ABSTRACT

Introduction:

Bladder and urinary sphincter malfunctioning that results from some change in the central and/or peripheral nervous system is defined as neurogenic bladder. The urinary tract symptoms that can be related to its filling, emptying, or both have a significant impact on the quality of life of individuals. The present review was based on the document prepared for the public health system in Brazil as a treatment guidelines proposal.

Material and Methods:

Survey questions were structured as per PICO (Population, Intervention, Control, and Outcome). Search strategies were defined and performed in the MEDLINE/Pubmed, Embase, Epistemonikos and Google Scholar databases. The selection of articles followed the evidence hierarchy concept; evidence body was identified, and the quantitative study data were extracted. The quality of evidence and grade of recommendation were qualitatively assessed according to GRADE (Grading of Recommendations, Assessment, Development and Evaluations).

Results:

A total of 2.707 articles were identified, with 49 of them being selected to compose the basis for this review. Neurogenic bladder treatments were classified according to their focus on filling or emptying symptoms and sub- classified in pharmacological and surgical treatments.

Conclusion:

Treatment guidelines are important tools for the public health system to promote the best practice when treating neurogenic bladder patients.

Keywords:
Urinary Bladder; Neurogenic; Therapeutics; Urinary Sphincter; Artificial

INTRODUCTION

Neurogenic bladder is a term used to define bladder and urinary sphincter malfunctioning that results from some change in the central nervous system (CNS) and/or peripheral nervous system (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... –³3 Panicker JN, Fowler CJ, Kessler TM. Lower urinary tract dysfunction in the neurological patient: clinical assessment and management. Lancet Neurol. 2015; 14:720-32.). In the pediatric population, damage often results from congenital and perinatal defects, such as cerebral palsy, spinal dysraphism, or sacral agenesis. Distinguishing between conditions producing stable damage (e.g., cerebrovascular accident, spinal cord injury, and cauda equina compression) and conditions generating progressive damage (caused by inflammatory or degenerative processes, such as dementias, Parkinson's disease, multiple sclerosis, and peripheral neuropathy) to the nervous system is also possible (²2[No Authors] Urinary Incontinence in Neurological Disease: Management of Lower Urinary Tract Dysfunction in Neurological Disease. In: National Clinical Guideline Centre (UK). Royal College of Physicians. London (UK); Published by the National Clinical Guideline Centre. 2012; vol 1. pp. 47-311.).

Patients with neurogenic lower urinary tract dysfunction have different filling, emptying, or both symptoms (²2[No Authors] Urinary Incontinence in Neurological Disease: Management of Lower Urinary Tract Dysfunction in Neurological Disease. In: National Clinical Guideline Centre (UK). Royal College of Physicians. London (UK); Published by the National Clinical Guideline Centre. 2012; vol 1. pp. 47-311.). The severity of neurogenic bladder dysfunction depends on many factors, including the neurologic lesion's location, nature, extension, and progression. Urinary tract symptoms have a significant impact on the quality of life of individuals, with urinary incontinence being the most expressive. Neurogenic urinary incontinence usually results from bladder overactivity, urethral sphincter dysfunction, or a combination of them (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... ).

Figure 1 shows the Functional Classification of neurogenic voiding disorders based on detrusor functioning and urethral sphincter characteristics (⁴4 Madersbacher H. The various types of neurogenic bladder dysfunction: an update of current therapeutic concepts. Paraplegia. 1990; 28:217-29.).

Medical interventions not necessarily restore the regular urinary function, but the conducts used to treat a patient's bladder dysfunction are able to improve their highly impacted quality of life. Yet, many patients will have to deal with the side effects from medications; the social and psychological consequences from the continuous use of absorbing devices; intermittent self-catheterization or permanent catheterization; urethral slings; and artificial sphincter (²2[No Authors] Urinary Incontinence in Neurological Disease: Management of Lower Urinary Tract Dysfunction in Neurological Disease. In: National Clinical Guideline Centre (UK). Royal College of Physicians. London (UK); Published by the National Clinical Guideline Centre. 2012; vol 1. pp. 47-311.).

The appropriate neurogenic bladder therapy and the successful treatment outcome are the result of an accurate diagnosis based on the patient's clinical history, physical examination, voiding diary, as well as a variety of complementary tests, including urodynamics and imaging (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... ).

MATERIALS AND METHODS

The present review was based on the document prepared for the Brazilian Public Health System (SUS) as a treatment guidelines proposal.

The authors identified and defined the technologies to be considered in the recommendations document, which did not include technologies and treatments previously available at SUS. Because these previously available technologies represent the conventional clinical practice, it was decided that those treatment or follow-up recommendations would not have a defined survey question, except in cases of current uncertainties about their use, cases of disuse, or opportunities of divestment. There were no restrictions on the number of treatments to be listed.

The document exclusively covered the treatments provided to neurogenic bladder patients. Therefore, no new considerations or topics about diagnosis resources were included in the current text. The authors selected survey questions structured as per PICO (Population, Intervention, Control, and Outcome):

1. How effective and safe oxybutynin, tolterodine, solifenacin, and darifenacin are in neurogenic bladder patients?

2. How effective and safe botulinum toxin (onabotulinumtoxin A - Botox®) is in neurogenic bladder patients?

3. How effective and safe surgical treatment with a sling is in neurogenic bladder patients?

4. How effective and safe the artificial urinary sphincter is in neurogenic bladder patients?

5. Is there scientific evidence to support the use of hydrophilic catheters in adult neurogenic bladder patients?

The team of methodologists worked to design search strategies for MEDLINE/Pubmed and Embase databases. Epistemonikos and Google Scholar databases were also used to validate the findings during the search on the primary databases. The search effort was limited to articles published in English, French, and Portuguese. The terms used in the search strategy and the details are found in the ^Appendix APPENDIX 1 SEARCH STRATEGY Question 1: How effective and safe oxybutynin, tolterodine, solifenacin, and darifenacin are in neurogenic bladder patients? 1) Search strategy MEDLINE / Pubmed: ((“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder)) AND (((((“oxybutynin” [Supplementary Concept] OR oxybutynin)) OR (“Tolterodine Tartrate”[Mesh] OR Tolterodine)) OR (“Solifenacin Succinate”[Mesh] OR Solifenacin)) OR (“darifenacin”[Supplementary Concept] OR darifenacin)) Access date: 27/Oct/2017 Total: 254 references EMBASE: (‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘neurogenic urinary bladder’) AND ((‘oxybutynin’/exp OR ‘oxybutynin’ OR ‘tolterodine’/exp OR ‘tolterodine’ OR ‘solifenacin’/exp OR ‘solifenacin’ OR ‘darifenacin’/exp OR ‘darifenacin’) AND [embase]/lim) Access date: 27/Oct/2017 Total: 574 references 2) Selection of evidence Only randomized clinical trials and systematic reviews of randomized controlled trials, which compared the antimuscarinics tolterodine, solifenacin, oxybutynin and darifenacin with placebo, with each other or with other antimuscarinics, were considered eligible. 828 references were retrieved through the search strategies (254 Medline and 574 Embase). 133 duplicates were removed. After removing duplicates, 625 references were evaluated by reading titles and abstracts. 590 references were excluded, leaving 35 references for the complete reading. After full reading 28 studies were excluded: two systematic reviews without meta-analysis; a systematic review with meta-analysis, but with incomplete quantitative analysis and most meta-analyzes with only one study; two clinical studies conducted in patients with non-neurogenic overactive bladder and 23 observational studies. Thus, seven randomized clinicians (23, 25, 17–19, 21, 22), retrieved by the search above, and two more randomized clinical studies retrieved by manual search (20, 24), totaling 9 references, were included. Question 2: How effective and safe botulinum toxin (onabotulinumtoxin A - Botox®) is in neurogenic bladder patients? 1) Search strategy MEDLINE / Pubmed: (((((“Urinary Bladder, Neurogenic”[Mesh] OR “Neurogenic Urinary Bladder” OR “Bladder, Neurogenic” OR “Neurogenic Bladder” OR “Urinary Bladder Neurogenic Dysfunction” OR “Neurogenic Dysfunction of the Urinary Bladder” OR “Neurogenic Urinary Bladder Disorder” OR “Neuropathic Bladder” OR “Urinary Bladder Disorder, Neurogenic” OR “Bladder Disorder Neurogenic” OR “Neuaogenic Bladder Disorders” OR “Neurogenic Bladder Disorder” OR “Urinary Bladder Neurogenesis” OR “Neurogenesis, Urinary Bladder” OR “Bladder Neurogenesis” OR “Neurogenesis, Bladder” OR “Neurogenic Urinary Bladder, Atonic” OR “Neurogenic Bladder, Atonic” OR “Atonic Neurogenic Bladder” OR “Neurogenic; Urinary Bladder, Spastic” OR “Neurogenic Bladder, Spastic” OR “Spastic Neurogenic Bladder” OR “Neuro genic Urinary Bladder, Uninhibited” OR “Neurogenic Bladder, Uninhibited” OR “Uninhibited Neurogenic Bladder”)) AND (“Botulinum Toxin Type A”[Mesh] OR “Botulinum Toxins”[Mesh] OR”Clostridium Botulinum Toxin Type A” OR “Clostridium botulinum A Toxin” OR “Botulinum A Toxin” OR “Toxin, Botulinum A” OR “Botulinum Neurotoxin A” OR “Neurotoxin A, Botulinum” OR “Dysport “ OR “Lasa Brand of Botulinum A Toxin” OR “Speywood Brand of Botulinum A Toxin” OR “Ispen Brand of Botulinum A Toxin” OR “Oculinum” OR “Botox” OR “Merz Brand of Botulinum A Toxin” OR “Allergan Brand of Botulinum A Toxin” OR “Toxins, Botulinum “ OR”Botulinum Toxin” OR “Toxin, Botulinum” OR “Clostridium botulinum Toxins” OR “Toxins, Clostridium botulinum” OR “botulinum Toxins, Clostridium” OR “ Botulin”)) AND (((randomized controlled trial[pt] OR control led clinical trial[pt] OR randomized[tiab] OR placebo[tiab] OR (drug therapy[sh] OR randomly[tiab] OR trial[tiab] OR groups[tiab] NOT (animals [mh] NOT humans [mh]))) Total: 423 references Access date: 23/11Nov/2017 EMBASE: (‘botulinum toxin type a’/exp OR ‘botulinum toxin type a’ OR ‘botulinum toxins’/exp OR ‘botulinum toxins’ OR ‘clostridium botulinum toxin type a’/exp OR ‘clostridium botulinum toxin type a’ OR ‘clostridium botulinum a toxin’/exp OR ‘clostridium botulinum a toxin’ OR ‘botulinum a toxin’/exp OR ‘botulinum a toxin’ OR ‘toxin, botulinum a’ OR ‘botulinum neurotoxin a’/exp OR ‘botulinum neurotoxin a’ OR ‘neurotoxin a, botulinum’ OR ‘dysport’/exp OR ‘dysport’ OR ‘lasa brand of botulinum a toxin’ OR ‘speywood brand of botulinum a toxin’ OR ‘ispen brand of botulinum a toxin’ OR ‘oculinum’/exp OR ‘oculinum’ OR ‘botox’/exp OR ‘botox’ OR ‘merz brand of botulinum a toxin’ OR ‘allergan brand of botulinum a toxin’ OR ‘toxins, botulinum’ OR ‘botulinum toxin’/exp OR ‘botulinum toxin’ OR ‘toxin, botulinum’ OR ‘clostridium botulinum toxins’ OR ‘toxins, clostridium botulinum’ OR ‘botulinum toxins, clostridium’ OR ‘botulin’/exp OR ‘botulin’) AND (‘urinary bladder, neurogenic’/exp OR ‘urinary bladder, neurogenic’ OR ‘neurogenic urinary bladder’ OR ‘bladder, neurogenic’/exp OR ‘bladder, neurogenic’ OR ‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘urinary bladder neurogenic dysfunction’ OR ‘neurogenic dysfunction of the urinary bladder’ OR ‘neurogenic urinary bladder disorder’ OR ‘neuropathic bladder’/exp OR ‘neuropathic bladder’ OR ‘urinary bladder disorder, neurogenic’ OR ‘bladder disorder, neurogenic’ OR ‘neurogenic bladder disorders’ OR ‘neurogenic bladder disorder’ OR ‘urinary bladder neurogenesis’ OR ‘neurogenesis, urinary bladder’ OR ‘bladder neurogenesis’ OR ‘neurogenesis, bladder’ OR ‘neurogenic urinary bladder, atonic’ OR ‘neurogenic bladder, atonic’ OR ‘atonic neurogenic bladder’ OR ‘neurogenic urinary bladder, spastic’ OR ‘neurogenic bladder, spastic’ OR ‘spastic neurogenic bladder’ OR ‘neurogenic urinary bladder, uninhibited’ OR ‘neurogenic bladder, uninhibited’ OR ‘uninhibited neurogenic bladder’) Total: 762 references Access date: 23/Nov/2017 2) Selection of evidence The search for evidence resulted in 1185 references (423 on MEDLINE and 762 on EMBASE). Of these, 122 were excluded because they were duplicated. One thousand and sixty-three references were screened by reading the title and abstracts, of which eighty-two references had their full texts evaluated for confirmation of eligibility. As an inclusion criterion, priority was given to systematic reviews with meta-analysis of randomized controlled trials and primary studies such as comparative randomized controlled trials. Comparative randomized controlled trials not included in systematic reviews were included. 73 studies were excluded because they were narrative reviews, letters to the editor, old systematic reviews for which there are already updates and clinical trials contained in included systematic reviews or because they used a type of botulinum toxin other than onabotulinumtoxinA. Nine studies were included: three systematic reviews with meta-analysis (39, 40, 44) and six randomized clinical trials (37, 38, 41, 42, 43, 45). Question 3: How effective and safe surgical treatment with a sling is in neurogenic bladder patients? 1) Search strategy MEDLINE / Pubmed: ((“Suburethral Slings”[Mesh] OR sling surgery OR sling OR Suburethral Slings OR Midurethral Sling)) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder) Total: 117 references Access date: 27/Oct/2017 EMBASE: ((“Suburethral Slings”[Mesh] OR sling surgery OR sling OR Suburethral Slings OR Midurethral Sling)) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder) Total: 175 references Access date: 27/Oct/2017 2) Selection of evidence The search for evidence in the MEDLINE (via PubMed) and Embase databases resulted in 292 references (117 in MEDLINE and 175 in Embase). Of these, 57 were excluded because they were duplicated. Two hundred and thirty-five references were screened by reading the title and abstracts, of which 46 had their full texts evaluated for confirmation of eligibility. Among the excluded studies, 1 was a non-systematic review, 1 was an editorial, 8 case series in pediatric patients, 4 were not treating sling, 4 clinical trials that performed sling in less than 5 patients, 2 clinical trials that included patients with post-incontinence prostatectomy, 1 study that excluded patients with neurogenic bladder, 2 studies that did not clarify the cause of incontinence and 15 non-comparative retrospectives. The inclusion criteria of the studies consisted of evaluating prospective studies that addressed the use of the technique of interest in patients with neurogenic bladder. Eight studies (8 publications) (72–76, 78–80) were included. Question 4: How effective and safe the artificial urinary sphincter is in neurogenic bladder patients? 1) Search strategy Medline / PubMed: (((“Urinary Sphincter, Artificial”[Mesh] OR Artificial Urinary Sphincter OR artificial sphincter))) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder) Access date: 27/Oct/2017 Total: 190 references EMBASE: (‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘neurogenic urinary bladder’) AND ((‘bladder sphincter prosthesis’/exp OR ‘bladder sphincter prosthesis’ OR ‘artificial urinary sphincter’/exp OR ‘artificial urinary sphincter’ OR ‘artificial sphincter’/exp OR ‘artificial sphincter’) AND [embase]/lim) Access date: 27/Oct/2017 Total: 173 references 2) Selection of evidence The search in the databases resulted in 363 references (190 on MEDLINE and 173 on EMBASE). After removing the duplicates, 280 references were screened by reading the title and abstract. Studies in the pediatric population, studies in the population with non–neurogenic urinary incontinence, case series with less than 10 patients, and case reports were excluded. Twenty-nine publications had their texts evaluated in full, to confirm eligibility, with 28 non-comparative studies and a systematic review. Of these, twelve were excluded for the following reasons: they evaluated the Adjustable Compressive Therapy device (n = 2); only a summary was available, without enough information to answer the research question (n = 3); included pediatric population (n = 2); evaluated intraurethral prosthesis (n = 1); included mixed population (urinary incontinence of different etiologies), with no information on efficacy and safety for the population of interest (n = 4). The systematic review, without meta-analysis, published in 2014, recovered only 54 in its search (not comprehensive) on various surgical treatments in patients with neurogenic bladder and included only eight studies evaluating artificial sphincter, with a poor report on the studies. Three of these studies evaluated the pediatric population and one included a case series with less than 10 patients. So, it was decided to exclude the review and include the primary studies eligible for this research question. In the end, 13 studies (16 publications) were considered eligible to answer the research question (81–96). Question 5: Is there scientific evidence to support the use of hydrophilic catheters in adult neurogenic bladder patients? 1) Search strategy MEDLINE / Pubmed: (((hydrophilic catheter* OR hydrophilic-coated catheter* OR hydrophilic coated catheter* OR hydrophilic catheterization))) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder) Access date: 27/Oct/2017 Total: 23 references EMBASE: (‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘neurogenic urinary bladder’) AND ((‘hydrophilic catheter’ OR ‘hydrophilic coated catheter’ OR ‘hydrophilic-coated catheter’ OR ‘hydrophilic catheterization’) AND [embase]/lim) Access date: 27/Oct/2017 Total: 16 references 2) Selection of evidence The search for evidence resulted in 39 references (23 on MEDLINE and 19 on EMBASE). Of these, 11 were excluded because they were duplicated. Twenty-eight references were screened by reading the title and abstracts, of which fifteen references had their full texts evaluated for confirmation of eligibility. As an inclusion criterion, systematic reviews with meta-analysis of randomized clinical trials and primary studies of the type randomized clinical trials were prioritized. As heterogeneity was observed between the studies and the small number of studies included in the meta-analyzes of the relevant outcomes for the research question, we chose to include the randomized clinical trials present in the systematic reviews that specifically addressed the study population. In total, 11 studies were excluded: 1) one study did not provide sufficient or incomplete information; 2) four studies included interventions of no interest to study; 3) two studies included a pediatric population; 4) a congress summary reference had made the full study available; 5) three studies were observational; 6) two reviews were narrative. The manual search found three systematic reviews with meta-analyzes and two randomized clinical trials included in the reviews. Two randomized clinical trials were included in the search. Thus, four randomized clinical trials present in both the performed and manual searches, as well as in systematic reviews, specifically addressed the study population and were included. In total, seven studies were considered eligible (99, 101–106). .

The selection of articles followed the evidence hierarchy concept. Once the evidence body was identified, the quantitative study data was extracted. The characteristics of the selected studies were defined in order of importance for the interpretation of findings. Both study characteristics and key outcomes as defined in the survey question were extracted. The risk of bias in systematic reviews was evaluated with the use of A MeaSurement Tool to Assess systematic Reviews 2 (AMSTAR-2) in randomized clinical trials using Cochrane's bias risk tool, and in cases of observational studies, with the use of the Newcastle-Ottawa tool and the Quality Assessment of Diagnostic Accuracy Studies 2 (QUADAS-2) (⁵5 Shea BJ, Reeves BC, Wells G, Thuku M, Hamel C, Moran J, et al. AMSTAR 2: a critical appraisal tool for systematic reviews that include randomised or non-randomised studies of healthcare interventions, or both. BMJ. 2017; 358:j4008.–⁸8 Whiting PF, Rutjes AW, Westwood ME, Mallett S, Deeks JJ, Reitsma JB, et al. QUADAS-2: a revised tool for the quality assessment of diagnostic accuracy studies. Ann Intern Med. 2011; 155:529-36.).

The quality of evidence and grade of recommendation were qualitatively assessed according to GRADE (Grading of Recommendations, Assessment, Development and Evaluations) criteria during the recommendation consensus meeting (⁹9 Guyatt GH, Oxman AD, Vist GE, Kunz R, Falck-Ytter Y, Alonso-Coello P, et al. GRADE: an emerging consensus on rating quality of evidence and strength of recommendations. BMJ. 2008; 336:924-6.). The panel specialist's conclusions were presented in the end of the paragraph corresponding to the treatment recommendation.

RESULTS

Two thousand seven hundred seven papers fulfilling the search criteria were identified. Incomplete texts, abstracts, and articles on repeated or duplicated topics were excluded. After a full reading, the articles to compose the database for the present review were selected according to their scientific level of evidence and relevance for the clinical practice. When two or more articles addressed the same topic, the most recent and most complete one was selected. Although many of the articles available in the literature had unarguable scientific and clinical relevance, the huge number made it impossible to include several of the publications, with 49 articles being finally selected.

Once the articles were selected, the authors reviewed them and wrote texts according to the topics for which they were designated. All summaries were presented in a joint session, and after a discussion and approval, a compilation and adjustment process led to the present text.

DISCUSSION

Filling dysfunction Bladder

Behavioral therapy

Behavioral and physical treatments may only be prescribed after the patient is evaluated by a specialist. Prescribed behavioral actions must be associated with patient, family and caregiver education about the neurogenic dysfunction. The specific physical therapy for the urinary system has restricted indication to patients with neurogenic voiding dysfunction. The Specific Physiotherapy is a restricted treatment in patients with neurogenic lower urinary tract dysfunction (NLUTD). Although the results are promising, it is important to recognize that there are no standard treatment regarding the parameters, frequency and electrodes position in different neurological disorders. Transcutaneous electrical nerve stimulation (TENS) may be effective, also demonstrate positive results by the urodynamic study findings, urinary tract symptoms and quality of life (¹⁰10 Liu Y, Xu G, Luo M, Teng HF. Effects of Transcutaneous Electrical Nerve Stimulation at Two Frequencies on Urinary Incontinence in Poststroke Patients: A Randomized Controlled Trial. Am J Phys Med Rehabil. 2016; 95:183-93.–¹³13 Gross T, Schneider MP, Bachmann LM, Blok BF, Groen J, Hoen LA, et al. Transcutaneous Electrical Nerve Stimulation for Treating Neurogenic Lower Urinary Tract Dysfunction: A Systematic Review. Eur Urol. 2016; 69:1102-11.). Systematics reviews describes favorable effects of sacral and posterior tibial nerve stimulation to treat patients with NLUTD however there is a low quality of evidences. For measurable results about that treatment reliable, randomized and controlled studies are required (¹³13 Gross T, Schneider MP, Bachmann LM, Blok BF, Groen J, Hoen LA, et al. Transcutaneous Electrical Nerve Stimulation for Treating Neurogenic Lower Urinary Tract Dysfunction: A Systematic Review. Eur Urol. 2016; 69:1102-11.). (Grade of recommendation: Weak; Quality of evidence: Low)

Pharmacological treatment

The pharmacological treatment of the bladder factor in the neurogenic voiding dysfunction is performed in situations where detrusor overactivity is present. To date, there is not a recommendation for the use of drugs to treat neurogenic detrusor underactivity. The pharmacologic arsenal for the treatment of overactive bladder/detrusor overactivity involves antimuscarinic (or anticholinergic) drugs and beta-3 adrenergic receptor agonists (Figure-2).

Antimuscarinic drugs

Antimuscarinic drugs act by competitively inhibiting the muscarinic receptors (M2 and M3) in the bladder wall, which leads to detrusor muscle relaxation, intravesical pressure reduction, and as a result, increased cystometric capacity and decreased urinary incontinence secondary to detrusor overactivity (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... –³3 Panicker JN, Fowler CJ, Kessler TM. Lower urinary tract dysfunction in the neurological patient: clinical assessment and management. Lancet Neurol. 2015; 14:720-32., ¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.–¹⁶16 Hood B, Andersson KE. Common theme for drugs effective in overactive bladder treatment: inhibition of afferent signaling from the bladder. Int J Urol. 2013; 20:21-7.). Treatment response among patients is variable. Oftentimes, high doses or combined drugs are required to control symptoms, which lead to side effects that frequently result in treatment discontinuation (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... , ¹⁷17 Nardulli R, Losavio E, Ranieri M, Fiore P, Megna G, Bellomo RG, et al. Combined antimuscarinics for treatment of neurogenic overactive bladder. Int J Immunopathol Pharmacol. 2012; 25(1 Suppl):35S-41S.).

The main drugs currently available in Brazil are oxybutynin, tolterodine, solifenacin, and darifenacin. However, there is little scientific evidence of these drug's efficacy and safety as well as which of them would be optimal for the treatment of overactive bladder in adult neurogenic patients (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... –³3 Panicker JN, Fowler CJ, Kessler TM. Lower urinary tract dysfunction in the neurological patient: clinical assessment and management. Lancet Neurol. 2015; 14:720-32., ¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.).

There are no studies directly comparing the four antimuscarinic drugs considered here (darifenacin, oxybutynin, tolterodine, and solifenacin). Therefore, recommending a specific antimuscarinic drug is not possible. The selection must take into consideration the cost of acquisition and the safety profile for each one (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... , ²2[No Authors] Urinary Incontinence in Neurological Disease: Management of Lower Urinary Tract Dysfunction in Neurological Disease. In: National Clinical Guideline Centre (UK). Royal College of Physicians. London (UK); Published by the National Clinical Guideline Centre. 2012; vol 1. pp. 47-311., ¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30., ¹⁵15 Novara G, Galfano A, Secco S, D’Elia C, Cavalleri S, Ficarra V, et al. A systematic review and meta-analysis of randomized controlled trials with antimuscarinic drugs for overactive bladder. Eur Urol. 2008; 54:740-63.) (Grade of recommendation: Strong; Quality of evidence: High)

Oxybutynin

Oxybutynin has antimuscarinic, antispasmodic, and local anesthetic effects. It has high affinity with M1 and M3 muscarinic receptors and with salivary glands, resulting in a major incidence of a dry mouth feeling with its use, which leads to a high treatment dropout rate (¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.–²²22 Fader M, Glickman S, Haggar V, Barton R, Brooks R, Malone-Lee J. Intravesical atropine compared to oral oxybutynin for neurogenic detrusor overactivity: a double-blind, randomized crossover trial. J Urol. 2007; 177:208-13.). Oxybutynin is available as 5mg immediate-release tablets and 10mg extended-release tablets. The recommended daily dose is up to 15mg, depending on the tolerance and treatment response. Oxybutynin at ≥10mg/d doses showed a poorer adverse event profile.

Tolterodine

Tolterodine is a non-selective antimuscarinic drug that has higher affinity with bladder receptors than with salivary and intestinal gland receptors, and therefore, it causes a lower feeling of dry mouth and less constipation when compared with oxybutynin. The extended-release formulation shows superior efficacy with fewer adverse effects (¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.–¹⁶16 Hood B, Andersson KE. Common theme for drugs effective in overactive bladder treatment: inhibition of afferent signaling from the bladder. Int J Urol. 2013; 20:21-7., ²³23 Ethans KD, Nance PW, Bard RJ, Casey AR, Schryvers OI. Efficacy and safety of tolterodine in people with neurogenic detrusor overactivity. J Spinal Cord Med. 2004; 27:214-8., ²⁴24 Van Kerrebroeck PE, Amarenco G, Thüroff JW, Madersbacher HG, Lock MT, Messelink EJ, et al. Dose-ranging study of tolterodine in patients with detrusor hyperreflexia. Neurourol Urodyn. 1998; 17:499-512.). Tolterodine is available as 4mg extended-release capsules. The recommended daily dose is 4mg.

Solifenacin

Solifenacin is an antimuscarinic drug that has higher affinity with M1 and M3 receptors and low incidence of dry mouth (¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.–¹⁶16 Hood B, Andersson KE. Common theme for drugs effective in overactive bladder treatment: inhibition of afferent signaling from the bladder. Int J Urol. 2013; 20:21-7., ²⁵25 Amarenco G, Sutory M, Zachoval R, Agarwal M, Del Popolo G, Tretter R, et al. Solifenacin is effective and well tolerated in patients with neurogenic detrusor overactivity: Results from the double-blind, randomized, active- and placebo-controlled SONIC urodynamic study. Neurourol Urodyn. 2017; 36:414-21.). Solifenacin is available as 5- and 10mg extended-release tablets. The recommended daily dose is up to 10mg, depending on the tolerance and treatment response.

Darifenacin

Darifenacin is a more selective antimuscarinic drug for M3 receptors, showing little affinity with M1 and M2 receptors (¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.–¹⁶16 Hood B, Andersson KE. Common theme for drugs effective in overactive bladder treatment: inhibition of afferent signaling from the bladder. Int J Urol. 2013; 20:21-7., ²⁶26 Zinner N. Darifenacin: a muscarinic M3-selective receptor antagonist for the treatment of overactive bladder. Expert Opin Pharmacother. 2007; 8:511-23.). Darifenacin is available as 7.5- and 15mg extended-release tablets. The recommended daily dose is up to 15mg, depending on the tolerance and treatment response.

Contraindications for the use of antimuscarinic drugs

The absolute contraindications for the use of antimuscarinic drugs include urinary retention (if not included in an intermittent self-catheterization program), gastric retention, acute-angle glaucoma, and known hypersensitivity to the drug. The relative contraindications include partial obstruction of bladder emptying, renal and/or hepatic impairment, excessive use of alcohol, decreased gastrointestinal motility, constipation, and myasthenia gravis (¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.–¹⁶16 Hood B, Andersson KE. Common theme for drugs effective in overactive bladder treatment: inhibition of afferent signaling from the bladder. Int J Urol. 2013; 20:21-7.).

Adverse events

Randomized clinical trial systematic reviews found that oral antimuscarinics yield a significant increase of the incidence of dry mouth. Other adverse events are significantly frequent, when antimuscarinic drugs and placebo are compared - blurred vision, constipation, erythema, fatigue, profuse sweating, and urinary retention (¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30., ¹⁵15 Novara G, Galfano A, Secco S, D’Elia C, Cavalleri S, Ficarra V, et al. A systematic review and meta-analysis of randomized controlled trials with antimuscarinic drugs for overactive bladder. Eur Urol. 2008; 54:740-63.). With regard to treatment discontinuation rate due to adverse effects, all of the evaluated antimuscarinics showed to be similar (darifenacin, solifenacin, tolterodine), except immediate-release oxybutynin that showed a higher rate of discontinuation (²⁷27 Yeaw J, Benner JS, Walt JG, Sian S, Smith DB. Comparing adherence and persistence across 6 chronic medication classes. J Manag Care Pharm. 2009; 15:728-40., ²⁸28 Sexton CC, Notte SM, Maroulis C, Dmochowski RR, Cardozo L, Subramanian D, et al. Persistence and adherence in the treatment of overactive bladder syndrome with anticholinergic therapy: a systematic review of the literature. Int J Clin Pract. 2011; 65:567-85.). Better quality-of-life results are observed in groups on extended-release than immediate-release formulations (¹⁴14 Madhuvrata P, Singh M, Hasafa Z, Abdel-Fattah M. Anticholinergic drugs for adult neurogenic detrusor overactivity: a systematic review and meta-analysis. Eur Urol. 2012; 62:816-30.–¹⁶16 Hood B, Andersson KE. Common theme for drugs effective in overactive bladder treatment: inhibition of afferent signaling from the bladder. Int J Urol. 2013; 20:21-7.). The persistence and adherence to treatment with antimuscarinics, i.e., the time elapsed from onset to discontinuation and in which the usage dose and interval are followed as prescribed, respectively, are the lowest among the chronic-use medications for several diseases (²⁷27 Yeaw J, Benner JS, Walt JG, Sian S, Smith DB. Comparing adherence and persistence across 6 chronic medication classes. J Manag Care Pharm. 2009; 15:728-40.). Discontinuation reaches higher than 80% levels in one year (²⁹29 Chapple CR, Nazir J, Hakimi Z, Bowditch S, Fatoye F, Guelfucci F, et al. Persistence and Adherence with Mirabegron versus Antimuscarinic Agents in Patients with Overactive Bladder: A Retrospective Observational Study in UK Clinical Practice. Eur Urol. 2017; 72:389-99.). Cognitive changes can occur with the use of antimuscarinics. Recently, published studies have demonstrated the correlation of these drugs with cognitive disorders (³⁰30 Krebs J, Scheel-Sailer A, Oertli R, Pannek J. The effects of antimuscarinic treatment on the cognition of spinal cord injured individuals with neurogenic lower urinary tract dysfunction: a prospective controlled before-and-after study. Spinal Cord. 2018; 56:22-27.). Careful use in elderly patients and those with a history of mental illness should be considered.

Beta 3-adrenergic agonist

Mirabegron - the only Beta 3-adrenergic agonist representative - cannot be recommended or contraindicated in detriment to antimuscarinics as the first choice of oral drug treatment because there is no evidence supporting this recommendation yet (³¹31 Wöllner J, Pannek J. Initial experience with the treatment of neurogenic detrusor overactivity with a new β-3 agonist (mirabegron) in patients with spinal cord injury. Spinal Cord. 2016; 54:78-82.–³⁴34 Chen SF, Kuo HC. Therapeutic efficacy of low-dose (25 mg) mirabegron therapy for patients with mild to moderate overactive bladder symptoms due to central nervous system diseases. Low Urin Tract Symptoms. 2019; 11:O53-O58.). (Figure-2) (Grade of recommendation: Conditional; Quality of evidence: Low)

Studies evaluating mirabegron showed efficacy in controlling incontinence symptoms in patients with spinal cord injury and multiple sclerosis (³¹31 Wöllner J, Pannek J. Initial experience with the treatment of neurogenic detrusor overactivity with a new β-3 agonist (mirabegron) in patients with spinal cord injury. Spinal Cord. 2016; 54:78-82.–³⁴34 Chen SF, Kuo HC. Therapeutic efficacy of low-dose (25 mg) mirabegron therapy for patients with mild to moderate overactive bladder symptoms due to central nervous system diseases. Low Urin Tract Symptoms. 2019; 11:O53-O58.). However, it is worth highlighting that two of these studies were case series without a comparator group of which outcomes were only significant in relation to the baseline result. In neurogenic voiding dysfunction patients, mirabegron showed significant reductions in the number of daily micturition and reduction of incontinence episodes over 24 hours (³¹31 Wöllner J, Pannek J. Initial experience with the treatment of neurogenic detrusor overactivity with a new β-3 agonist (mirabegron) in patients with spinal cord injury. Spinal Cord. 2016; 54:78-82.). It is important to stress that one of these studies only showed a significant difference in the results of micturition episodes, urgency episodes, and mean number of incontinence episodes when mirabegron was associated with desmopressin (³²32 Zachariou A, Filiponi M, Baltogiannis D, Giannakis J, Dimitriadis F, Tsounapi P, et al. Effective treatment of neurogenic detrusor overactivity in multiple sclerosis patients using desmopressin and mirabegron. Can J Urol. 2017; 24:9107-13.). No significant difference was observed in micturition results in relation to the study baseline when mirabegron was used as monotherapy. Recently, the use of mirabegron has been evaluated in patients with multiple sclerosis and spinal cord injury. There was an improvement in bladder compliance and a reduction in incontinence episodes with beta 3 adrenergic (³³33 Krhut J, Borovička V, Bílková K, Sýkora R, Míka D, Mokriš J, et al. Efficacy and safety of mirabegron for the treatment of neurogenic detrusor overactivity-Prospective, randomized, double-blind, placebo-controlled study. Neurourol Urodyn. 2018; 37:2226-33., ³⁴34 Chen SF, Kuo HC. Therapeutic efficacy of low-dose (25 mg) mirabegron therapy for patients with mild to moderate overactive bladder symptoms due to central nervous system diseases. Low Urin Tract Symptoms. 2019; 11:O53-O58.).

The adverse events observed with the use of mirabegron are, in general, well tolerated. Arterial hypertension, tachycardia, urinary infections, dizziness, and headache are the most commonly observed adverse events following mirabegron administration (³⁵35 Blauwet MB, Dorrepaal C, Siddiqui E, Martin NE. Mirabegron for the treatment of overactive bladder: a prespecified pooled efficacy analysis and pooled safety analysis of three randomised, double-blind, placebo-controlled, phase III studies. Int J Clin Pract. 2013; 67:619-32.). Patients with controlled arterial hypertension must be monitored previously to the treatment and periodically during the use of the beta 3-adrenergic medication (³⁵35 Blauwet MB, Dorrepaal C, Siddiqui E, Martin NE. Mirabegron for the treatment of overactive bladder: a prespecified pooled efficacy analysis and pooled safety analysis of three randomised, double-blind, placebo-controlled, phase III studies. Int J Clin Pract. 2013; 67:619-32., ³⁶36 Chapple CR, Kaplan SA, Mitcheson D, Klecka J, Cummings J, Drogendijk T, et al. Randomized double-blind, active-controlled phase 3 study to assess 12-month safety and efficacy of mirabegron, a β(3)-adrenoceptor agonist, in overactive bladder. Eur Urol. 2013; 63:296-305.). The concomitant use of beta 1 and beta 2-adrenergic blockers is not contraindicated when mirabegron is administered (³⁵35 Blauwet MB, Dorrepaal C, Siddiqui E, Martin NE. Mirabegron for the treatment of overactive bladder: a prespecified pooled efficacy analysis and pooled safety analysis of three randomised, double-blind, placebo-controlled, phase III studies. Int J Clin Pract. 2013; 67:619-32., ³⁶36 Chapple CR, Kaplan SA, Mitcheson D, Klecka J, Cummings J, Drogendijk T, et al. Randomized double-blind, active-controlled phase 3 study to assess 12-month safety and efficacy of mirabegron, a β(3)-adrenoceptor agonist, in overactive bladder. Eur Urol. 2013; 63:296-305.).

Mirabegron shows a lower discontinuation rate and a longer persistence period than antimuscarinic drugs (²⁸28 Sexton CC, Notte SM, Maroulis C, Dmochowski RR, Cardozo L, Subramanian D, et al. Persistence and adherence in the treatment of overactive bladder syndrome with anticholinergic therapy: a systematic review of the literature. Int J Clin Pract. 2011; 65:567-85.). The mirabegron dose is recommended to be adjusted in patients with kidney and liver failure, and because it inhibits the enzyme CYP, caution should be taken in patients on digoxin and metoprolol (³⁵35 Blauwet MB, Dorrepaal C, Siddiqui E, Martin NE. Mirabegron for the treatment of overactive bladder: a prespecified pooled efficacy analysis and pooled safety analysis of three randomised, double-blind, placebo-controlled, phase III studies. Int J Clin Pract. 2013; 67:619-32., ³⁶36 Chapple CR, Kaplan SA, Mitcheson D, Klecka J, Cummings J, Drogendijk T, et al. Randomized double-blind, active-controlled phase 3 study to assess 12-month safety and efficacy of mirabegron, a β(3)-adrenoceptor agonist, in overactive bladder. Eur Urol. 2013; 63:296-305.).

Surgical treatment Botulinum toxin

Botulinum toxin type A injection into the bladder wall is recommended in adult patients with refractory neurogenic detrusor overactivity where behavioral, physiotherapeutic, and drug therapies reveal to be ineffective or poorly tolerated (³⁷37 Chancellor MB, Patel V, Leng WW, Shenot PJ, Lam W, Globe DR, et al. OnabotulinumtoxinA improves quality of life in patients with neurogenic detrusor overactivity. Neurology. 2013; 81:841-8.–⁴⁴44 Yuan H, Cui Y, Wu J, Peng P, Sun X, Gao Z. Efficacy and Adverse Events Associated With Use of OnabotulinumtoxinA for Treatment of Neurogenic Detrusor Overactivity: A Meta-Analysis. Int Neurourol J. 2017; 21:53-61.) (Grade of recommendation: Strong; Quality of evidence: High).

The effects of the intravesical botulinum toxin injection have been demonstrated in both restoring detrusor stability and consequent resumption of urinary continence and protecting the upper urinary tract by avoiding the deleterious effects on kidneys caused by bladder hypertension (⁴⁵45 Apostolidis A, Thompson C, Yan X, Mourad S. An exploratory, placebo-controlled, dose-response study of the efficacy and safety of onabotulinumtoxinA in spinal cord injury patients with urinary incontinence due to neurogenic detrusor overactivity. World J Urol. 2013; 31:1469-74.–⁴⁷47 Gerridzen RG, Thijssen AM, Dehoux E. Risk factors for upper tract deterioration in chronic spinal cord injury patients. J Urol. 1992; 147:416-8.).

Pre-op preparation

An urodynamic exam is indicated for evaluation of the bladder-sphincter functioning. In addition, it allows evidencing bladder compliance, urinary continence condition, and the bladder emptying phase. The upper urinary tract must be preferably evaluated using ultrasound and pertinent laboratory tests (⁴⁸48 Cruz F, Herschorn S, Aliotta P, Brin M, Thompson C, Lam W, et al. Efficacy and safety of onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity: a randomised, double-blind, placebo-controlled trial. Eur Urol. 2011; 60:742-50., ⁴⁹49 Ginsberg D, Gousse A, Keppenne V, Sievert KD, Thompson C, Lam W, et al. Phase 3 efficacy and tolerability study of onabotulinumtoxinA for urinary incontinence from neurogenic detrusor overactivity. J Urol. 2012; 187:2131-9.). The general clinical evaluation and pre-op tests must be performed according to the good clinical practices. All neurogenic detrusor overactivity patients that are eligible to botulinum toxin intravesical injection, or their caregivers, must be evaluated for their manual dexterity and appropriate cognitive function and accept the possibility of intermittent self-catheterization as a bladder emptying method. One out of four patients with neurogenic detrusor overactivity will develop urinary retention and need of intermittent self-catheterization (⁴⁸48 Cruz F, Herschorn S, Aliotta P, Brin M, Thompson C, Lam W, et al. Efficacy and safety of onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity: a randomised, double-blind, placebo-controlled trial. Eur Urol. 2011; 60:742-50., ⁴⁹49 Ginsberg D, Gousse A, Keppenne V, Sievert KD, Thompson C, Lam W, et al. Phase 3 efficacy and tolerability study of onabotulinumtoxinA for urinary incontinence from neurogenic detrusor overactivity. J Urol. 2012; 187:2131-9.). As many patients already use intermittent self-catheterization, this minimizes the problem of post-op urinary retention in this patient population.

Technique and dosage

Botulinum toxin is injected into the detrusor muscle through cystoscopy, and general anesthesia or sedation may be performed (⁵⁰50 Karsenty G, Denys P, Amarenco G, De Seze M, Gamé X, Haab F, et al. Botulinum toxin A (Botox) intradetrusor injections in adults with neurogenic detrusor overactivity/neurogenic overactive bladder: a systematic literature review. Eur Urol. 2008; 53:275-87.). In patients with spinal cord injury, particularly those with a lesion at the thoracic or cervical level, general anesthesia is required in order to reduce the risk of autonomic dysreflexia. For the rest of cases, it is possible to carry out the procedure under local anesthesia (⁵⁰50 Karsenty G, Denys P, Amarenco G, De Seze M, Gamé X, Haab F, et al. Botulinum toxin A (Botox) intradetrusor injections in adults with neurogenic detrusor overactivity/neurogenic overactive bladder: a systematic literature review. Eur Urol. 2008; 53:275-87., ⁵¹51 Schurch B, Denys P, Kozma CM, Reese PR, Slaton T, Barron R. Reliability and validity of the Incontinence Quality of Life questionnaire in patients with neurogenic urinary incontinence. Arch Phys Med Rehabil. 2007; 88:646-52.). For individuals with neurogenic detrusor overactivity, the recommended dose is 200U, with the possibility of using the 300U dose at the injecting physician's discretion (⁵²52 Gaillet S, Bardot P, Bernuz B, Boissier R, Lenne-Aurier K, Thiry-Escudier I, et al. Five years follow-up study and failures analysis of Botulinum toxin repeated injections to treat neurogenic detrusor overactivity. Prog Urol. 2012; 22:1064-70.). The injection is performed into 20-30 equidistant detrusor sites (Figure-3). The trigone is usually spared due to the theoretical risk of vesicoureteral reflux, although the publications have not proven this effect yet (⁵³53 Kennelly M, Dmochowski R, Ethans K, Karsenty G, Schulte-Baukloh H, Jenkins B, et al. Long-term efficacy and safety of onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity: an interim analysis. Urology. 2013; 81:491-7.). Neither have additional effects been observed when including the trigone in the injection sites (⁵⁴54 Kuo HC, Liao CH, Chung SD. Adverse events of intravesical botulinum toxin a injections for idiopathic detrusor overactivity: risk factors and influence on treatment outcome. Eur Urol. 2010; 58:919-26.).

Monitoring

The procedure is usually performed in an outpatient manner. On average, botulinum toxin effect begins two weeks after injection. Within this period, the residual volume must be monitored, either by ultrasound or bladder catheterization. In patients that do not perform catheterization, if the residual volume is higher than 150mL, establishing the intermittent self-catheterization is suggested (⁴⁸48 Cruz F, Herschorn S, Aliotta P, Brin M, Thompson C, Lam W, et al. Efficacy and safety of onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity: a randomised, double-blind, placebo-controlled trial. Eur Urol. 2011; 60:742-50., ⁴⁹49 Ginsberg D, Gousse A, Keppenne V, Sievert KD, Thompson C, Lam W, et al. Phase 3 efficacy and tolerability study of onabotulinumtoxinA for urinary incontinence from neurogenic detrusor overactivity. J Urol. 2012; 187:2131-9.). There is not a fixed schedule for periodical evaluations. Botulinum toxin must be re-injected when recurrence of urinary symptoms, especially urinary incontinence is verified (on average, 9 months). The minimal interval for botulinum toxin re-injection is 12 weeks, so that anti-toxin antibody formation is not induced (⁴⁸48 Cruz F, Herschorn S, Aliotta P, Brin M, Thompson C, Lam W, et al. Efficacy and safety of onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity: a randomised, double-blind, placebo-controlled trial. Eur Urol. 2011; 60:742-50.).

Side effects

Urinary tract infection and urinary retention are the most frequently observed adverse effects in patients with detrusor overactivity undergoing treatment with botulinum toxin (⁵³53 Kennelly M, Dmochowski R, Ethans K, Karsenty G, Schulte-Baukloh H, Jenkins B, et al. Long-term efficacy and safety of onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity: an interim analysis. Urology. 2013; 81:491-7., ⁵⁵55 MacDonald R, Fink HA, Huckabay C, Monga M, Wilt TJ. Botulinum toxin for treatment of urinary incontinence due to detrusor overactivity: a systematic review of effectiveness and adverse effects. Spinal Cord. 2007; 45:535-41.). Other reported adverse events are less frequent, and they include procedure-related pain, macroscopic hematuria and autonomic dysfunction, generalized weakness, asthenia, malaise, and flu-like symptoms (⁵⁵55 MacDonald R, Fink HA, Huckabay C, Monga M, Wilt TJ. Botulinum toxin for treatment of urinary incontinence due to detrusor overactivity: a systematic review of effectiveness and adverse effects. Spinal Cord. 2007; 45:535-41.). There is no increase of the number of adverse event cases by repeating the botulinum toxin injection (⁵³53 Kennelly M, Dmochowski R, Ethans K, Karsenty G, Schulte-Baukloh H, Jenkins B, et al. Long-term efficacy and safety of onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity: an interim analysis. Urology. 2013; 81:491-7.).

Bladder augmentation - Enterocystoplasty

The surgical bladder augmentation is indicated for the treatment of neurogenic detrusor overactivity when the intravesical botulinum toxin injection fails or in cases of low bladder compliance. The objective of bladder augmentation is to increase bladder capacity and compliance, and with this, to reestablish urinary continence and protect the upper urinary tract against potential deleterious effects of high vesical pressure or chronic urinary retention (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25.–⁵⁸58 Dantas RAF, Calisto FCFS, Vilar FO, Araujo LAP, Lima SVC. Nonsecretory intestinocystoplasty: postoperative outcomes of 25 years. Int Braz J Urol. 2019; 45:681-5.). Any intestinal segment - either of the small intestine or colon - and even a portion of the stomach may be used in bladder augmentation (Figure-4). Problems related to fluid reabsorption led to the complete abandonment of the use of jejunum for this practice. Ileum is the intestinal portion of choice to surgically augment the bladder (enterocystoplasty). Cecum, colon, and sigmoid are alternatives (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25.). (Grade of recommendation: Strong; Quality of evidence: Moderate).

There are few studies and limited evidence on bladder auto-augmentation, and most of them are in a pediatric population. The success rate for neurogenic detrusor overactivity cases is 50%, against 92% success with enterocystoplasty (⁵⁹59 Swami KS, Feneley RC, Hammonds JC, Abrams P. Detrusor myectomy for detrusor overactivity: a minimum 1-year follow-up. Br J Urol. 1998; 81:68-72., ⁶⁰60 Beier-Holgersen R, Kirkeby LT, Nordling J. ‘Clam’ ileocystoplasty. Scand J Urol Nephrol. 1994; 28:55-8.).

Contraindications for enterocystoplasty

The existence of intrinsic intestinal disease (e.g., Chron's disease), post-radiotherapy intestinal abnormalities, inability for or non-acceptance of intermittent self-catheterization are contraindications for enterocystoplasty. Partial kidney failure is seen as a relative contraindication, once most of neurogenic bladder-sphincter dysfunction patients maintain the renal function stable, and in some cases, they even show a reduction in the renal function decline speed following a bladder augmentation (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25.).

Pre-op preparation

An evaluation of the patient's clinical and psychiatric conditions and certification of the acceptance of intermittent self-catheterization (26–100% need intermittent self-catheterization post-operatively) are required, as well as guidance on the potential need for future interventions to achieve urinary continence (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25.). The upper urinary tract functioning must be verified through laboratory tests and imaging methods. Intestinal preparation must be individualized, in accordance with each patient's evacuation pattern. The current trend is not to perform an extensive intestinal preparation, except in major bowel repletion cases.

Post-op follow-up

There may be a demand of approximately three months to adapt to the new functional pattern. Six months following the surgery, a cystography and an urodynamic study must be performed. If there is good capacity, compliance and good bladder emptying, a urinary tract ultrasound must be performed every six months. An abdomen x-ray exam must be performed every at least two years to identify bladder stones (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25.). In case of ileocystoplasty, a metabolic evaluation through laboratory tests must be performed if metabolic acidosis symptoms are identified (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25., ⁵⁸58 Dantas RAF, Calisto FCFS, Vilar FO, Araujo LAP, Lima SVC. Nonsecretory intestinocystoplasty: postoperative outcomes of 25 years. Int Braz J Urol. 2019; 45:681-5.). From the fifth year following bladder augmentation on, an annual cystoscopy helps in the early identification of malignant neoplasms (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25.).

Complications

The use of small bowel segment usually does not lead to changes in the digestive and intestinal absorptive processes. However, approximately one third of bladder-sphincter dysfunction patients undergoing enterocystoplasty progress with increased evacuation frequency, while one quarter shows post-enterocystoplasty fecal incontinence (⁶¹61 Singh G, Thomas DG. Bowel problems after enterocystoplasty. Br J Urol. 1997; 79:328-32.). The use of a more extensive intestinal segment of the ileus terminal portion may lead to a change of vitamin-B12 absorption, and as a result, anemia. Hematologic monitoring is required in the post-op follow-up (⁶²62 Steiner MS, Morton RA, Marshall FF. Vitamin B12 deficiency in patients with ileocolic neobladders. J Urol. 1993; 149:255-7., ⁶³63 Krishna A, Gough DC, Fishwick J, Bruce J. Ileocystoplasty in children: assessing safety and success. Eur Urol. 1995; 27:62-6.).

With regard to complications resulting from the intracavitary surgical approach, approximately 10% of patients will have intestinal obstruction due to post-ileocystoplasty adherence. Spontaneous perforation occurs in 5-10% of bladder augmentations, usually in the intestinal segment used for augmentation or in the anastomosis area with primitive bladder (⁶⁰60 Beier-Holgersen R, Kirkeby LT, Nordling J. ‘Clam’ ileocystoplasty. Scand J Urol Nephrol. 1994; 28:55-8., ⁶¹61 Singh G, Thomas DG. Bowel problems after enterocystoplasty. Br J Urol. 1997; 79:328-32., ⁶⁴64 Rushton HG, Woodard JR, Parrott TS, Jeffs RD, Gearhart JP. Delayed bladder rupture after augmentation enterocystoplasty. J Urol. 1988; 140:344-6.). The most common cause is the increase of intra-reservoir pressure secondary to drainage deficit. The diagnosis is based on clinical symptoms and imaging studies, such as ultrasound and cystography. It is worth highlighting that up to 20% of perforation cases may have a false negative result upon cystography (⁶⁵65 Gough DC. Enterocystoplasty. BJU Int. 2001; 88:739-43.). Minor leakages may be conducted conservatively with vesical drainage with a catheter. Situations with a higher urinary output to the pelvic and peritoneal cavity must be managed by surgical approach.

The formation of bladder stones is more likely to occur the longer the time elapsed since bladder augmentation. The likelihood of bladder stone formation is higher in cases in which bladder augmentation and urinary diversion are associated, such as Mitrofanoff conduit. The chances of bladder calculi recurrence within two years are 30% (⁶⁵65 Gough DC. Enterocystoplasty. BJU Int. 2001; 88:739-43.). Periodic bladder irrigation does not seem to reduce stone formation (⁶⁶66 Brough RJ, O’Flynn KJ, Fishwick J, Gough DC. Bladder washout and stone formation in paediatric enterocystoplasty. Eur Urol. 1998; 33:500-2.). When there is a urinary diversion, endoscopic handling becomes limited and the chances of residual fragments increase.

Asymptomatic bacteriuria occurs in 50-100% of patients following bladder augmentation; however, symptomatic infections are observed in 4-43% only (⁵⁶56 Greenwell TJ, Venn SN, Mundy AR. Augmentation cystoplasty. BJU Int. 2001; 88:511-25., ⁶⁵65 Gough DC. Enterocystoplasty. BJU Int. 2001; 88:739-43.).

The late development of malignant neoplasms in patients with bladder augmentation due to neurogenic dysfunction is relatively rare and less frequent when compared with diversions such as ileal conduit and ureterosigmoidostomy. Periodic evaluation by cystoscopy five years from bladder augmentation and collection of oncotic cytology may be used in the diagnostic evaluation of this complication (⁶⁵65 Gough DC. Enterocystoplasty. BJU Int. 2001; 88:739-43.).

Metabolic disorders following bladder augmentation result from the absorption of substances present in the urine by the intestinal mucosa, such as water, sodium, hydrogen ion, ammonia and chloride, and the increased excretion of potassium and bicarbonate. As a result, in enterocystoplasty, there is a risk of developing hyperchloremic metabolic acidosis (⁶⁷67 Nurse DE, Mundy AR. Metabolic complications of cystoplasty. Br J Urol. 1989; 63:165-70.). Most patients undergoing enterocystoplasty are asymptomatic. When patients become symptomatic, oral administration of sodium bicarbonate is indicated to control the metabolic acidosis. Bone complications secondary to chronic acidosis is more frequently observed in children undergoing bladder augmentation. In adults, bone complications are less significant. Segments that are less commonly used in bladder, jejunum and colon augmentation, respectively, lead to higher water absorption and hyperchloremic metabolic alkalosis (⁶⁷67 Nurse DE, Mundy AR. Metabolic complications of cystoplasty. Br J Urol. 1989; 63:165-70.).

Sacral Neuromodulation

Sacral neuromodulation has been evaluated in patients with neurogenic bladder (⁶⁸68 Lay AH, Das AK. The role of neuromodulation in patients with neurogenic overactive bladder. Curr Urol Rep. 2012; 13:343-7.–⁷⁰70 Averbeck MA, Moreno-Palacios J, Aparicio A. Is there a role for sacral neuromodulation in patients with neurogenic lower urinary tract dysfunction? Int Braz J Urol. 2020; 46:891-901.). Its use in this category of patients, however, is still debatable. There are case series that show some results in selected patients. However, there is a lack of randomized studies and international guidelines do not recommend its routine use. (⁷⁰70 Averbeck MA, Moreno-Palacios J, Aparicio A. Is there a role for sacral neuromodulation in patients with neurogenic lower urinary tract dysfunction? Int Braz J Urol. 2020; 46:891-901.) (Grade of recommendation: Conditional; Quality of evidence: Low).

Sphincter

Pharmacological treatment

A number of drugs, including alpha-adrenergic agonists, estrogens and tricyclic antidepressants, and duloxetine may be used to increase the resistance to urine output. However, there are no studies showing high-level evidence in neurologic patients (⁷¹71 Game X, Cornu JN, Robert G, Descazeaud A, Droupy S, Benard-Laribiere A, et al. Les médicaments de l’urètre [Drug therapy of urethral diseases]. Prog Urol. 2013; 23:1287-98.). (Grade of recommendation: Weak; Quality of evidence: Low)

Surgical treatment

Slings

Autologous fascial sling surgery is recommended for individuals with neurogenic stress incontinence. Sling is a treatment of choice for women with neurogenic urethral sphincter failure. Studies evaluating slings (puboprostatic, transobturator, TVT, pubovaginal) associated with bladder augmentation or associated with intradetrusor botulinum toxin injection showed favorable incontinence control results (⁷²72 Daneshmand S, Ginsberg DA, Bennet JK, Foote J, Killorin W, Rozas KP, et al. Puboprostatic sling repair for treatment of urethral incompetence in adult neurogenic incontinence. J Urol. 2003; 169:199-202.–⁷⁹79 El-Azab AS, El-Nashar SA. Midurethral slings versus the standard pubovaginal slings for women with neurogenic stress urinary incontinence. Int Urogynecol J. 2015; 26:427-32.). One study comparing TVT and pubovaginal (PVS) slings showed similar failure rates in both interventions. Some quality-of-life domains were better in the PVS group than in the TVT group (⁷⁹79 El-Azab AS, El-Nashar SA. Midurethral slings versus the standard pubovaginal slings for women with neurogenic stress urinary incontinence. Int Urogynecol J. 2015; 26:427-32.). However, due to the lack of a control group in most studies as well as the low methodological quality and small population, recommending one type of sling over the other is not possible. Thus, the aponeurotic sling is preferably recommended for women with neurogenic incontinence (⁷⁷77 Athanasopoulos A, Gyftopoulos K, McGuire EJ. Treating stress urinary incontinence in female patients with neuropathic bladder: the value of the autologous fascia rectus sling. Int Urol Nephrol. 2012; 44:1363-7.). (Grade of Recommendation: Strong [for women]; Quality of Evidence: Moderate [for women]).

A systematic review published in 2016 included 15 non-randomized studies that used male urethral slings to treat neurogenic urinary incontinence. Of the 108 men included in those studies, 26 were treated with synthetic slings. The average success rate was 58%. Complications occurred in 14% of cases, with surgical re-interventions in 7%. There was no statistically significant difference in the success rate when compared the sling technique and artificial urinary sphincter implant. However, more surgical re-interventions were necessary after implantation of artificial sphincter compared to slings (n=8 studies, mean=51±25% vs. n=14 studies, mean=7±9%; P <0.003) (⁸⁰80 Farag F, Koens M, Sievert KD, De Ridder D, Feitz W, Heesakkers J. Surgical treatment of neurogenic stress urinary incontinence: A systematic review of quality assessment and surgical outcomes. Neurourol Urodyn. 2016; 35:21-5.). For men with neurogenic sphincter deficiency, the use of slings seems to have modest results, and new studies with a higher level of scientific evidence to demonstrate their efficacy are needed (Grade of recommendation: Conditional [for men]; Quality of evidence: Low [for men]).

Artificial urinary sphincter

Artificial urinary sphincter is recommended for individuals with neurogenic urethral sphincter failure. This is the procedure of choice in males with this dysfunction. Patients using artificial sphincters - the most consistently studied is AMS 800® - usually have high rates of continence (ranging from 70-92%) post-surgery (⁸¹81 Gonzalez R, Dewolf WC. The artificial bladder sphincter AS-721 for the treatment of incontinence in patients with neurogenic bladder. J Urol. 1979; 121:71-2.–⁹⁶96 Guillot-Tantay C, Chartier-Kastler E, Mozer P, Bitker MO, Richard F, Ambrogi V, et al. Traitement de l’incontinence urinaire masculine neurologique par le sphincter urinaire artificiel AMS 800™ (Boston Scientific, Boston, États-Unis): résultats à très long terme (>25ans) [Male neurogenic stress urinary incontinence treated by artificial urinary sphincter AMS 800™ (Boston Scientific, Boston, USA): Very long-term results (>25years)]. Prog Urol. 2018; 28:39-47.). The most frequent adverse events were infection, erosion, and re-operation (⁹²92 Costa P, Poinas G, Ben Naoum K, Bouzoubaa K, Wagner L, Soustelle L, et al. Long-term results of artificial urinary sphincter for women with type III stress urinary incontinence. Eur Urol. 2013; 63:753-8.–⁹⁶96 Guillot-Tantay C, Chartier-Kastler E, Mozer P, Bitker MO, Richard F, Ambrogi V, et al. Traitement de l’incontinence urinaire masculine neurologique par le sphincter urinaire artificiel AMS 800™ (Boston Scientific, Boston, États-Unis): résultats à très long terme (>25ans) [Male neurogenic stress urinary incontinence treated by artificial urinary sphincter AMS 800™ (Boston Scientific, Boston, USA): Very long-term results (>25years)]. Prog Urol. 2018; 28:39-47.). There are no studies comparing two different sphincter models nor comparing them with slings (⁷⁶76 Farag F, Koens M, Sievert KD, De Ridder D, Feitz W, Heesakkers J. Surgical treatment of neurogenic stress urinary incontinence: A systematic review of quality assessment and surgical outcomes. Neurourol Urodyn. 2016; 35:21-5.). Therefore, based on the current clinical practice, the use of AMS 800® sphincter is recommended in adult patients with neurogenic urethral sphincter failure (Grade of recommendation: Strong; Quality of evidence: Moderate).

It is advisable to monitor the upper urinary tract following artificial urinary sphincter surgery (e.g., performing annual ultrasound exams), as some individuals may have their bladder filling function deteriorated after treatment of neurogenic stress urinary incontinence.

Emptying dysfunction

Bladder

Pharmacological treatment

In those patients with underactive detrusor, the use of drugs that improve detrusor contractility has already been researched. However, its use in clinical practice is controversial and there is insufficient evidence to recommend its routine use to improve bladder emptying (⁹⁷97 Barendrecht MM, Oelke M, Laguna MP, Michel MC. Is the use of parasympathomimetics for treating an underactive urinary bladder evidence-based? BJU Int. 2007; 99:749-52.). (Grade of recommendation: Weak; Quality of evidence: Low).

Intermittent catheterization (IC)/Intermittent self-catheterization (ISC)

Intermittent catheterization is the periodic bladder emptying method in which a catheter is introduced through the urethra or through a catheterizable conduit (such as Mitrofanoff or Monti conduits) to the bladder or urinary reservoirs. This is the procedure of choice for neurogenic lower urinary tract dysfunction with incomplete bladder emptying due to detrusor contraction deficit, or temporary or permanent urethral sphincter relaxation difficulty (⁹⁸98 Lapides J, Diokno AC, Silber SJ, Lowe BS. Clean, intermittent self-catheterization in the treatment of urinary tract disease. J Urol. 1972; 107:458-61.–¹⁰⁷107 Truzzi JC, Teich V, Pepe C. Can hydrophilic coated catheters be beneficial for the public healthcare system in Brazil? - A cost-effectiveness analysis in patients with spinal cord injuries. Int Braz J Urol. 2018; 44:121-31.). In individuals with neurogenic bladder dysfunction, intermittent self-catheterization significantly reduces complications, such as urinary infection (UTI), fistulas, vesicoureteral reflux, urethral stenosis, and hydronephrosis. Furthermore, ISC leads to reduced morbidity and mortality, in addition to considerably improving the quality of life (¹⁰⁰100 Chavarriaga J, Fernández N, Campo MAO, Bolivar J, Patiño G, Perez J. Self-perception, quality of life and ease of catheterization in patients with continent urinary diversion with the mitrofanoff principle. Int Braz J Urol. 2020; 46:743-51., ¹⁰²102 Bermingham SL, Hodgkinson S, Wright S, Hayter E, Spinks J, Pellowe C. Intermittent self catheterisation with hydrophilic, gel reservoir, and non-coated catheters: a systematic review and cost effectiveness analysis. BMJ. 2013; 346:e8639.). Hydrophilic catheters were designed to facilitate the intermittent self-catheterization technique, thereby providing patients with higher comfort and reducing the complication rates. Hydrophilic catheters, despite the cost barrier in our community, have been associated with lower rates of symptomatic urinary infection, even in the acute spinal shock phase and hematuria, when compared with PVC catheters (¹⁰¹101 De Ridder DJ, Everaert K, Fernández LG, Valero JV, Durán AB, Abrisqueta ML, et al. Intermittent catheterisation with hydrophilic-coated catheters (SpeediCath) reduces the risk of clinical urinary tract infection in spinal cord injured patients: a prospective randomised parallel comparative trial. Eur Urol. 2005; 48:991-5., ¹⁰⁵105 Cardenas DD, Moore KN, Dannels-McClure A, Scelza WM, Graves DE, Brooks M, Busch AK. Intermittent catheterization with a hydrophilic-coated catheter delays urinary tract infections in acute spinal cord injury: a prospective, randomized, multicenter trial. PM R. 2011; 3:408-17., ¹⁰⁶106 Li L, Ye W, Ruan H, Yang B, Zhang S, Li L. Impact of hydrophilic catheters on urinary tract infections in people with spinal cord injury: systematic review and meta-analysis of randomized controlled trials. Arch Phys Med Rehabil. 2013; 94:782-7.). Systematic reviews and meta-analyses revealed favorable urinary infection and hematuria outcomes with the use of hydrophilic catheters when compared with PVC catheters (¹⁰²102 Bermingham SL, Hodgkinson S, Wright S, Hayter E, Spinks J, Pellowe C. Intermittent self catheterisation with hydrophilic, gel reservoir, and non-coated catheters: a systematic review and cost effectiveness analysis. BMJ. 2013; 346:e8639., ¹⁰⁶106 Li L, Ye W, Ruan H, Yang B, Zhang S, Li L. Impact of hydrophilic catheters on urinary tract infections in people with spinal cord injury: systematic review and meta-analysis of randomized controlled trials. Arch Phys Med Rehabil. 2013; 94:782-7.). Therefore, the use of low friction catheter is suggested in patients showing repetitive infections and with previous urethral lesions. A pharmacologic-economic study conducted in Brazil showed that the hydrophilic catheter is cost-effective for a spinal cord injury population from the perspective of the public health system (¹⁰⁷107 Truzzi JC, Teich V, Pepe C. Can hydrophilic coated catheters be beneficial for the public healthcare system in Brazil? - A cost-effectiveness analysis in patients with spinal cord injuries. Int Braz J Urol. 2018; 44:121-31.). (Grade of recommendation: Strong; Quality of evidence: Moderate)

The frequency of the intermittent self-catheterization performance is determined by the data obtained from the voiding diary. It depends on the patient's bladder functional capacity; fluid ingestion; urodynamic parameters, such as bladder compliance; filling pressure; presence achieved in involuntary contractions; efficacy of the drugs used; presence and availability of a caregiver; etc. It is important that the drained volume is not superior to 400mL and must be regularly verified (¹⁰⁸108 Wyndaele JJ. Complications of intermittent catheterization: their prevention and treatment. Spinal Cord. 2002; 40:536-41., ¹⁰⁹109 Bakke A, Digranes A, Høisaeter PA. Physical predictors of infection in patients treated with clean intermittent catheterization: a prospective 7-year study. Br J Urol. 1997; 79:85-90.). Some factors may limit the performance of intermittent self-catheterization, such as obesity (mainly among women), urethral lesions (diverticula and stenosis), motor sequels, tremor or manual difficulty, cognitive impairment, lower limb hypertonia, hip prosthesis, neuropathic pain, etc.

Despite the controversies, the use of prophylactic antibiotics is not recommended, once there is no evidence that it may reduce the incidence of symptomatic urinary infection episodes, although it reduces the incidence of asymptomatic bacteriuria. However, asymptomatic bacteriuria should not be treated, except when the patient undergoes surgical or endoscopic handling (¹⁰²102 Bermingham SL, Hodgkinson S, Wright S, Hayter E, Spinks J, Pellowe C. Intermittent self catheterisation with hydrophilic, gel reservoir, and non-coated catheters: a systematic review and cost effectiveness analysis. BMJ. 2013; 346:e8639., ¹⁰⁵105 Cardenas DD, Moore KN, Dannels-McClure A, Scelza WM, Graves DE, Brooks M, Busch AK. Intermittent catheterization with a hydrophilic-coated catheter delays urinary tract infections in acute spinal cord injury: a prospective, randomized, multicenter trial. PM R. 2011; 3:408-17.).

Intermittent self-catheterization complications

Intermittent self-catheterization is not free of risks and complications. The most commonly seen complications include urinary infections, bleeding upon handling, and urethral lesions (¹⁰⁸108 Wyndaele JJ. Complications of intermittent catheterization: their prevention and treatment. Spinal Cord. 2002; 40:536-41.).

The most frequent complication from intermittent self-catheterization is urinary tract infection (UTI). The prevalence of UTI associated with intermittent self-catheterization is highly variable in the Urology literature. This is due to the different criteria used (¹⁰⁹109 Bakke A, Digranes A, Høisaeter PA. Physical predictors of infection in patients treated with clean intermittent catheterization: a prospective 7-year study. Br J Urol. 1997; 79:85-90.–¹¹¹111 Maynard FM, Diokno AC. Urinary infection and complications during clean intermittent catheterization following spinal cord injury. J Urol. 1984; 132:943-6.). Case series with long-term follow-ups show that 42% of patients will have recurrent or persistent UTI (¹¹²112 Wyndaele JJ, Maes D. Clean intermittent self-catheterization: a 12-year followup. J Urol. 1990; 143:906-8.). It should be emphasized that the treatment of UTI should only be carried out when symptoms are present (¹¹³113 Lewis RI, Carrion HM, Lockhart JL, Politano VA. Significance of asymptomatic bacteriuria in neurogenic bladder disease. Urology. 1984; 23:343-7.). Intravesical instillation of antibiotics after catheterization and the use of prophylactic low-dose oral antibiotic have been the subject of some studies; however, the results are conflicting (¹¹⁴114 Pearman JW. The value of kanamycin-colistin bladder instillations in reducing bacteriuria during intermittent catheterisation of patients with acute spinal cord injury. Br J Urol. 1979; 51:367-74.–¹¹⁶116 Paradella AC, Musegante AF, Brites C. Comparison of different antibiotic protocols for asymptomatic bacteriuria in patients with neurogenic bladder treated with botulinum toxin A. Braz J Infect Dis. 2016; 20:623-6.). The use of oral ascorbic acid only seems to be helpful in association with antimicrobial agents (¹¹⁷117 Murphy FJ, Zelman S, Mau W. Ascorbic acid as a urinary acidifying agent. 2. Its adjunctive role in chronic urinary infection. J Urol. 1965; 94:300-3.).

Urethral trauma with the presence of bleeding is often observed on the onset of intermittent self-catheterization, but it may persist in up to 30-60% of patients in late phases (¹¹⁸118 Webb RJ, Lawson AL, Neal DE. Clean intermittent self-catheterisation in 172 adults. Br J Urol. 1990; 65:20-3.–¹²⁰120 Stensballe J, Looms D, Nielsen PN, Tvede M. Hydrophilic-coated catheters for intermittent catheterisation reduce urethral micro trauma: a prospective, randomised, participant-blinded, crossover study of three different types of catheters. Eur Urol. 2005; 48:978-83.). Mucosa injury with false passage is also a frequent complication, which may occur due to the presence of urethral stenosis, detrusor-sphincter dyssynergia and increased prostatic volume. Urethral stenosis is a late complication - on average, five years after the onset of intermittent self-catheterization (¹¹⁹119 Perrouin-Verbe B, Labat JJ, Richard I, Mauduyt de la Greve I, Buzelin JM, Mathe JF. Clean intermittent catheterisation from the acute period in spinal cord injury patients. Long term evaluation of urethral and genital tolerance. Paraplegia. 1995; 33:619-24.). The low resistance caused by the catheter surface with hydrophilic coating has been related to the prevention of urethral complications with significant reduction of hematuria episodes (¹¹⁸118 Webb RJ, Lawson AL, Neal DE. Clean intermittent self-catheterisation in 172 adults. Br J Urol. 1990; 65:20-3.).

Sphincter

Pharmacological treatment

Alpha-blockers may be initially used to reduce sphincter resistance and avoid autonomic dysreflexia, although their use is controversial, and their results are limited (¹²¹121 Abrams P, Amarenco G, Bakke A, Buczyński A, Castro-Diaz D, Harrison S, et al. Tamsulosin: efficacy and safety in patients with neurogenic lower urinary tract dysfunction due to suprasacral spinal cord injury. J Urol. 2003; 170(4 Pt 1):1242-51.). (Grade of recommendation: Weak; Quality of evidence: Low)

Surgical treatment - Sphincterotomy

Sphincterotomy is one of the options to treat the incomplete bladder emptying in individuals with neurogenic bladder and should be considered when intermittent self-catheterization is not an option, particularly when there is a risk of upper urinary tract injury (¹²²122 Chancellor MB, Rivas DA, Abdill CK, Karasick S, Ehrlich SM, Staas WE. Prospective comparison of external sphincter balloon dilatation and prosthesis placement with external sphincterotomy in spinal cord injured men. Arch Phys Med Rehabil. 1994; 75:297-305.–¹²⁶126 Mahfouz W, Corcos J. Management of detrusor external sphincter dyssynergia in neurogenic bladder. Eur J Phys Rehabil Med. 2011; 47:639-50.). (Grade of recommendation: Strong, Quality of evidence: Moderate)

A randomized study and a prospective cohort compared sphincterotomy with urethral stent and urethral balloon. Sphincterotomy showed significant results in reducing the voiding pressure and residual post-voiding volume three, six, and 12 months from the procedure in relation to the pre-procedure period. There was no significant difference for micturition outcomes between the groups (¹²²122 Chancellor MB, Rivas DA, Abdill CK, Karasick S, Ehrlich SM, Staas WE. Prospective comparison of external sphincter balloon dilatation and prosthesis placement with external sphincterotomy in spinal cord injured men. Arch Phys Med Rehabil. 1994; 75:297-305., ¹²³123 Chancellor MB, Bennett C, Simoneau AR, Finocchiaro MV, Kline C, Bennett JK, et al. Sphincteric stent versus external sphincterotomy in spinal cord injured men: prospective randomized multicenter trial. J Urol. 1999; 161:1893-8.). However, the hospitalization time, surgery duration, and post-procedure bleeding were significantly higher in the sphincterotomy group (¹²²122 Chancellor MB, Rivas DA, Abdill CK, Karasick S, Ehrlich SM, Staas WE. Prospective comparison of external sphincter balloon dilatation and prosthesis placement with external sphincterotomy in spinal cord injured men. Arch Phys Med Rehabil. 1994; 75:297-305.).

This technique is contraindicated for both women and men with bladder acontratility or unable to adapt to a urine collecting system and it has the potential to limit human reproduction (male factor). Studies evaluating the urethral sphincterotomy showed high success rates in reducing hydronephrosis or bilateral reflux; urinary infection; autonomic dysreflexia; increased bladder emptying; reduction of lost detrusor pressure; and reduction of voiding pressure (¹²⁴124 Fontaine E, Hajri M, Rhein F, Fakacs C, Le Mouel MA, Beurton D. Reappraisal of endoscopic sphincterotomy for post-traumatic neurogenic bladder: a prospective study. J Urol. 1996; 155:277-80.–¹²⁶126 Mahfouz W, Corcos J. Management of detrusor external sphincter dyssynergia in neurogenic bladder. Eur J Phys Rehabil Med. 2011; 47:639-50.). However, this procedure leads to some complications such as hematuria, bacteremia, recurrent urinary infection, high residual volume, and autonomic dysreflexia, in addition to failures such as incomplete sphincterotomy, perineal spasticity, colon sclerosis; re-operation; urethral stenosis, and smooth sphincter dyssynergia (¹²⁴124 Fontaine E, Hajri M, Rhein F, Fakacs C, Le Mouel MA, Beurton D. Reappraisal of endoscopic sphincterotomy for post-traumatic neurogenic bladder: a prospective study. J Urol. 1996; 155:277-80.–¹²⁶126 Mahfouz W, Corcos J. Management of detrusor external sphincter dyssynergia in neurogenic bladder. Eur J Phys Rehabil Med. 2011; 47:639-50.).

Monitoring Neuro-Urological dysfunctions

Neuro-urological disorders are often unstable, and their symptoms may vary considerably, even within a relatively short period. For this reason, a regular follow-up is required. The main problems relative to neurogenic lower urinary tract dysfunctions are kidney failure, ureterohydronephrosis, recurrent urinary infection, and impaired quality of life due to incontinence and bladder emptying difficulty. Patient's monitoring has the purpose of avoiding the frequent infections, impeding renal lesion, and improving the patient's quality of life. Depending on the type of underlying neurological pathology and the current symptom stability, the interval between initial and control investigations may vary; in many cases, it should not exceed one to two years. In high-risk patients (ex: high intravesical pressure), this interval should be shorter (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... –³3 Panicker JN, Fowler CJ, Kessler TM. Lower urinary tract dysfunction in the neurological patient: clinical assessment and management. Lancet Neurol. 2015; 14:720-32.).

Measuring blood creatinine and calculating the glomerular filtration (GF) rate yields a reasonable estimate of the renal function, with low cost. Creatinine clearance provides a more accurate evaluation, but it involves a 24-hour urine collection to estimate creatinine excretion. Special care should be taken in incomplete collection cases, as it may result in underestimation of the renal function. GF rate is more accurately obtained with renal scintigraphy, which is especially recommended when a low renal function is found and in high-risk patients (³3 Panicker JN, Fowler CJ, Kessler TM. Lower urinary tract dysfunction in the neurological patient: clinical assessment and management. Lancet Neurol. 2015; 14:720-32.). Urine test does not need to be a routine examination; it should be especially guided by the patient's symptoms (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... ).

The upper urinary tract must be monitored by ultrasound at regular intervals - every six months in high-risk patients (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... ).

Urodynamic exam must be performed in patients with lower urinary tract symptoms, particularly in cases where there is a risk of renal complications. The exam may be repeated depending on risk factors that might reflect on the upper urinary tract functioning (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... , ²2[No Authors] Urinary Incontinence in Neurological Disease: Management of Lower Urinary Tract Dysfunction in Neurological Disease. In: National Clinical Guideline Centre (UK). Royal College of Physicians. London (UK); Published by the National Clinical Guideline Centre. 2012; vol 1. pp. 47-311., ¹²⁷127 de Sèze M, Ruffion A, Denys P, Joseph PA, Perrouin-Verbe B; GENULF. The neurogenic bladder in multiple sclerosis: review of the literature and proposal of management guidelines. Mult Scler. 2007; 13:915-28., ¹²⁸128 Ghezzi A, Carone R, Del Popolo G, Amato MP, Bertolotto A, Comola M, et al. Recommendations for the management of urinary disorders in multiple sclerosis: a consensus of the Italian Multiple Sclerosis Study Group. Neurol Sci. 2011; 32:1223-31.). It is a fact that the indication for a urodynamic evaluation must be made according to the good medical practice criteria when the symptoms do not allow a clear diagnosis or when the empiric treatment fails, as well as in cases where more invasive treatments are needed (³3 Panicker JN, Fowler CJ, Kessler TM. Lower urinary tract dysfunction in the neurological patient: clinical assessment and management. Lancet Neurol. 2015; 14:720-32., ¹²⁹129 Bosch JL, Cardozo L, Hashim H, Hilton P, Oelke M, Robinson D. Constructing trials to show whether urodynamic studies are necessary in lower urinary tract dysfunction. Neurourol Urodyn. 2011; 30:735-40., ¹³⁰130 Scarpero H. Urodynamics in the evaluation of female LUTS: when are they helpful and how do we use them? Urol Clin North Am. 2014; 41:429-38.).

It is reasonable that any clinical changes or changes in the control tests require investigation and specialized, targeted treatment. However, we lack studies with high level of evidence on this topic, and each recommendation must be seen on an individual basis (¹1 Blok B, Castro-Diaz D, Del Popolo G, Groen J, Hamid R, Karsenty G, et al. Summary of European Association of Urology (EAU) Guidelines on Neuro-Urology 2020. [Internet]. Available at. <https://uroweb.org/guideline/neuro-urology/>
https://uroweb.org/guideline/neuro-urolo... –³3 Panicker JN, Fowler CJ, Kessler TM. Lower urinary tract dysfunction in the neurological patient: clinical assessment and management. Lancet Neurol. 2015; 14:720-32., ¹³¹131 Cintra LKL, de Bessa J Júnior, Kawahara VI, Ferreira TPA, Srougi M, Battistella LR, et al. Cross-cultural adaptation and validation of the neurogenic bladder symptom score questionnaire for Brazilian Portuguese. Int Braz J Urol. 2019; 45:605-14.). (Grade of recommendation: Strong, Quality of evidence: Low).

REFERENCES

APPENDIX 1 SEARCH STRATEGY

Question 1: How effective and safe oxybutynin, tolterodine, solifenacin, and darifenacin are in neurogenic bladder patients?

1) Search strategy

MEDLINE / Pubmed:

((“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder)) AND (((((“oxybutynin” [Supplementary Concept] OR oxybutynin)) OR (“Tolterodine Tartrate”[Mesh] OR Tolterodine)) OR (“Solifenacin Succinate”[Mesh] OR Solifenacin)) OR (“darifenacin”[Supplementary Concept] OR darifenacin))

Access date: 27/Oct/2017

Total: 254 references

EMBASE:

(‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘neurogenic urinary bladder’) AND ((‘oxybutynin’/exp OR ‘oxybutynin’ OR ‘tolterodine’/exp OR ‘tolterodine’ OR ‘solifenacin’/exp OR ‘solifenacin’ OR ‘darifenacin’/exp OR ‘darifenacin’) AND [embase]/lim)

Access date: 27/Oct/2017

Total: 574 references

2) Selection of evidence

Only randomized clinical trials and systematic reviews of randomized controlled trials, which compared the antimuscarinics tolterodine, solifenacin, oxybutynin and darifenacin with placebo, with each other or with other antimuscarinics, were considered eligible.

828 references were retrieved through the search strategies (254 Medline and 574 Embase). 133 duplicates were removed. After removing duplicates, 625 references were evaluated by reading titles and abstracts. 590 references were excluded, leaving 35 references for the complete reading. After full reading 28 studies were excluded: two systematic reviews without meta-analysis; a systematic review with meta-analysis, but with incomplete quantitative analysis and most meta-analyzes with only one study; two clinical studies conducted in patients with non-neurogenic overactive bladder and 23 observational studies. Thus, seven randomized clinicians (²³23 Ethans KD, Nance PW, Bard RJ, Casey AR, Schryvers OI. Efficacy and safety of tolterodine in people with neurogenic detrusor overactivity. J Spinal Cord Med. 2004; 27:214-8., ²⁵25 Amarenco G, Sutory M, Zachoval R, Agarwal M, Del Popolo G, Tretter R, et al. Solifenacin is effective and well tolerated in patients with neurogenic detrusor overactivity: Results from the double-blind, randomized, active- and placebo-controlled SONIC urodynamic study. Neurourol Urodyn. 2017; 36:414-21., ¹⁷17 Nardulli R, Losavio E, Ranieri M, Fiore P, Megna G, Bellomo RG, et al. Combined antimuscarinics for treatment of neurogenic overactive bladder. Int J Immunopathol Pharmacol. 2012; 25(1 Suppl):35S-41S.–¹⁹19 Stöhrer M, Mürtz G, Kramer G, Schnabel F, Arnold EP, Wyndaele JJ; et al. Propiverine compared to oxybutynin in neurogenic detrusor overactivity--results of a randomized, double-blind, multicenter clinical study. Eur Urol. 2007; 51:235-42., ²¹21 Schröder A, Albrecht U, Schnitker J, Reitz A, Stein R. Efficacy, safety, and tolerability of intravesically administered 0.1% oxybutynin hydrochloride solution in adult patients with neurogenic bladder: A randomized, prospective, controlled multi-center trial. Neurourol Urodyn. 2016; 35:582-8., ²²22 Fader M, Glickman S, Haggar V, Barton R, Brooks R, Malone-Lee J. Intravesical atropine compared to oral oxybutynin for neurogenic detrusor overactivity: a double-blind, randomized crossover trial. J Urol. 2007; 177:208-13.), retrieved by the search above, and two more randomized clinical studies retrieved by manual search (²⁰20 Madersbacher H, Stöhrer M, Richter R, Burgdörfer H, Hachen HJ, Mürtz G. Trospium chloride versus oxybutynin: a randomized, double-blind, multicentre trial in the treatment of detrusor hyper-reflexia. Br J Urol. 1995; 75:452-6., ²⁴24 Van Kerrebroeck PE, Amarenco G, Thüroff JW, Madersbacher HG, Lock MT, Messelink EJ, et al. Dose-ranging study of tolterodine in patients with detrusor hyperreflexia. Neurourol Urodyn. 1998; 17:499-512.), totaling 9 references, were included.

Question 2: How effective and safe botulinum toxin (onabotulinumtoxin A - Botox®) is in neurogenic bladder patients?

1) Search strategy

MEDLINE / Pubmed:

(((((“Urinary Bladder, Neurogenic”[Mesh] OR “Neurogenic Urinary Bladder” OR “Bladder, Neurogenic” OR “Neurogenic Bladder” OR “Urinary Bladder Neurogenic Dysfunction” OR “Neurogenic Dysfunction of the Urinary Bladder” OR “Neurogenic Urinary Bladder Disorder” OR “Neuropathic Bladder” OR “Urinary Bladder Disorder, Neurogenic” OR “Bladder Disorder Neurogenic” OR “Neuaogenic Bladder Disorders” OR “Neurogenic Bladder Disorder” OR “Urinary Bladder Neurogenesis” OR “Neurogenesis, Urinary Bladder” OR “Bladder Neurogenesis” OR “Neurogenesis, Bladder” OR “Neurogenic Urinary Bladder, Atonic” OR “Neurogenic Bladder, Atonic” OR “Atonic Neurogenic Bladder” OR “Neurogenic; Urinary Bladder, Spastic” OR “Neurogenic Bladder, Spastic” OR “Spastic Neurogenic Bladder” OR “Neuro genic Urinary Bladder, Uninhibited” OR “Neurogenic Bladder, Uninhibited” OR “Uninhibited Neurogenic Bladder”)) AND (“Botulinum Toxin Type A”[Mesh] OR “Botulinum Toxins”[Mesh] OR”Clostridium Botulinum Toxin Type A” OR “Clostridium botulinum A Toxin” OR “Botulinum A Toxin” OR “Toxin, Botulinum A” OR “Botulinum Neurotoxin A” OR “Neurotoxin A, Botulinum” OR “Dysport “ OR “Lasa Brand of Botulinum A Toxin” OR “Speywood Brand of Botulinum A Toxin” OR “Ispen Brand of Botulinum A Toxin” OR “Oculinum” OR “Botox” OR “Merz Brand of Botulinum A Toxin” OR “Allergan Brand of Botulinum A Toxin” OR “Toxins, Botulinum “ OR”Botulinum Toxin” OR “Toxin, Botulinum” OR “Clostridium botulinum Toxins” OR “Toxins, Clostridium botulinum” OR “botulinum Toxins, Clostridium” OR “ Botulin”)) AND (((randomized controlled trial[pt] OR control led clinical trial[pt] OR randomized[tiab] OR placebo[tiab] OR (drug therapy[sh] OR randomly[tiab] OR trial[tiab] OR groups[tiab] NOT (animals [mh] NOT humans [mh])))

Total: 423 references

Access date: 23/11Nov/2017

EMBASE:

(‘botulinum toxin type a’/exp OR ‘botulinum toxin type a’ OR ‘botulinum toxins’/exp OR ‘botulinum toxins’ OR ‘clostridium botulinum toxin type a’/exp OR ‘clostridium botulinum toxin type a’ OR ‘clostridium botulinum a toxin’/exp OR ‘clostridium botulinum a toxin’ OR ‘botulinum a toxin’/exp OR ‘botulinum a toxin’ OR ‘toxin, botulinum a’ OR ‘botulinum neurotoxin a’/exp OR ‘botulinum neurotoxin a’ OR ‘neurotoxin a, botulinum’ OR ‘dysport’/exp OR ‘dysport’ OR ‘lasa brand of botulinum a toxin’ OR ‘speywood brand of botulinum a toxin’ OR ‘ispen brand of botulinum a toxin’ OR ‘oculinum’/exp OR ‘oculinum’ OR ‘botox’/exp OR ‘botox’ OR ‘merz brand of botulinum a toxin’ OR ‘allergan brand of botulinum a toxin’ OR ‘toxins, botulinum’ OR ‘botulinum toxin’/exp OR ‘botulinum toxin’ OR ‘toxin, botulinum’ OR ‘clostridium botulinum toxins’ OR ‘toxins, clostridium botulinum’ OR ‘botulinum toxins, clostridium’ OR ‘botulin’/exp OR ‘botulin’) AND (‘urinary bladder, neurogenic’/exp OR ‘urinary bladder, neurogenic’ OR ‘neurogenic urinary bladder’ OR ‘bladder, neurogenic’/exp OR ‘bladder, neurogenic’ OR ‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘urinary bladder neurogenic dysfunction’ OR ‘neurogenic dysfunction of the urinary bladder’ OR ‘neurogenic urinary bladder disorder’ OR ‘neuropathic bladder’/exp OR ‘neuropathic bladder’ OR ‘urinary bladder disorder, neurogenic’ OR ‘bladder disorder, neurogenic’ OR ‘neurogenic bladder disorders’ OR ‘neurogenic bladder disorder’ OR ‘urinary bladder neurogenesis’ OR ‘neurogenesis, urinary bladder’ OR ‘bladder neurogenesis’ OR ‘neurogenesis, bladder’ OR ‘neurogenic urinary bladder, atonic’ OR ‘neurogenic bladder, atonic’ OR ‘atonic neurogenic bladder’ OR ‘neurogenic urinary bladder, spastic’ OR ‘neurogenic bladder, spastic’ OR ‘spastic neurogenic bladder’ OR ‘neurogenic urinary bladder, uninhibited’ OR ‘neurogenic bladder, uninhibited’ OR ‘uninhibited neurogenic bladder’)

Total: 762 references

Access date: 23/Nov/2017

2) Selection of evidence

The search for evidence resulted in 1185 references (423 on MEDLINE and 762 on EMBASE). Of these, 122 were excluded because they were duplicated. One thousand and sixty-three references were screened by reading the title and abstracts, of which eighty-two references had their full texts evaluated for confirmation of eligibility. As an inclusion criterion, priority was given to systematic reviews with meta-analysis of randomized controlled trials and primary studies such as comparative randomized controlled trials. Comparative randomized controlled trials not included in systematic reviews were included.

73 studies were excluded because they were narrative reviews, letters to the editor, old systematic reviews for which there are already updates and clinical trials contained in included systematic reviews or because they used a type of botulinum toxin other than onabotulinumtoxinA.

Nine studies were included: three systematic reviews with meta-analysis (³⁹39 Cheng T, Shuang WB, Jia DD, Zhang M, Tong XN, Yang WD, et al. Efficacy and Safety of OnabotulinumtoxinA in Patients with Neurogenic Detrusor Overactivity: A Systematic Review and Meta-Analysis of Randomized Controlled Trials. PLoS One. 2016; 11:e0159307., ⁴⁰40 Gu HY, Song JK, Zhang WJ, Xie J, Yao QS, Zeng WJ, et al. A systematic review and meta-analysis of effectiveness and safety of therapy for overactive bladder using botulinum toxin A at different dosages. Oncotarget. 2017; 8:90338-50., ⁴⁴44 Yuan H, Cui Y, Wu J, Peng P, Sun X, Gao Z. Efficacy and Adverse Events Associated With Use of OnabotulinumtoxinA for Treatment of Neurogenic Detrusor Overactivity: A Meta-Analysis. Int Neurourol J. 2017; 21:53-61.) and six randomized clinical trials (³⁷37 Chancellor MB, Patel V, Leng WW, Shenot PJ, Lam W, Globe DR, et al. OnabotulinumtoxinA improves quality of life in patients with neurogenic detrusor overactivity. Neurology. 2013; 81:841-8., ³⁸38 Chen YC, Kuo HC. The therapeutic effects of repeated detrusor injections between 200 or 300 units of onabotulinumtoxinA in chronic spinal cord injured patients. Neurourol Urodyn. 2014; 33:129-34., ⁴¹41 Hui C, Keji X, Chonghe J, Ping T, Rubiao O, Jianweng Z, et al. Combined detrusor-trigone BTX-A injections for urinary incontinence secondary to neurogenic detrusor overactivity. Spinal Cord. 2016; 54:46-50., ⁴²42 Šámal V, Mečl J, Šrám J. Submucosal administration of onabotulinumtoxinA in the treatment of neurogenic detrusor overactivity: pilot single-centre experience and comparison with standard injection into the detrusor. Urol Int. 2013; 91:423-8., ⁴³43 Sussman D, Patel V, Del Popolo G, Lam W, Globe D, Pommerville P. Treatment satisfaction and improvement in health-related quality of life with onabotulinumtoxinA in patients with urinary incontinence due to neurogenic detrusor overactivity. Neurourol Urodyn. 2013; 32:242-9., ⁴⁵45 Apostolidis A, Thompson C, Yan X, Mourad S. An exploratory, placebo-controlled, dose-response study of the efficacy and safety of onabotulinumtoxinA in spinal cord injury patients with urinary incontinence due to neurogenic detrusor overactivity. World J Urol. 2013; 31:1469-74.).

Question 3: How effective and safe surgical treatment with a sling is in neurogenic bladder patients?

1) Search strategy

MEDLINE / Pubmed:

((“Suburethral Slings”[Mesh] OR sling surgery OR sling OR Suburethral Slings OR Midurethral Sling)) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder)

Total: 117 references

Access date: 27/Oct/2017

EMBASE:

((“Suburethral Slings”[Mesh] OR sling surgery OR sling OR Suburethral Slings OR Midurethral Sling)) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder)

Total: 175 references

Access date: 27/Oct/2017

2) Selection of evidence

The search for evidence in the MEDLINE (via PubMed) and Embase databases resulted in 292 references (117 in MEDLINE and 175 in Embase). Of these, 57 were excluded because they were duplicated. Two hundred and thirty-five references were screened by reading the title and abstracts, of which 46 had their full texts evaluated for confirmation of eligibility. Among the excluded studies, 1 was a non-systematic review, 1 was an editorial, 8 case series in pediatric patients, 4 were not treating sling, 4 clinical trials that performed sling in less than 5 patients, 2 clinical trials that included patients with post-incontinence prostatectomy, 1 study that excluded patients with neurogenic bladder, 2 studies that did not clarify the cause of incontinence and 15 non-comparative retrospectives. The inclusion criteria of the studies consisted of evaluating prospective studies that addressed the use of the technique of interest in patients with neurogenic bladder. Eight studies (8 publications) (⁷²72 Daneshmand S, Ginsberg DA, Bennet JK, Foote J, Killorin W, Rozas KP, et al. Puboprostatic sling repair for treatment of urethral incompetence in adult neurogenic incontinence. J Urol. 2003; 169:199-202.–⁷⁶76 Farag F, Koens M, Sievert KD, De Ridder D, Feitz W, Heesakkers J. Surgical treatment of neurogenic stress urinary incontinence: A systematic review of quality assessment and surgical outcomes. Neurourol Urodyn. 2016; 35:21-5., ⁷⁸78 Fontaine E, Bendaya S, Desert JF, Fakacs C, Le Mouel MA, Beurton D. Combined modified rectus fascial sling and augmentation ileocystoplasty for neurogenic incontinence in women. J Urol. 1997; 157:109-12.–⁸⁰80 Farag F, Koens M, Sievert KD, De Ridder D, Feitz W, Heesakkers J. Surgical treatment of neurogenic stress urinary incontinence: A systematic review of quality assessment and surgical outcomes. Neurourol Urodyn. 2016; 35:21-5.) were included.

Question 4: How effective and safe the artificial urinary sphincter is in neurogenic bladder patients?

1) Search strategy

Medline / PubMed:

(((“Urinary Sphincter, Artificial”[Mesh] OR Artificial Urinary Sphincter OR artificial sphincter))) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder)

Access date: 27/Oct/2017

Total: 190 references

EMBASE:

(‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘neurogenic urinary bladder’) AND ((‘bladder sphincter prosthesis’/exp OR ‘bladder sphincter prosthesis’ OR ‘artificial urinary sphincter’/exp OR ‘artificial urinary sphincter’ OR ‘artificial sphincter’/exp OR ‘artificial sphincter’) AND [embase]/lim)

Access date: 27/Oct/2017

Total: 173 references

2) Selection of evidence

The search in the databases resulted in 363 references (190 on MEDLINE and 173 on EMBASE). After removing the duplicates, 280 references were screened by reading the title and abstract. Studies in the pediatric population, studies in the population with non–neurogenic urinary incontinence, case series with less than 10 patients, and case reports were excluded. Twenty-nine publications had their texts evaluated in full, to confirm eligibility, with 28 non-comparative studies and a systematic review. Of these, twelve were excluded for the following reasons: they evaluated the Adjustable Compressive Therapy device (n = 2); only a summary was available, without enough information to answer the research question (n = 3); included pediatric population (n = 2); evaluated intraurethral prosthesis (n = 1); included mixed population (urinary incontinence of different etiologies), with no information on efficacy and safety for the population of interest (n = 4).

The systematic review, without meta-analysis, published in 2014, recovered only 54 in its search (not comprehensive) on various surgical treatments in patients with neurogenic bladder and included only eight studies evaluating artificial sphincter, with a poor report on the studies. Three of these studies evaluated the pediatric population and one included a case series with less than 10 patients. So, it was decided to exclude the review and include the primary studies eligible for this research question. In the end, 13 studies (16 publications) were considered eligible to answer the research question (⁸¹81 Gonzalez R, Dewolf WC. The artificial bladder sphincter AS-721 for the treatment of incontinence in patients with neurogenic bladder. J Urol. 1979; 121:71-2.–⁹⁶96 Guillot-Tantay C, Chartier-Kastler E, Mozer P, Bitker MO, Richard F, Ambrogi V, et al. Traitement de l’incontinence urinaire masculine neurologique par le sphincter urinaire artificiel AMS 800™ (Boston Scientific, Boston, États-Unis): résultats à très long terme (>25ans) [Male neurogenic stress urinary incontinence treated by artificial urinary sphincter AMS 800™ (Boston Scientific, Boston, USA): Very long-term results (>25years)]. Prog Urol. 2018; 28:39-47.).

Question 5: Is there scientific evidence to support the use of hydrophilic catheters in adult neurogenic bladder patients?

1) Search strategy

MEDLINE / Pubmed:

(((hydrophilic catheter* OR hydrophilic-coated catheter* OR hydrophilic coated catheter* OR hydrophilic catheterization))) AND (“Urinary Bladder, Neurogenic”[Mesh] OR Neurogenic Urinary Bladder OR Neurogenic Bladder)

Access date: 27/Oct/2017

Total: 23 references

EMBASE:

(‘neurogenic bladder’/exp OR ‘neurogenic bladder’ OR ‘neurogenic urinary bladder’) AND ((‘hydrophilic catheter’ OR ‘hydrophilic coated catheter’ OR ‘hydrophilic-coated catheter’ OR ‘hydrophilic catheterization’) AND [embase]/lim)

Access date: 27/Oct/2017

Total: 16 references

2) Selection of evidence

The search for evidence resulted in 39 references (23 on MEDLINE and 19 on EMBASE). Of these, 11 were excluded because they were duplicated. Twenty-eight references were screened by reading the title and abstracts, of which fifteen references had their full texts evaluated for confirmation of eligibility.

As an inclusion criterion, systematic reviews with meta-analysis of randomized clinical trials and primary studies of the type randomized clinical trials were prioritized. As heterogeneity was observed between the studies and the small number of studies included in the meta-analyzes of the relevant outcomes for the research question, we chose to include the randomized clinical trials present in the systematic reviews that specifically addressed the study population.

In total, 11 studies were excluded: 1) one study did not provide sufficient or incomplete information; 2) four studies included interventions of no interest to study; 3) two studies included a pediatric population; 4) a congress summary reference had made the full study available; 5) three studies were observational; 6) two reviews were narrative. The manual search found three systematic reviews with meta-analyzes and two randomized clinical trials included in the reviews. Two randomized clinical trials were included in the search. Thus, four randomized clinical trials present in both the performed and manual searches, as well as in systematic reviews, specifically addressed the study population and were included. In total, seven studies were considered eligible (⁹⁹99 Truzzi JC, Almeida FM, Nunes EC, Sadi MV. Residual urinary volume and urinary tract infection--when are they linked? J Urol. 2008; 180:182-5., ¹⁰¹101 De Ridder DJ, Everaert K, Fernández LG, Valero JV, Durán AB, Abrisqueta ML, et al. Intermittent catheterisation with hydrophilic-coated catheters (SpeediCath) reduces the risk of clinical urinary tract infection in spinal cord injured patients: a prospective randomised parallel comparative trial. Eur Urol. 2005; 48:991-5.–¹⁰⁶106 Li L, Ye W, Ruan H, Yang B, Zhang S, Li L. Impact of hydrophilic catheters on urinary tract infections in people with spinal cord injury: systematic review and meta-analysis of randomized controlled trials. Arch Phys Med Rehabil. 2013; 94:782-7.).

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