Technology & Innovation in Urology
Discover how modern technology is transforming urological care — from laser-powered kidney stone surgery with no incisions to AI-assisted diagnostics that catch cancer earlier than ever before.
How laser technology treats kidney stones
For decades, kidney stone treatment meant either waiting for stones to pass — an often agonising process — or undergoing open surgery with significant recovery time. Today, high-powered laser technology has fundamentally changed this equation. For the majority of patients, kidney stones can now be treated without a single incision, in under an hour, with discharge the following morning.
The two laser systems used most widely in advanced urology centres are the Holmium:YAG laser and the newer Thulium Fibre Laser (TFL). Both are delivered through the working channel of a flexible ureteroscope passed through the urinary passage — no cuts required.
Holmium Laser Lithotripsy — How it works
The Holmium laser operates at a wavelength of 2,100 nm — absorbed strongly by water in the stone itself. When the laser fibre tip is positioned against a stone and fired in short pulses, energy is transferred directly into the stone, causing it to fragment or, with the right settings, vaporise into fine dust (a technique known as dusting or vapourisation).
Dusting mode produces fragments so small — under 1 mm — that they pass out in the urine on their own, eliminating the need for basket retrieval and significantly shortening procedure time.
- Step 1 — AccessA flexible ureteroscope is passed through the urethra, bladder, and ureter into the kidney. No incision is made at any point.
- Step 2 — VisualisationThe stone is directly visualised on a high-definition monitor. The urologist navigates the flexible scope to reach stones even in the most difficult lower-pole calyces.
- Step 3 — Laser deliveryA laser fibre (200–365 µm diameter) is passed through the scope's working channel and positioned against the stone. Laser energy is applied until the stone is fragmented or dusted.
- Step 4 — Retrieval or passageLarge fragments are retrieved with a stone basket; dust particles pass spontaneously. A ureteric stent is placed to ensure drainage and then removed 10–14 days later.
- Step 5 — ConfirmationCT KUB at 4 weeks confirms stone-free status and assesses kidney function.
The Thulium Fibre Laser, increasingly available at leading centres, offers even finer dusting capability and continuous wave delivery — meaning shorter procedure times and more thorough stone clearance than first-generation Holmium systems.
Benefits of minimally invasive surgery
Minimally invasive surgery (MIS) in urology encompasses a spectrum of approaches — endoscopic, laparoscopic, robotic-assisted, and percutaneous — all united by the goal of achieving the same therapeutic outcome as open surgery with dramatically less trauma to the body. The shift from open to minimally invasive urology over the past two decades has been one of the most consequential improvements in patient care in surgical medicine.
Open surgery vs minimally invasive — a direct comparison
| Factor | Open Surgery | Minimally Invasive |
|---|---|---|
| Incision size | 10–20 cm wound | 0–3 small ports (0.5–1 cm each) |
| Hospital stay | 5–7 days | 1–2 days (often day-care) |
| Blood loss | Moderate–high | Minimal — transfusion rarely needed |
| Post-op pain | Significant — opioid analgesia often required | Mild–moderate — managed with oral medication |
| Return to work | 4–6 weeks | 3–7 days (desk work); 2–3 weeks (physical) |
| Infection risk | Higher — larger wound surface | Significantly lower |
| Scarring | Prominent scar | Minimal to invisible |
| Oncological outcome | Excellent | Equivalent (robotic-assisted) |
For the vast majority of urological procedures today — kidney stone surgery, prostate surgery, bladder tumour resection, and even radical nephrectomy for kidney cancer — minimally invasive approaches deliver outcomes equivalent or superior to open surgery, with substantially better patient experience and recovery.
Robotic-assisted laparoscopic surgery — using the da Vinci Surgical System — extends minimally invasive benefits to complex procedures such as radical prostatectomy, partial nephrectomy, and pyeloplasty. The robotic platform offers 3D magnified vision, tremor filtration, and 7 degrees of instrument movement, enabling precision in tight anatomical spaces that is difficult to match with conventional laparoscopy.
Flexible ureteroscopy explained
Flexible ureteroscopy — the technique underlying RIRS (Retrograde Intrarenal Surgery) — is one of the most significant technological advances in kidney stone management of the past decade. Unlike rigid ureteroscopes that can only reach the ureter, a flexible ureteroscope can navigate through the ureter and fully deflect within the kidney to reach stones in any calyx, including the lower pole, which is inaccessible to shock wave lithotripsy and to rigid instruments.
The flexible ureteroscope — instrument anatomy
Modern single-use flexible ureteroscopes are marvels of engineering compressed into a shaft thinner than a standard pencil. The instrument combines a high-definition camera at the tip, a dedicated irrigation channel for continuous saline flow, a working channel through which laser fibres and stone baskets are passed, and an active deflection mechanism controlled by the surgeon's thumb.
Single-use (disposable) ureteroscopes, now widely used at leading centres, eliminate the cross-infection risk associated with reprocessed instruments and ensure every patient receives a scope with optimal optics and deflection — a meaningful quality improvement over reusable instruments that degrade with repeated sterilisation.
- Tip — CameraChip-on-tip CMOS sensor delivers HD or 4K video directly from inside the kidney. Images are displayed on a large-format surgical monitor, with the surgeon steering the scope in real time.
- Shaft — Irrigation channelContinuous low-pressure saline irrigation maintains a clear visual field, washes out stone debris, and prevents thermal build-up during laser firing.
- Shaft — Working channelA 3.6 Fr working channel accommodates laser fibres (200–365 µm), nitinol stone baskets for fragment retrieval, and biopsy forceps for tissue sampling when needed.
- Handle — Deflection controlA thumb-operated lever provides active tip deflection of up to 270°, enabling navigation to lower-pole calyces — the area most frequently harbouring stones and least accessible by other techniques.
Beyond stone treatment, flexible ureteroscopy is also used for the diagnosis and treatment of upper tract urothelial carcinoma (UTUC) — tumours of the ureter and renal pelvis — enabling biopsy and, in selected cases, laser ablation through the same instrument. This dual diagnostic and therapeutic capability makes it one of the most versatile tools in contemporary urology.
Advanced diagnostics in urology
The ability to detect urological disease earlier, characterise it more accurately, and monitor treatment response in real time has been transformed by a new generation of imaging and biomarker technologies. These tools are now integral to clinical practice at leading urology centres — directly improving outcomes for patients with cancer, kidney stones, and complex functional disorders.
MRI-targeted (fusion) prostate biopsy
Traditional TRUS (transrectal ultrasound-guided) prostate biopsy takes 12 random samples from the prostate, frequently missing clinically significant cancers while simultaneously over-diagnosing low-grade tumours that do not require treatment. Multiparametric MRI (mpMRI) combined with real-time fusion biopsy has fundamentally changed this.
In the MRI-fusion workflow, a multiparametric MRI of the prostate is performed first. Radiologists identify and grade suspicious lesions using the PI-RADS scoring system (scores 1–5). Only lesions scoring PI-RADS 3 or higher are then targeted at biopsy — with the MRI image fused in real time to the live ultrasound feed, guiding the biopsy needle to the exact lesion identified on MRI.
Fusion biopsy detects approximately 30% more clinically significant prostate cancers than standard random biopsy, while simultaneously reducing detection of insignificant low-grade tumours — meaning fewer unnecessary treatments and fewer missed high-grade cancers.
PSMA PET-CT — Next-generation prostate cancer staging
Prostate-specific membrane antigen (PSMA) PET-CT is a nuclear medicine imaging technique that uses a radiolabelled tracer targeting PSMA — a protein overexpressed on prostate cancer cells — to detect even very small deposits of cancer throughout the body. It is now considered superior to conventional CT and bone scan for staging high-risk prostate cancer and detecting biochemical recurrence after treatment.
PSMA PET-CT can detect recurrent prostate cancer deposits as small as 3–4 mm — sites that conventional CT and bone scan would entirely miss. For patients with rising PSA after prostatectomy or radiotherapy, this changes management in 50–60% of cases.
Urodynamic studies — measurement of bladder filling pressures, voiding dynamics, and sphincter function — remain the gold standard for diagnosing complex lower urinary tract dysfunction. Before recommending surgery for incontinence or voiding difficulty, Dr. Utture performs urodynamic testing to confirm the precise mechanism, ensuring the right procedure is selected for each patient.
Future trends in urological care
Urological surgery is entering a new phase shaped by artificial intelligence, single-port robotics, genomic risk stratification, and the integration of real-time data into the operating theatre. Several of these technologies are already in clinical use at leading global centres; others will become standard of care within this decade.
Single-port robotic surgery
The da Vinci SP and Hugo RAS systems perform complex urological procedures through a single 2.5 cm incision — further reducing trauma, scarring, and recovery time compared to multi-port robotic platforms.
In clinical useAI-assisted cystoscopy
Real-time AI image analysis during cystoscopy flags suspicious bladder lesions the naked eye might overlook, improving detection rates for flat or early-stage bladder cancer (CIS) — the most dangerous subtype due to its subtle appearance.
In clinical useGenomic risk stratification
Tissue-based genomic tests (Decipher, Prolaris, Oncotype DX Genomic Prostate Score) analyse the molecular biology of a prostate biopsy to predict cancer aggressiveness beyond Gleason grade — guiding decisions about active surveillance vs immediate treatment.
In clinical useLiquid biopsy for bladder cancer
Urine-based cell-free DNA and exosome analysis can detect early bladder cancer recurrence without cystoscopy — a potential game-changer for the millions of patients requiring lifelong surveillance after bladder tumour resection.
EmergingPredictive stone metabolomics
Machine learning models applied to 24-hour urine metabolic panels and stone composition analysis now predict recurrence risk with unprecedented precision — enabling truly personalised stone prevention programmes.
EmergingAugmented reality in surgery
AR overlays — projecting pre-operative CT or MRI anatomy directly into the surgeon's field of view — are being tested in laparoscopic partial nephrectomy to guide tumour resection margins in real time, reducing the risk of positive surgical margins.
In trialsAt Dr. Utture's Mumbai clinic, patients benefit from the technologies already in established clinical use — flexible ureteroscopy, laser lithotripsy, HoLEP, MRI-fusion biopsy, and urodynamic assessment. As emerging technologies gain evidence and regulatory approval in India, they are evaluated and integrated on a clinical merit basis.
Experience modern urological care — Consult Dr. Anand Utture
Whether you need laser kidney stone surgery, a prostate evaluation, a cancer diagnosis discussion, or a second opinion, Dr. Anand Utture brings the latest in urological technology to his Mumbai practice — with the personalised care every patient deserves.
Book a consultationFrequently asked questions
How does laser technology treat kidney stones?
A Holmium or Thulium fibre laser is delivered through a flexible ureteroscope passed through the natural urinary passage into the kidney. The laser fragments or vaporises the stone into dust with no incisions required. Most patients are discharged within 24 hours, with stone-free rates exceeding 95% for stones up to 20 mm.
What makes minimally invasive urology better than open surgery?
Minimally invasive procedures result in significantly less pain, shorter hospital stays (often 24–48 hours vs 5–7 days for open surgery), faster return to work, reduced infection risk, and minimal scarring. For most urological conditions today — including cancer surgery — open surgery is rarely necessary.
What is flexible ureteroscopy and when is it used?
Flexible ureteroscopy (RIRS) involves passing a thin steerable camera through the urinary passage into the kidney to treat stones with laser energy. It is preferred for stones between 10–20 mm, lower-pole stones inaccessible to shock wave lithotripsy, and patients seeking a no-incision approach. It can also be used to diagnose and treat upper tract tumours.
Is MRI-fusion biopsy available in Mumbai?
Yes. Multiparametric MRI followed by fusion-guided targeted prostate biopsy is available at leading centres in Mumbai. Dr. Utture recommends mpMRI prior to biopsy for men with elevated PSA and no prior biopsy, or in men with a prior negative biopsy where clinical suspicion remains elevated.