe or increasing moderate scrotal pain with skin oedema and erythema and urinary symptoms occurring in the first week after vasectomy were classified as having high probability of infection. ML also documented the dates of the following changes taking place in the practice over the years: topical antibiotics applied on the skin opening, excision of a short vas segment, and the use of surgical masks.

In Colombia, author DT conducted a string search for the words “ciprofloxacina”, “norfloxacina”, “cefalexina”, and “gentamicina” in the electronic medical records of patients who attended one-week post-procedure routine follow-up visits, or any other visits related to vasectomy to identify patients who received these antibiotics. This search excluded patients who received prophylactic antibiotics for large hematomas (n=22) and patients who had both circumcision and vasectomy performed on the same day (n=24). These patients represented 0.25% (46/18,536) of the vasectomies performed in Colombia. DT recorded the dates of changes in hand sanitation procedures and vasectomy occlusion techniques.

The New Zealand practice maintains a post-operative contact spreadsheet. Author SS reviewed the post-vasectomy paper-based clinical records of patients who received consultation for a post-vasectomy concern to identify those who were prescribed an antibiotic. Patients who were given antibiotics with (e.g. swelling, erythema, fever) and without (no increasing pain) strong evidence of infection were considered to have a high- and low-probability of post-vasectomy infection, respectively. SS also documented the dates of changes in the type of skin disinfectant used (4% solution of chlorhexidine or 10% of povidone iodine) in the practice, and the use of sterile or non-sterile gloves during vasectomy.

In the UK, author GJ reviewed the vasectomy audit database of the Association of Surgeons of Primary Care (ASPC). Since 2006, ASPC annually collects data from approximately 30 vasectomy providers each year (66 Atkinson M, James G, Bond K, Harcombe Z, Labrecque M. Comparison of postal and non-postal post-vasectomy semen sample submission strategies on compliance and failures: an 11-year analysis of the audit database of the Association of Surgeons in Primary Care of the UK. BMJ Sex Reprod Health. 2022;48:54-59.), Surgeons send a web-based questionnaire to each patient four months after the vasectomy and report the completed questionnaire to ASPC. Risk of infection was determined via affirmative responses to a question asking if any clinician (e.g. vasectomy provider or general practitioner) prescribed an antibiotic following vasectomy.

In addition to extracting responses from this survey, GJ conducted three analyses of data available in the ASPC audit database to validate the frequency of infection. In the first analysis, surgeons participating in the audit process between 2012 and 2019 were divided into three groups reflecting the return rate of their four-month post-operative questionnaire to ascertain the homogeneity of infection risk. In the second analysis, GJ retrieved data from a single vasectomy clinic where 278 patients had a vasectomy in 2016-2017. Patients were contacted and inquired about their use of antibiotics. In the third analysis, GJ consulted data from another clinic where the vasectomy surgeon and administrative team reviewed the general practitioners’ electronic record of each patient who had a vasectomy in 2017-2018. Patients who had clinical visits with their physician or were prescribed antibiotics for any reason within four weeks of the procedure were recorded for analysis.

At each site, vasectomy providers gave authorization to access their data or personally provided data to conduct the retrospective audit. We did not seek approval of ethical review boards as it is not required for clinical audits (77[No Authors]. National Health and Medical Research Council (NHMRC): National Statement on Ethical Conduct in Human Research 2007 (Updated 2018). [Internet]. 2018. Available at. <www.nhmrc.gov.au/sites/default/files/documents/attachments/National/Statement.pdf>
www.nhmrc.gov.au/sites/default/files/doc...
99[No Authors]. National Health Service (NHS): Governance arrangements for research ethics committees: 2020 edition. [Internet]. Available at. <https://www.hra.nhs.uk/planning-and-improving-research/policies-standards-legislation/governance-arrangement-research-ethics-committees/>
https://www.hra.nhs.uk/planning-and-impr...
). Apart from nominal support from the vasectomy practice organisations in each country (Vasectomie Québec in Canada, Profamilia Bogota in Colombia, SNIP Vasectomy Clinics in New Zealand, ASPC in UK) no funding or financial support was received to conduct this study.

Data analysis

Analysis of each dataset was performed with respect to variations in clinical procedures over time (Table-2) and to different providers (Table-3). Infection risks were evaluated using a denominator of the total number of vasectomies performed during the study period at each site. In the Colombia practice, an additional risk calculation was performed using the number of patients who returned for the routine one-week follow-up visit. Differences between infection risk according to time and clinical procedures were evaluated with chi-square test or Fisher's exact test where chi-square is not applicable (1010 iCalcu: Chi-Square Calculator. 2021. [Internet]. Available at. <https://www.icalcu.com/stat/chisqtest.html>
https://www.icalcu.com/stat/chisqtest.ht...
). We considered p-values less than 0.05 to be statistically significant.

Table 3
Risk of post-vasectomy infections in the Canada and New Zealand practices according to vasectomy surgeons and the certainty of infections.

RESULTS

We present the estimated risk of infection in the four vasectomy practices according to changes in clinical procedures and protocols that took place during the audit periods in Table-2. The overall risk of post-vasectomy infection was 0.8% in Canada, 2.1% of all patients and 2.8% of patients with routine one-week follow-up in Colombia, 1.0% in New Zealand, and 1.3% in United Kingdom.

In the Canadian practice, we did not observe clinically or statistically significant differences across audit periods, suggesting the limited effect of excising a short vas segment, applying routine topical antibiotic on the scrotal opening, and wearing surgical masks on the risk of infection.

At the Colombia practice, clinically and statistically significant differences were observed between the audit periods when ligation/excision combined with fascial interposition on the testicular segment (known as the Li occlusion technique) (1111 Sokal D, Irsula B, Hays M, Chen-Mok M, Barone MA; Investigator Study Group. Vasectomy by ligation and excision, with or without fascial interposition: a randomized controlled trial [ISRCTN77781689]. BMC Med. 2004;2:6., 1212 Miranda Claro SJ, Vargas Laverde J, Mariño Samper E, Ibáñez Pinilla M, Torres Quiroz DS, Labrecque M. Risk of vasectomy failure by ligation and excision with fascial interposition: A prospective descriptive study. Contraception. 2020;101:342-9.) and when thermal mucosal cautery combined with facial interposition on the abdominal segment were performed for vas occlusion (1313 Labrecque M. Vasectomy occlusion technique combining thermal cautery and fascial interposition. Int Braz J Urol. 2011;37:630-5.). When the latter technique was used, the risk of infection (0.9% of all patients and 1.2% of patients with routine one-week follow-up) was comparable to the risk observed in the other participating countries.

In New Zealand, there was limited difference in the risk of infection in the audit period when povidone iodine was used compared to the other audit periods. No clinically nor statistically significant difference was observed when comparing audit periods when sterile and non-sterile gloves were used.

The UK analysis revealed a statistically significant difference in infection risk across the 12 audit cycles, though the risk was low, ranging from 1.0% to 1.7%. There was no clinically significant trend across the 12 years. In the validation analysis performed on the 2012-2019 audit cycles, the infection risks of patients whose surgeons had a return rate of the four-month post-operative questionnaire of less than 10%, 10% to 33%, and 33% or more were 1.0%, 1.0%, and 2.0%, respectively. The risk of infection in the first (2016-2017) and the second (2017-2018) GP clinic audited were 0.7% and 1.2%, respectively.

Strata of infection risk observed between physicians and certainty of infections (low/high) were available for the practices in Canada and New Zealand (Table-3). In both practices, there were slight but similar variations in the total risk of infection between physicians. These differences were statistically significant in Canada but not in New Zealand. Overall, just over half of the infections were deemed to be of low certainty in both countries. In both sites, some physicians consistently reported higher proportions of low certainty infections. These differences between physicians reflecting certainty of infection were statistically significant only in Canada.

Figure-1 shows the types of the 219 post-vasectomy infections encountered in Canada. Most (85%) were limited to the scrotal content but 15% were located in the prostate or urinary track. The risks of suffering any scrotal infection, a scrotal infection with an abscess, or a prostate or urinary track infection were 0.7%, 0.05%, and 0.1% respectively (Figure-1). Regardless of the presence of abscess, one in five scrotal infections were associated with a hematoma. Two other non-urinary or genital low probability infections were encountered in the electronic medical record; one was a fever of unknown origin and the other a heart valve infection occurring 14 and 28 days following the vasectomy, respectively.

Figure 1
Types of post-vasectomy infection in Canada practice (n= 26,809 vasectomies).

DISCUSSION

To our knowledge, this is the largest study on post-vasectomy infection ever reported. Analysis of our data demonstrates that about 1% of vasectomy patients suffered a post-vasectomy infection based on the proportion who received antibiotics for suspected or confirmed infection. A survey of US physicians published in 1982 – before the worldwide use of NSV – reported a 3.5% risk of infections among 65,155 vasectomies performed by 1,541 physicians who responded to the survey (1414 Kendrick JS, Gonzales B, Huber DH, Grubb GS, Rubin GL. Complications of vasectomies in the United States. J Fam Pract. 1987;25:245-8.). However, our results are consistent with infection risk reported in the AUA practice guideline on vasectomy (1-2%). Our findings support the AUA recommendation that prophylactic antibiotics are not routinely indicated unless the patient presents a high risk of infection (33 Sharlip ID, Belker AM, Honig S, Labrecque M, Marmar JL, Ross LS, et al. American Urological Association. Vasectomy: AUA guideline. J Urol. 2012;188(6 Suppl):2482-91.).

The estimated risk of infection was similar across practices in Canada, Colombia in recent years, New Zealand, and UK even though the settings, clinical procedures, and surgical techniques varied within and among each country. Interestingly, wearing a surgical mask did not seem to influence the risk of post-vasectomy infection. A Cochrane review has also concluded that there is no clear evidence that wearing disposable face masks modifies the risk of wound infections after clean surgery (1515 Vincent M, Edwards P. Disposable surgical face masks for preventing surgical wound infection in clean surgery. Cochrane Database Syst Rev. 2016;4(4):CD002929.). Similarly, the use of sterile compared to non-sterile gloves did not appear to influence the risk of infection. This finding aligns with previously reported reviews of trials of non-sterile gloves versus sterile gloves in other minor surgical procedures (1616 Steen K. Sterile eller rene hansker ved småkirurgi i allmennpraksis [Sterile or non-sterile gloves in minor surgical procedures in general practice]. Tidsskr Nor Laegeforen. 2017;137:885-9.1818 Ho C, Jones A. Disposable, Non-Sterile Gloves for Minor Surgical Procedures: A Review of Clinical Evidence [Internet]. Ottawa (ON): Canadian Agency for Drugs and Technologies in Health; 2017 3. [a head of print].).

The only clinically and statistically significant difference between factors that could influence the infection risk was observed in Colombia. The risk of infection decreased from an average of 2.6% of all patients /3.5% of patients with routine one-week follow-up in 2015-2018 to 0.9%/1.2% in 2019-2020 when surgeons changed their occlusion technique. They stopped using ligation and excision with FI on the testicular end after confirming in their practice the high risk of occlusion failure demonstrated in the Sokal et al. randomized trial (1111 Sokal D, Irsula B, Hays M, Chen-Mok M, Barone MA; Investigator Study Group. Vasectomy by ligation and excision, with or without fascial interposition: a randomized controlled trial [ISRCTN77781689]. BMC Med. 2004;2:6., 1212 Miranda Claro SJ, Vargas Laverde J, Mariño Samper E, Ibáñez Pinilla M, Torres Quiroz DS, Labrecque M. Risk of vasectomy failure by ligation and excision with fascial interposition: A prospective descriptive study. Contraception. 2020;101:342-9.). They adopted the thermal cautery of the vas mucosa combined with FI on the prostatic end (1313 Labrecque M. Vasectomy occlusion technique combining thermal cautery and fascial interposition. Int Braz J Urol. 2011;37:630-5.), recommended in clinical practice guidelines (33 Sharlip ID, Belker AM, Honig S, Labrecque M, Marmar JL, Ross LS, et al. American Urological Association. Vasectomy: AUA guideline. J Urol. 2012;188(6 Suppl):2482-91., 1313 Labrecque M. Vasectomy occlusion technique combining thermal cautery and fascial interposition. Int Braz J Urol. 2011;37:630-5., 1919 Dohle GR, Diemer T, Kopa Z, Krausz C, Giwercman A, Jungwirth A; European Association of Urology Working Group on Male Infertility. European Association of Urology guidelines on vasectomy. Eur Urol. 2012;61:159-63., 2020 Zini A, Grantmyre J, Chow V, Chan P. UPDATE - 2022 Canadian Urological Association best practice report: Vasectomy. Can Urol Assoc J. 2022;16:E231-6.). Colombian surgeons suggested that the use of three silk sutures with the former occlusion technique compared with only one silk suture with the currently used technique may contribute to this difference.

We were able to assess the type of infection in the Canadian practice. Although most infections were limited to scrotal content, a sizable proportion (15%) involved the prostate and urinary tract infection. Endogenous genital tract infection identified by pre-vasectomy semen culture have been associated with post-vasectomy infection (2121 Appell RA, Evans PR. Vasectomy: etiology of infectious complications. Fertil Steril. 1980;33:52-3.). This could explain our findings in part, but the very low absolute risk (1/812) may not justify routine screening with pre-vasectomy semen culture. This study also highlighted the association of hematomas with scrotal infection with or without abscess. This finding supports the use of minimally invasive technique such as NSV to reduce both the risks of bleeding and infection as recommended in recent vasectomy guidelines (33 Sharlip ID, Belker AM, Honig S, Labrecque M, Marmar JL, Ross LS, et al. American Urological Association. Vasectomy: AUA guideline. J Urol. 2012;188(6 Suppl):2482-91., 1919 Dohle GR, Diemer T, Kopa Z, Krausz C, Giwercman A, Jungwirth A; European Association of Urology Working Group on Male Infertility. European Association of Urology guidelines on vasectomy. Eur Urol. 2012;61:159-63., 2020 Zini A, Grantmyre J, Chow V, Chan P. UPDATE - 2022 Canadian Urological Association best practice report: Vasectomy. Can Urol Assoc J. 2022;16:E231-6., 2222 Faculty of Sexual & Reproductive Healthcare (FSRH): Male and Female Sterilisation. [Internet]. 2014. Available at. <https://www.fsrh.org/standards-and-guidance/fsrh-guidelines-and-statements/method-specific/male-and-female-sterilisation/>
https://www.fsrh.org/standards-and-guida...
). We fortuitously identified a heart valve infection occurring in a patient who had a recent vasectomy. Infective endocarditis possibly caused by vasectomy has been previously reported (2323 Dan M, Marien GJ, Goldsand G. Endocarditis caused by Staphylococcus warneri on a normal aortic valve following vasectomy. Can Med Assoc J. 1984;131:211-3.2727 Kessler RB, Kimbrough RC 3rd, Jones SR. Infective endocarditis caused by Staphylococcus hominis after vasectomy. Clin Infect Dis. 1998;27:216-7.).

Our study has limitations. Retrospective audit data were collected independently in the four practices. Information registered in medical records and ascertainment of cases at the time of diagnosis were not standardized. Certainty of post-vasectomy infection varies according to evaluation of symptoms and signs by the physician and follow-up method (telephone consultation or in-office visit). However, we agreed on a common definition of infection before data collection and analysis.

Our definition of infection - the use of antibiotics - may have led to an overestimation of post-vasectomy infection risk. Although we observed variations among physicians, globally, over half of vasectomized men from Canada and New Zealand who received antibiotics had low certainty of infection. The number of men with real post-vasectomy infections may then be lower than the number of all those receiving antibiotics. The risk could also have been underestimated. Men may have consulted general practitioners or emergency physicians and received antibiotics for non infectious post-vasectomy conditions. Such events may not be reported and go unnoticed by the vasectomy providers.

Our study has also many strengths. Our findings on infection risk were consistent across and within high volume practices of four countries. The sample size enhances precision in our estimates of risk. The involvement of multiple vasectomy providers of various level of experience using different procedures and vasectomy techniques indicates generalizability of our results. Importantly, our analysis demonstrates that a clear and consistent definition of post-vasectomy infection has yielded similar rates of post-vasectomy infection in various practices with varying techniques and procedures.

The risk of infection after vasectomy is low, about 1%, among international high-volume vasectomy practices performing the no-scalpel approach for vas isolation and various occlusion techniques recommended in vasectomy clinical practice guidelines (33 Sharlip ID, Belker AM, Honig S, Labrecque M, Marmar JL, Ross LS, et al. American Urological Association. Vasectomy: AUA guideline. J Urol. 2012;188(6 Suppl):2482-91., 1919 Dohle GR, Diemer T, Kopa Z, Krausz C, Giwercman A, Jungwirth A; European Association of Urology Working Group on Male Infertility. European Association of Urology guidelines on vasectomy. Eur Urol. 2012;61:159-63., 2020 Zini A, Grantmyre J, Chow V, Chan P. UPDATE - 2022 Canadian Urological Association best practice report: Vasectomy. Can Urol Assoc J. 2022;16:E231-6., 2222 Faculty of Sexual & Reproductive Healthcare (FSRH): Male and Female Sterilisation. [Internet]. 2014. Available at. <https://www.fsrh.org/standards-and-guidance/fsrh-guidelines-and-statements/method-specific/male-and-female-sterilisation/>
https://www.fsrh.org/standards-and-guida...
). Future research should continue to investigate variations in surgical and clinical procedures and associated risks of post-vasectomy infections.

REFERENCES

  • 1
    Li SQ, Goldstein M, Zhu J, Huber D. The no-scalpel vasectomy. J Urol. 1991;145:341-4.
  • 2
    [No Authors]. World Health Organization -WHO, Department of Reproductive Health and Research (WHO/RHR) and Johns Hopkins Bloomberg School of Public Health/Center for Communication Programs (CCP): Knowledge for Health Project. Family Planning: A Global Handbook for Providers (2018 update). Baltimore and Geneva, CCP and WHO. [Internet]. 2018. Available at. <https://apps.who.int/iris/bitstream/handle/10665/260156/9780999203705-eng.pdf>
    » https://apps.who.int/iris/bitstream/handle/10665/260156/9780999203705-eng.pdf>
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    Sharlip ID, Belker AM, Honig S, Labrecque M, Marmar JL, Ross LS, et al. American Urological Association. Vasectomy: AUA guideline. J Urol. 2012;188(6 Suppl):2482-91.
  • 4
    Chen KC, Peng CC, Hsieh HM, Chiang HS. Simply modified no-scalpel vasectomy (percutaneous vasectomy)--a comparative study against the standard no-scalpel vasectomy. Contraception. 2005;71:153-6.
  • 5
    Black T, Francome C. Comparison of Marie Stopes scalpel and electrocautery no-scalpel vasectomy techniques. J Fam Plann Reprod Health Care. 2003;29:32-4. Erratum in: J Fam Plann Reprod Health Care. 2003;29:159.
  • 6
    Atkinson M, James G, Bond K, Harcombe Z, Labrecque M. Comparison of postal and non-postal post-vasectomy semen sample submission strategies on compliance and failures: an 11-year analysis of the audit database of the Association of Surgeons in Primary Care of the UK. BMJ Sex Reprod Health. 2022;48:54-59.
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    [No Authors]. National Health and Medical Research Council (NHMRC): National Statement on Ethical Conduct in Human Research 2007 (Updated 2018). [Internet]. 2018. Available at. <www.nhmrc.gov.au/sites/default/files/documents/attachments/National/Statement.pdf>
    » www.nhmrc.gov.au/sites/default/files/documents/attachments/National/Statement.pdf
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    [No Authors]. National Health Service (NHS): Governance arrangements for research ethics committees: 2020 edition. [Internet]. Available at. <https://www.hra.nhs.uk/planning-and-improving-research/policies-standards-legislation/governance-arrangement-research-ethics-committees/>
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    » https://www.icalcu.com/stat/chisqtest.html>
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    Sokal D, Irsula B, Hays M, Chen-Mok M, Barone MA; Investigator Study Group. Vasectomy by ligation and excision, with or without fascial interposition: a randomized controlled trial [ISRCTN77781689]. BMC Med. 2004;2:6.
  • 12
    Miranda Claro SJ, Vargas Laverde J, Mariño Samper E, Ibáñez Pinilla M, Torres Quiroz DS, Labrecque M. Risk of vasectomy failure by ligation and excision with fascial interposition: A prospective descriptive study. Contraception. 2020;101:342-9.
  • 13
    Labrecque M. Vasectomy occlusion technique combining thermal cautery and fascial interposition. Int Braz J Urol. 2011;37:630-5.
  • 14
    Kendrick JS, Gonzales B, Huber DH, Grubb GS, Rubin GL. Complications of vasectomies in the United States. J Fam Pract. 1987;25:245-8.
  • 15
    Vincent M, Edwards P. Disposable surgical face masks for preventing surgical wound infection in clean surgery. Cochrane Database Syst Rev. 2016;4(4):CD002929.
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    Steen K. Sterile eller rene hansker ved småkirurgi i allmennpraksis [Sterile or non-sterile gloves in minor surgical procedures in general practice]. Tidsskr Nor Laegeforen. 2017;137:885-9.
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    Ho C, Jones A. Disposable, Non-Sterile Gloves for Minor Surgical Procedures: A Review of Clinical Evidence [Internet]. Ottawa (ON): Canadian Agency for Drugs and Technologies in Health; 2017 3. [a head of print].
  • 19
    Dohle GR, Diemer T, Kopa Z, Krausz C, Giwercman A, Jungwirth A; European Association of Urology Working Group on Male Infertility. European Association of Urology guidelines on vasectomy. Eur Urol. 2012;61:159-63.
  • 20
    Zini A, Grantmyre J, Chow V, Chan P. UPDATE - 2022 Canadian Urological Association best practice report: Vasectomy. Can Urol Assoc J. 2022;16:E231-6.
  • 21
    Appell RA, Evans PR. Vasectomy: etiology of infectious complications. Fertil Steril. 1980;33:52-3.
  • 22
    Faculty of Sexual & Reproductive Healthcare (FSRH): Male and Female Sterilisation. [Internet]. 2014. Available at. <https://www.fsrh.org/standards-and-guidance/fsrh-guidelines-and-statements/method-specific/male-and-female-sterilisation/>
    » https://www.fsrh.org/standards-and-guidance/fsrh-guidelines-and-statements/method-specific/male-and-female-sterilisation/>
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Publication Dates

  • Publication in this collection
    14 Aug 2023
  • Date of issue
    Jul-Aug 2023

History

  • Received
    13 Apr 2023
  • Accepted
    08 May 2023
  • Published
    20 May 2023
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