Introduction
Characteristic clinical symptoms of lumbar degenerative diseases include intermittent claudication, low back pain, and leg pain. The condition is often exacerbated on standing, walking, or lumbar extension and can be relieved by forwards-flexion or by sitting [1-3]. Lumbar degenerative diseases also cause bowel, bladder, and erectile dysfunction [4]. Walking and flexion of the lumbar spine, such as sitting forwards, can aggravate walking-evoked erection, and symptoms can be relieved by resting for several minutes. The pathogenesis of walking-evoked erection is unclear; consequently, it is rarely noticed. It has been reported that urge incontinence due to an overactive bladder may be stimulated during walking; this mechanism is similar to the mechanism of development of a walking-evoked erection [5]. In this study, we examined patients with lumbar degenerative diseases and evaluated the pathogenesis and the treatment outcomes of walking-evoked erection and bladder dysfunction.
Materials and Methods
A total of 1,570 male patients from our department with lumbar degenerative diseases including lumbar spinal stenosis, lumbar disk herniation, and spondylolisthesis underwent surgery between April 2003 and June 2017, of these, eight patients presented with walking-evoked erection. The Ethical Committee of Fujieda Heisei Memorial Hospital approved the study protocols (reference no., FHR 28-6). We examined the clinical data of walking-evoked erection, paresthesia, motor dysfunction, bladder, and bowel dysfunction. The neurological status of each participant, before and after surgery, was assessed using the Japanese Orthopedic Association (JOA) score. A urologist examined six patients for evaluation for prostatic hyperplasia and overactive bladder. Patients with a score >5 on the Overactive Bladder Symptom Score (OABSS) were classified as having an overactive bladder [6]. Prostatic hyperplasia was diagnosed using prostatic echo. Lumbar magnetic resonance imaging (MRI) was used for the diagnosis of lumbar degenerative diseases. With regards to surgical treatment, a discectomy was completed for disk herniation, and one- or two-level partial laminectomy was performed in patients with lumbar spinal stenosis. Patients with lumbar disk herniation and spondylolisthesis accompanied by segmental instability underwent posterior lumbar interbody fusion (PLIF) and transformational lumbar interbody fusion (TLIF). Follow-up of all patients lasted for at least 6 months after surgery.
Subsequently, a PubMed search was conducted in May 2019 to identify all studies on walking-evoked erection in English with no publishing year restriction. Clinical articles and case reports were searched, and the reference lists were screened for additional relevant articles. Search terms used were: “lumbar spinal stenosis,” “erection,” and “intermittent priapism.” These terms were combined using the algorithmic terms “AND” to retrieve relevant study titles of reports and abstracts. Additionally, reference lists of the selected articles were further screened to highlight other referenced studies not identified in the original search. Inclusion criteria were: English language studies, case reports, and reviews, including detailed clinical data of the patient, imaging data, and outcome after surgery; abstract; and full-text availability. We selected only surgical cases with walking-evoked erection accompanied by cauda equina symptoms.
Results
Among the 1,570 patients screened in our department, eight patients presented with walking-evoked erection accompanied with cauda equina symptoms. The clinical background of the eight patients with walking-evoked erection is shown in Table 1 and Table 2.
Table 1.
Clinical features of our cases
| Case | Age (yr) | Duration from symptoms to surgery (mo) | Intermittent claudication (m) | Muscle weakness | Numbness in legs | Paresthesia in genitalia or perianal | PTR | ATR | JOA score | OABSS | OAB |
|---|---|---|---|---|---|---|---|---|---|---|---|
| 1 | 57 | 120 | 50 | - | Bilateral S1 areas | + | +/+ | -/- | 15 | 0 | - |
| 2 | 59 | 40 | 100 | - | Left S1 area | + | +/+ | -/- | 17 | 6 | + |
| 3 | 66 | 29 | 100 | - | Bilateral S1 areas | + | ++/++ | ±/± | 4 | 12 | + |
| 4 | 62 | 24 | 50 | - | Bilateral S1 areas | + | +/+ | ±/± | 7 | 5 | + |
| 5 | 77 | 7 | 100 | - | Bilateral S1 areas | - | +/+ | -/- | 13 | 8 | + |
| 6 | 81 | 360 | 30 | - | Bilateral L5 and S1 areas | + | +/+ | ±/± | 16 | 4 | - |
| 7 | 69 | 12 | 100 | - | Bilateral L5 and S1 areas | + | ±/± | ±/± | 14 | NA | NA |
| 8 | 61 | 72 | 50 | - | Bilateral L5 and S1 areas | + | +/+ | -/- | 20 | NA | NA |
PTR, patellar reflex; ATR, achilles reflex; JOA, Japanese Orthopedic Association; OABSS, Overactive Bladder Symptom Score; OAB, overactive bladder; NA, not available.
Table 2.
Radiographical findings, treatment, and postoperative course
| Case | Lesion | Level of lesion | Treatment | Follow-up (mo) | Postoperative JOA score | Postoperative OABSS | Postoperative claudication | Postoperative priapism | Postoperative paresthsia |
|---|---|---|---|---|---|---|---|---|---|
| 1 | Spondylolisthesis | L4/5 | TLIF (L4/5) | 12 | 19 | 1 | Improved | Improved | Improved |
| 2 | Spondylolisthesis | L4/5 | PLIF (L4/5) | 12 | 20 | 3 | Improved | Improved | Improved |
| 3 | LDH | L4/5 | Partial laminectomy+discectomy (L4/5) | 24 | 20 | 12 | Improved | Improved | Improved |
| 4 | LCS+LDH | L3/4, L4/5 | Laminectomy (L3/4)+PLIF (L4/5) | 36 | 24 | 1 | Improved | Improved | Improved |
| 5 | LCS | L3/4, L4/5 | Laminectomy (L3/4)+PLIF (L4/5) | 48 | 17 | 5 | Improved | Improved | - |
| 6 | LCS | L3/4 | Partial laminectomy (L3/4) | 6 | 27 | 3 | Improved | Improved | Improved |
| 7 | LCS | L3/4, L4/5 | Laminectomy (L3/4, L4/5) | After surgery | NA | NA | Improved | Improved | Improved |
| 8 | LCS | L4/5 | PLIF (L4/5) | After surgery | NA | NA | Improved | Improved | Improved |
JOA, Japanese Orthopedic Association; OABSS, Overactive Bladder Symptom Score; TLIF, transformational lumbar interbody fusion; PLIF, posterior lumbar interbody fusion; LDH, lumbar disc herniation; LCS, lumbar canal stenosis; NA, not available.
1. Patient characteristics
Eight participants were included in this study; the average age was 67 years (range, 57–81 years). The median duration from initial cauda equina symptoms to admission for surgery was 83 months (range, 7–360 months). Walking approximately 72.5 m (range, 30–100 m) caused intermittent claudication. All patients had an erection while walking and resting for several minutes, relieved the symptoms. Out of the eight patients, seven had paresthesia in the genitalia or perianal region and developed walking-evoked erection accompanying the paresthesia. In all participants, numbness occurred from the back of the thigh to the bottom of the foot (S1 area), and the Achilles reflex was diminished or absent. The average JOA score was 13.5 points (range, 4–20 points). Bladder dysfunction was evaluated in six of the patients; all were diagnosed with prostatic hyperplasia, while four were diagnosed with an overactive bladder.
2. Radiographical findings
Of the eight patients, MRI, or myelography showed lumbar canal stenosis in four patients, spondylolisthesis in two patients, and disc herniation in two patients. Pathological changes were noticed in one patient at L3/4, in four patients at L4/5, and in three patients at L3/4 and L4/5 levels.
3. Treatment
A total of three patients underwent lumbar decompression surgery, and five patients underwent fusion surgery (PLIF or TLIF). Of the participants, five experienced a single-level decompression, and three underwent a two-level decompression. No complications, such as nerve root injuries, were observed after surgery in any of the patients.
4. Postoperative course
The median follow-up time after surgery was 23 months (range, 0–48 months). After surgery, all patients experienced a complete disappearance of walking-evoked erection. Paresthesias in the genitalia or perianal region disappeared in seven patients. JOA scores improved in six patients; however, two patients did not experience an improved score. OABSS improved in four patients.
5. Literature search
The initial PubMed search yielded 22 reports; six additional studies were identified from reference lists of the selected articles. Duplicates were checked and discarded. As a result, 23 patients, including 13 reports, were included in our study (Table 3) [7-19]. A total of 31 patients, including the eight participants in our study, were included, the average age being 62.1 years (range, 34–81 years). The median duration from any initial cauda equina symptoms to admission for surgery was 55.4 months (range, 3–360 months). Intermittent claudication was caused by walking approximately 121 m (range, 10–350 m). Nineteen patients (61.3%) had paresthesia in the genitalia or perianal region. Bladder dysfunction was demonstrated in nine of the patients (29%), seven of which had urinary incontinence. In total, 26 patients underwent lumbar decompression surgery, and five patients underwent fusion surgery (PLIF or TLIF). The median follow-up after surgery was 22.1 months (range, 0–76.8 months) in all 31 patients. Walking-evoked erection disappeared completely after surgery in all patients.
Table 3.
Clinical features of the previous studies including our cases
| No. | Year | Autors | Age (yr) | Intermittent claudication (m) | Duration from symptoms to surgery (mo) | Paresthesia in genitalia or perianal region | Bladder and bowel dysfunction | Level of lesion | Lesion | Treatment | Follow-up (mo) | Postoperative claudication | Postoperative priapism |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 1 | 1964 | Brish et al. [9] | 36 | NA | 96 | + | + | L3/4 | LCS | Laminectomy (L2–L5) | 1.5 | Improved | Improved |
| 2 | 1979 | Ravindran [18] | 66 | 182 | 48 | - | - | L4/5 | LCS | Laminectomy (L4/5) | 1.5 | Improved | Improved |
| 3 | 1979 | Laha et al. [14] | 36 | 100 | 3 | - | - | L3/4, L4/5 | LCS | Laminectomy (L2–L5) | After surgery | Improved | Improved |
| 4 | 1985 | Ram et al. [17] | 70 | 200 | 12 | - | + (Urinary incontinence) | L2/3, L3/4 | LCS | Laminectomy (L2– L4)+discectomy (L2/3, 3/4) | After surgery | Improved | Improved |
| 5 | 1985 | Maurice-Williams et al. [15] | 60 | 182 | 12 | + | - | L3/4 | LCS | Laminectomy (L3–5) | 24 | Improved | Improved |
| 6 | 1987 | Hopkins et al. [13] | 62 | 50 | 60 | - | - | L3/4, L4/5 | LCS | Laminectomy (L3–4) | 3 | Improved | Improved |
| 7 | 34 | 30 min | 12 | + | - | L4/5 | LCS | Laminectomy (L3–5) | After surgery | Improved | Improved | ||
| 8 | 1987 | Phanthumchinda et al. [16] | 52 | 100 | 24 | + | - | L3/4 | LCS | Laminectomy (L2– 5)+discectomy (L3/4, L4/5) | 6 | Improved | Improved |
| 9 | 1989 | Coraddu et al. [11] | 64 | 150 | 60 | + | - | L4/5 | LCS | Laminectomy (L4/5) | 1 | Improved | Improved |
| 10 | 1989 | Willen et al. [19] | 57 | 50 | 168 | + | + (Urinary incontinence) | L2/3, L4/5 | LCS | Laminectomy (L2/3, L4/5) | 6 | Improved | Improved |
| 11 | 1991 | Hidalgo Ovejero et al. [12] | 56 | 300 | NA | - | - | L3/4, L4/5 | LCS | Laminoarthrectomy (L3/4, L4/5) | 36 | Improved | Improved |
| 12 | 1994 | Baba et al. [7] | 58 | 50 | 84 | + | NA | L3/4,L4/5 | LCS | Partial laminectomy (L3/4 4/5) | 76.8 | Improved | Improved |
| 13 | 81 | 10 | 35 | - | NA | L3/4, L4/5 | Spondylolisthesis | Laminectomy (L3–S1) | After surgery | Improved | Improved | ||
| 14 | 73 | 300 | 36 | + | NA | L4/5 | LCS | Wide laminectomy (L4–L5) | 69.6 | Improved | Improved | ||
| 15 | 72 | 100 | 51 | + | NA | L4/5 | Spondylolisthesis | Wide laminectomy (L4–L5) | 42 | Improved | Improved | ||
| 16 | 65 | 120 | 42 | + | NA | L4/5 | Spondylolisthesis | Partial laminectomy (L4/5) | 36 | Improved | Improved | ||
| 17 | 63 | 80 | 42 | - | NA | L3/4, L4/5 | LCS | Partial laminectomy (L3/4, 4/5) | 33.6 | Improved | Improved | ||
| 18 | 68 | 300 | 66 | + | NA | L3/4, L4/5 | LCS | Partial laminectomy (L4/5) | 20.4 | Improved | Improved | ||
| 19 | 1995 | Baba et al. [8] | 53 | 200 | 22 | - | NA | L4/5 | LCS | Partial laminectomy (L4/5) | 42 | Improved | Improved |
| 20 | 71 | 50 | 46 | - | NA | L4/5 | Spondylolisthesis | Partial laminectomy+CD instrumentation (L4/5) | 34.8 | Unchanged | Improved | ||
| 21 | 64 | 130 | 15.5 | + | NA | L4/5 | Spondylolisthesis | Partial laminectomy (L4/5) | 31.2 | Improved | Improved | ||
| 22 | 59 | 350 | 8 | - | NA | L3/4, L4/5 | LCS | Partial laminectomy (L3/4, L4/5) | 9.6 | Improved | Improved | ||
| 23 | 2007 | Cansever et al. [10] | 74 | 50 | NA | - | - | L4/5 | Spondylolisthesis | PLIF (L4/5) | 72 | Improved | Improved |
| 24 | 2018 | Present study | 57 | 50 | 120 | + | + | L4/5 | Spondylolisthesis | TLIF (L4/5) | 12 | Improved | Improved |
| 25 | 59 | 100 | 40 | + | + (Urinary incontinence) | L4/5 | Spondylolisthesis | PLIF (L4/5) | 12 | Improved | Improved | ||
| 26 | 66 | 100 | 29 | + | + (Urinary incontinence) | L4/5 | LDH | Partial laminectomy+discectomy (L4/5) | 24 | Improved | Improved | ||
| 27 | 62 | 50 | 24 | + | + (Urinary incontinence) | L3/4, L4/5 | LCS+LDH | Laminectomy (L3/4)+PLIF (L4/5) | 36 | Improved | Improved | ||
| 28 | 77 | 100 | 7 | - | + (Urinary incontinence) | L3/4, L4/5 | LCS | Laminectomy (L3/4)+PLIF (L4/5) | 48 | Improved | Improved | ||
| 29 | 81 | 30 | 360 | + | + (Urinary incontinence) | L3/4 | LCS | Partial laminectomy (L3/4) | 6 | Improved | Improved | ||
| 30 | 69 | 100 | 12 | + | - | L3/4, L4/5 | LCS | Laminectomy (L3/4, L4/5) | After surgery | Improved | Improved | ||
| 31 | 61 | 50 | 72 | + | - | L4/5 | LCS | PLIF (L4/5) | After surgery | Improved | Improved |
NA, not available; LCS, lumbar canal stenosis; LDH, lumbar disc herniation; CD instrumentation, Cotrel-Dubosset transpedicular screw arrangement with posterolateral fusion; PLIF, posterior lumbar interbody fusion; TLIF, transformational lumbar interbody fusion.
Discussion
This study comprises the first review of walking-evoked erection in patients with lumbar degenerative diseases. It was first described in 1964 by Brish et al. [9]; followed by several other authors [7-19]. The central finding of the study shows that in patients with lumbar degenerative diseases, the incidence of walking-evoked erection was 0.51% (8/1,570). Furthermore, surgical intervention proved successful in the study participants, as walking-evoked erection disappeared after treatment.
1. Epidemiology and clinical futures
Baba et al. [7] reported that the incidence of walking-evoked erection in patients with lumbar degenerative diseases was 1.8% (9/487), in our study, the incidence were lower at 0.51% (8/1,570). Intermittent claudication is the most specific symptom of central lumbar canal stenosis; intermittent claudication consists of the progressive onset of pain, numbness, weakness, and tingling in the low back, buttocks, and legs, which can be initiated by standing, walking, or lumbar extension [20]. Intermittent claudication in this study was caused by walking a median of 121 m, thus indicating severe grade lumbar canal stenosis. Additionally, paresthesia in the genital and perianal region as an accompanying symptom was confirmed to be highly prevalent in patients with walking-evoked erection; the frequency was 87.5% in our participants. An erection accompanied by paresthesia in the genital and perianal region is a characteristic symptom.
2. Pathogenesis
Penile erection is the result of a complex interaction of psychological, neural, vascular, and endocrine factors. Stimulation for erection can be classified as psychogenic (visual, olfactory, gustatory, etc.) and reflexogenic (stimulation of the glans penis) [21]. Reflexogenic erection is triggered by direct physical stimulation of the genital organs and involves two reflex loops. (1) The pudendacavernosal reflex loop initiates reflexogenic erection: the dorsal nerve of the penis sends afferent sensory information to the sacral erection center S2–4, and the efferent cavernous nerves, through the pelvic nerve, initiate arterial vasodilatation in the erectile tissues of the penis leading to tumescence. (2) In the bulbocavernosus reflex loop, the dorsal nerve of the penis sends afferent sensory information from the penis to the sacral erection center S2–4, while efferent motor neurons travel via the pudendal nerve to the bulbocavernosus muscles [22]. The stimulus for reflexogenic erection comes from external sources such as rubbing paresthesia in the genitalia or perianal region. The functional neuroanatomy of penile erection is shown in Fig. 1 .
Enlarge this image.Fig. 1 .Functional neuroanatomy of penile erection. Direct stimulation of the penis delivers sensory messages to the spinal cord via S2–S4, and then signals traveling from the spinal cord to the penis cause reflexogenic erection. Psychogenic erection is regulated by a centrally connected thoracolumbar (T11–L1) and sacral (S2–4) erection center.
Walking-evoked erection is involved in reflexogenic erection, the pathogenesis of which is unclear. Previous reports have suggested two hypotheses for walking-evoked erection; one report suggested that compression of the cauda equina with the S2–S4 roots in lumbar canal stenosis directly stimulates the pelvic nerve, resulting in the erection. Shintani et al. [23] speculated that walking-evoked erection is caused by intermittent mechanical compression of the cauda equina, which includes the efferent fibers of S2–S4 parasympathetic outflows; they describe posture induced ischemia and compression neuropathy of S2–S4 parasympathetic efferent fibers, causing the symptom of walking-evoked erection. Baba et al. [7] suggested that walking-evoked erection could disturb the circulation within the cauda equina due to increased cerebrospinal fluid pressure in the subarachnoid cavity. However, if mechanical compression of the cauda equina induces walking-evoked erection, its occurrence would be more frequent. However, as this study explains, the erection phenomenon is very rarely noticed. The hypothesis that that induction of erection has some inducing factors other than mechanical compression of the cauda equina is therefore supported. In our study, walking-evoked erection was observed to be accompanied by sensory manifestations such as paresthesia in the genitalia or perianal region; the paresthesia was observed in 61% (19 of 31) of patients.
Additionally, an overactive bladder has often been diagnosed in patients with lumbar degenerative diseases, the frequency of which is 21%–44%, as per previous reports [5,24]. It is reported that walking may induce urge incontinence due to overactive bladder and often occurs after paresthesias in the genitalia or perianal region, the mechanism of which is similar to the development of walking-evoked erection. Interestingly, it has been reported that patients with lumbar canal stenosis had both erection and urge incontinence due to overactive bladder on walking [5]. A urologist evaluated the study participants for bladder function; four out of six patients had both urge incontinence due to overactive bladder, as well as erection on walking, three of which also had paresthesia on walking. The neural pathways of both urination and erection are similar, consisting of the pudendal nerve for genital or perianal sensory input. We speculate that sensory input, such as paresthesias in the genitalia or perianal region, stimulates the pelvic, or perineal nerves through the pudendal nerve and induces reflexogenic erections.
3. Outcome
Patients experienced no further occurrences of walking-evoked erection after surgery. Walking-evoked erection, as well as paresthesias in the genital or perianal region on walking, was eliminated in our patients. Our study followed eight patients, four of which showed an improved OABSS score. Patients with a poor outcome with regards to an overactive bladder in comparison with the outcome of walking-evoked erection were in part due to their having co-existent prostatic hyperplasia. In summary, lumbar decompression surgery plays a vital role in the treatment of walking-evoked erection
Conclusions
The prevalence of lumbar degenerative diseases is expected to increase with the prolonging of the human life span. Symptoms such as intermittent claudication and urogenital symptoms such as incontinence, impotence, and walking-evoked erection should be meticulously examined and treated in patients who present with lumbar degenerative disorders.
Conflicts of interest
No potential conflict of interest relevant to this article was reported.
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Kengo Hirota1, 2, Junya Hanakita1, Toshiyuki Takahashi1, Ryo Kanematsu1, Manabu Ueno3, Hidetoshi Kasuya2, Manabu Minami1
1Spinal Disorders Center, Fujieda Heisei Memorial Hospital, Shizuoka, Japan
2Department of Neurosurgery, Tokyo Women’s Medical University Medical Center East, Tokyo, Japan
3Department of Urology, Fujieda Heisei Memorial Hospital, Shizuoka, Japan
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