Background
Ketamine has been used recreationally since the 1970s for its dissociative and hallucinogenic effects. Since it was first reported in 2007 [
1], there has been an emerging association between ketamine abuse and the development of severe uro/neurological symptoms including dysuria, frequency and urgency in association with a thickened, contracted bladder (reviewed [
2]). Anecdotally, the development of severe bladder pain may impel continued or even increased ketamine usage due to the anaesthetic relief it provides [
3]. Ketamine’s illicit status makes this a difficult patient group to study, and so the full extent and incidence of the problem within the population is unknown, and poor documentation of ketamine usage with respect to the development of functional/structural bladder changes has hindered the causal and staged mapping of the pathogenic pathway. Reports of urological symptoms in a minority of patients prescribed ketamine for chronic pain suggests that some individuals may be highly susceptible [
4,
5].
Histological findings reported to-date for ketamine cystitis include an ulcerated urothelium, neovascularisation, petechial haemorrhages, chronic inflammation/granulation, lymphocytic infiltration, querciphylloid smooth muscle cells (containing peripheral vacuoles) and occasional eosinophilia [
1,
6‐
9]. In the absence of an honest case history, ketamine cystitis may be mistaken histologically for urothelial carcinoma in-situ (CIS) due to a disordered morphology and enlarged nuclei, although the application of histopathological markers such as cytokeratin 20 and p53 can differentiate [
7].
As an emergent condition where there is a suspected causal agent, it is instructive to compare the pathological features of ketamine cystitis to other benign bladder syndromes. Here we have extended the histopathological study of ketamine cystitis to include further specimens and markers, and compared to a cohort of benign bladder specimens reported elsewhere [
10]. This included interstitial cystitis (IC), a chronic and often debilitating inflammatory disorder of the urinary bladder characterised by urinary urgency, frequency and bladder pain, in the absence of infection. As controls, we included non-diseased tissue taken during radical prostatectomy (RP), non-inflammatory dysfunctional conditions of urge urinary incontinence secondary to idiopathic detrusor overactivity (IDO) and stress urinary incontinence (SUI) associated with urodynamic stress incontinence [
10].
Methods
Tissues
All tissue was collected with NHS Research Ethics Committee approval and either with informed patient consent or was used anonymously. Tissue samples were obtained as cold cut biopsies or cystectomy specimens from patients with clinically-diagnosed ketamine cystitis. Some of the ketamine cystitis specimens have been described previously [
7], while others were obtained from James Cook University Hospital.
A control group of bladder biopsies with no history of bladder atypia or malignancy (taken during radical prostatectomies, RP) was included. The series of IC, IDO and SUI specimens has been described previously [
10]. Briefly, the non-trigone cold-cut biopsies were obtained from patients diagnosed with IC, urge urinary incontinence secondary to IDO, or SUI secondary to urodynamic stress incontinence, according to published specifications [
11,
12].
Although there was no statistically significant difference in the mean (range) age for IC, OAB and GSI, at 51 (25–67), 47 (27–71) and 52 (38–80) years, respectively; the ketamine cystitis group was much younger at 26 (19–36) and the RP group older at 71 (61–88).
Immunohistochemistry
Immunoperoxidase labelling was performed on dewaxed, formalin-fixed 5 μm tissue sections using the antibodies and antigen retrieval methods detailed in Table
1. Blocking steps to neutralise endogeneous peroxidase and avidin-binding activities were included. Antigen retrieval for the antibodies raised against epithelial membrane antigen (EMA), neurofilament protein (NFP) and S100 was performed using “High Retrieval” of 20 min in high pH solution at 97°C (Dako) and labelling was performed with an AutostainerLink 48 (Dako).
Table 1
Antibodies used for immunoperoxidase labelling of human bladder biopsies
EMA | E29 | Mouse | Dako | 1:2000 | High retrieval | No |
NGFR | 7 F10 | Mouse | Novocastra | 1:100 | Citric acid pH6 | Yes |
NFP | 2 F11 | Mouse | Dako | 1:3000 | High retrieval | No |
S100 | Z0311 | Rabbit | Dako | 1:6000 | High retrieval | No |
SMA | 1A4 | Mouse | Sigma | 1:4,000 | Trypsin digestion | No |
For the p75 low-affinity nerve growth factor receptor (NGFR) antibody labelling, heat mediated antigen retrieval was performed by boiling for 10 min in 10 mM citric acid buffer (pH 6). The sensitivity of detection of NGFR immunolabelling was increased using a tyramide-based amplification system according to the supplier’s instructions (Dako, UK).
For smooth muscle actin (SMA) labelling, trypsin digestion (0.1%, w/v, Sigma) was performed for 10 min at 37°C in 0.1% (w/v) CaCl2 (pH 7.8). After overnight incubation in primary antibody at 4°C, slides were washed, incubated in biotinylated secondary antibodies and a streptavidin-biotin horseradish peroxidase complex (Dako Cytomation) and visualised using a diaminobenzidine substrate reaction (Sigma-Aldrich).
All sections were counterstained with haematoxylin, dehydrated and mounted in DPX (CellPath). Positive and negative specificity controls were included in all experiments.
Discussion
Ketamine cystitis is a growing global problem afflicting predominantly young patients and exposing them to significant risk of bladder damage with unknown long-term consequences. To-date, there has been little research into the pathology of ketamine cystitis and as a result, the mechanism(s) of the bladder pain and damage remain unknown. This histological study observed expansion of the basal NGFR+ labelling, stromal nerve hyperplasia and the occurrence of superficial neuroma-like lesions which likely contribute to the extreme bladder pain experienced by ketamine cystitis patients.
The discovery of numerous fine NFP
+ nerve fibres throughout the stroma of ketamine cystitis tissues is unusual and to our knowledge has not been previously described. The presence of nerve hyperplasia in ketamine cystitis tissue in conjunction with urothelial damage leading to stromal urine exposure may help to account for the extreme pain experienced by ketamine cystitis patients. Understanding the mechanism of pain in ketamine cystitis is critical to developing effective new treatment strategies since at present, many ketamine users self-manage their pain with increased ketamine use. The current lack of effective clinical pain management for these patients is a key obstacle to cessation of use [
2]. In neuropathic bladders, there have been reports of nerve hyperplasia invading the urothelium [
13]; however, no NFP
+ fibres were observed within the urothelium in this study. In the small group of IC patients studied here only a single sample contained visible NFP
+ fibres in the lamina propria. That this NFP
+ IC patient may have been an undisclosed ketamine user cannot be ruled out; however, the potential utility of NFP as a biomarker for an IC subgroup with similarities of pathogenesis to ketamine cystitis warrants further investigation. Based on current knowledge, the discovery of NFP
+ fibres in the bladder stroma may be a useful, if not unequivocal, clinical biomarker of ketamine cystitis in patients who have non-bacterial cystitis, but do not provide a history of drug use.
A further novel, and apparently unique, feature of ketamine cystitis reported here is the appearance of large peripheral nerve fascicles in the lamina propria, with a predominant Schwannian and perineural component, and some resemblance to a Morton’s neuroma. These lesions appear to arise as a hyperplastic/reactive response and may be consequential to interstitial regeneration following ketamine damage. At present, it is unclear how these changes relate to the degree of pain experienced in these patients; however, they appeared in nearly all (20/21) urology-referred ketamine cystitis patients in this study and were not seen in the other bladder pathologies studied as controls.
The cause of peripheral nerve fascicle hyperplasia in ketamine cystitis tissues remains unknown; however, chronic ketamine users (of at least 4 times/week) have on average twice the serum concentration of brain-derived neurotrophic factor (BDNF) when compared with a control group [
14]. Further study of ketamine cystitis will need to address whether the cause of nerve fascicle hyperplasia is the direct action of ketamine and/or its metabolites; or alternatively, whether circulating BDNF could be the causative agent.
The role of NGFR in the urothelium remains an interesting unknown; however, in RP/IDO/SUI tissues it is most commonly confined to basal urothelial cells. The expansion of NGFR
+ might be indicative of a general dedifferentiation of the tissues; however, no change was noted for other basal markers (eg CK5) and there was no disruption of differentiation markers such as uroplakin 3a (data not shown). Previous studies have reported increased Ki67 indices in ketamine cystitis urothelium [
7] and interpreted with the supra-basal NGFR
+ expansion reported here, this might suggest changes in the epithelium towards a regenerative wound-healing phenotype. This concept is consistent with the widespread urothelial damage observed in ketamine cystitis and retention of uroplakin labelling suggests the urothelium retains a functional barrier in areas where it remains full-thickness. During cystoscopy of one patient the urothelium was observed desquamating from the basement membrane as large sheets, which was consistent with finding histologically that areas of intact full-thickness urothelium were directly adjacent to areas of absent urothelium. Whether the mechanism of urothelial loss relates to direct toxicity of ketamine or the action of a metabolite requires further study.
Whilst ketamine was originally described as a NMDA receptor antagonist, this is a gross oversimplification of its binding promiscuity, which includes activity against β-adrenergic, sigma, and muscarinic receptors [
15]. Recent interest in using ketamine as a rapid-onset anti-depressant and pressure to drive derivatives to market quickly (reviewed [
16]), make understanding the mechanism of ketamine cystitis an urgent clinical problem to avoid side-effects in future therapeutics.
Acknowledgements
The authors are grateful for referral material from the following pathologists: Susan Adams (Yeovil Hospital), Dr N. Mayer (Leicester Royal Infirmary), Dr D. Paterson (Weston General Hospital), Dr M. Lesna (The Royal Bournemouth and Christchurch Hospital), Dr J. Heaton (West Dorset General Hospital) and Dr S. Rose (Royal United Hospital, Bath).
The authors would like to thank Mrs Maya Harris, Mr Khurram Shahzad and Mr Henry Hardacre for their contribution to our research in this area that has not made it into the final publication.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
SCB, JSt and JH carried out experiments, SCB, JSt and JSo conceived experiments and analysed data. SF, IE, FM, JO and DG supported the acquisition of data. All authors were involved in writing the paper and had final approval of the submitted and published versions.