By Dr. Anup Ramani

Robotic surgery in urology represents a revolutionary advancement in medical technology, allowing surgeons to perform complex procedures with greater precision and control than traditional methods. This approach uses robotic systems, which surgeons manipulate via a console, to conduct minimally invasive surgeries.

Robotic urological surgeries include procedures like prostatectomy, nephrectomy, and cystectomy, enhancing surgical outcomes and patient recovery. The evolution of robotic surgery in urology began in the early 2000s, driven by the desire to reduce surgical risks and improve postoperative recovery times.

With high-definition 3D vision and articulated instruments that mimic the movements of the human hand, robotic systems offer unparalleled accuracy and dexterity. As a result, these procedures often result in less blood loss, reduced pain, and faster recovery compared to conventional open surgeries.

Robotic surgery’s adoption in urology has grown rapidly, driven by continual technological improvements and increasing evidence of its benefits. The field continues to evolve, promising further advancements that could make these high-precision surgeries even more accessible and effective.

Traditional Surgery vs. Robotic Surgery

Traditional urological surgeries often involve open procedures with large incisions, leading to significant postoperative pain, longer hospital stays, and extended recovery periods. In contrast, robotic surgery utilizes minimally invasive techniques, with small incisions and the use of robotic arms controlled by the surgeon.

This method reduces trauma to the body, minimizes blood loss, and accelerates healing times. Robotic surgery offers enhanced precision, as the robotic instruments provide greater range of motion and stability than the human hand.

Additionally, the high-definition 3D cameras used in robotic surgery provide better visualization of the surgical field, allowing for more accurate dissection and suturing. While traditional surgery remains necessary in certain complex cases where robotic access is limited, the robotic approach is increasingly preferred for many urological procedures.

The choice between traditional and robotic surgery depends on factors such as the specific medical condition, patient health, and the surgeon’s expertise. Both methods have their own sets of advantages and limitations, making the decision a collaborative process between the patient and the healthcare provider.

Milestones in Robotic Surgery

The development of robotic surgery in urology has been marked by several key milestones that have shaped its current practice. The introduction of the da Vinci Surgical System in 2000 was a pivotal moment, providing surgeons with the tools to perform minimally invasive surgeries with unprecedented precision.

Subsequent iterations of this system have incorporated improved imaging technologies, more sophisticated robotic arms, and enhanced software, further refining surgical capabilities. In 2008, the first robotic-assisted laparoscopic prostatectomy was performed, setting a new standard for prostate cancer treatment.

Over the years, robotic systems have been used to perform a wider range of urological procedures, including partial nephrectomies and complex reconstructive surgeries. Clinical studies have consistently shown better outcomes with robotic surgery, including lower complication rates and quicker recoveries. 

These advancements have been driven by continuous research and development, as well as feedback from surgeons and patients. Today, robotic surgery is an integral part of urological practice, with ongoing innovations promising even more improvements in the future.

The Robotic Surgical System

A robotic surgical system comprises several key components, each playing a crucial role in the operation. The most prominent part is the surgeon’s console, where the surgeon sits and controls the robotic instruments.

This console provides a high-definition, 3D view of the surgical area, enhancing the surgeon’s ability to perform precise movements. The patient-side cart holds the robotic arms that carry out the surgeon’s commands.

These arms are equipped with tiny instruments that can rotate and bend far more than a human wrist, allowing for greater flexibility and control within the patient’s body. The robotic system also includes a vision system, which provides real-time images of the surgical site, and a set of foot pedals and hand controls that the surgeon uses to manipulate the instruments.

Advanced software coordinates the movements of the robotic arms, ensuring smooth and accurate operation. The integration of these components enables surgeons to perform complex procedures with higher precision, reduced risk of complications, and improved patient outcomes.

Dr. Anup Ramani Performing Robotic Surgery

Technological Foundations of Robotic Surgery

The technological foundations of robotic surgery in urology combine advancements in robotics, artificial intelligence (AI), and imaging technologies to create a sophisticated surgical environment. Robotics provide the mechanical precision and dexterity needed for complex surgical tasks, while AI algorithms assist in planning and executing procedures with greater accuracy.

High-definition 3D imaging systems enhance the surgeon’s visualization of the surgical field, offering detailed views that are crucial for precise dissection and suturing. These imaging technologies include intraoperative fluoroscopy, MRI, and CT scans, which can be integrated with the robotic system to guide surgical instruments in real-time.

Additionally, haptic feedback technologies are being developed to provide surgeons with tactile sensations, further improving their control over robotic instruments. The continuous improvement of these technologies is driven by research and collaboration between engineers, medical professionals, and tech companies.

This synergy aims to reduce surgical risks, minimize invasiveness, and enhance patient outcomes. As these technologies evolve, the capabilities of robotic systems in urology are expected to expand, making surgeries safer, faster, and more effective.

Robotic Prostatectomy - Common Applications of Robotic Surgery in Urology

Robotic prostatectomy is one of the most common applications of robotic surgery in urology, primarily used to treat prostate cancer. This minimally invasive procedure involves the removal of the prostate gland and surrounding tissues using robotic arms controlled by the surgeon.

The advantages of robotic prostatectomy surgery include greater precision in removing cancerous tissues while sparing important structures such as nerves and blood vessels. This precision reduces the risks of complications like incontinence and erectile dysfunction, which are common concerns in traditional prostate surgery.

The procedure typically results in less blood loss, reduced pain, and shorter hospital stays compared to open surgery. Patients often experience quicker recovery times and can return to their normal activities sooner.

The enhanced 3D visualization and dexterity provided by the robotic system allow surgeons to operate with a level of accuracy that is difficult to achieve with conventional techniques. As a result, robotic prostatectomy has become the preferred method for many urologists in treating prostate cancer, offering patients a safer and more effective surgical option.

Robotic Cystectomy Procedure to Treat Bladder Cancer

Robotic cystectomy is a procedure used to treat bladder cancer by removing the bladder and surrounding tissues, sometimes including the prostate in men or the uterus in women. This surgery is complex and traditionally associated with significant morbidity due to its invasive nature.

However, robotic cystectomy offers several benefits over conventional methods. The robotic system’s enhanced dexterity and precision allow surgeons to perform delicate dissections and reconstructions with greater accuracy.

This precision helps preserve vital structures and reduces the risk of complications. Additionally, patients undergoing robotic cystectomy typically experience less blood loss, lower postoperative pain, and quicker recovery times.

The procedure also allows for better cosmetic outcomes due to smaller incisions. After the removal of the bladder, reconstructive techniques, such as creating a neobladder or an ileal conduit, can be performed more precisely with the robotic system. These advancements improve the quality of life for patients after surgery.

As a result, robotic cystectomy is increasingly adopted as the standard approach for bladder cancer surgery, providing patients with improved outcomes and faster recoveries.

Dr. Anup Ramani Expert in Robotic Surgery

Robotic Nephrectomy

Robotic radical nephrectomy involves the removal of a kidney or part of a kidney and is used to treat conditions such as kidney cancer, severe kidney damage, or benign kidney tumors. There are several types of nephrectomies, including partial, simple, and radical nephrectomies, all of which can be performed robotically.

The robotic approach offers significant advantages, including smaller incisions, less blood loss, and reduced postoperative pain compared to open surgery. The precision of robotic instruments allows surgeons to perform kidney-sparing procedures, such as partial nephrectomies, with high accuracy, preserving as much healthy kidney tissue as possible.

This is particularly important in patients with a single kidney or those at risk of future kidney issues. The enhanced visualization provided by the robotic system enables surgeons to navigate complex anatomy and remove tumors effectively while minimizing damage to surrounding structures.

Patients benefit from shorter hospital stays and quicker return to normal activities. The robotic approach has become a preferred method for nephrectomies, offering a less invasive and more precise surgical option that improves patient outcomes and recovery.

Other Urological Procedures

In addition to prostatectomy, cystectomy, and nephrectomy, robotic surgery is used for a variety of other urological procedures. Robotic pyeloplasty, for instance, is performed to correct ureteropelvic junction obstruction, a condition that impedes urine flow from the kidney to the bladder.

This procedure involves reconstructing the obstructed area to restore normal urine flow. The robotic approach allows for precise dissection and suturing, leading to better surgical outcomes. Another application is robotic ureteral reimplantation, which addresses issues like vesicoureteral reflux by repositioning the ureter to prevent urine from flowing backward into the kidneys.

This minimally invasive technique reduces patient discomfort and recovery time. Additionally, robotic-assisted surgeries are used for procedures such as adrenalectomy, ureterolithotomy, and diverticulectomy.

These applications demonstrate the versatility of robotic systems in addressing a wide range of urological conditions. The precision and minimally invasive nature of robotic surgery provide significant benefits, including less postoperative pain, faster recovery, and improved cosmetic results.

As technology advances, the scope of robotic surgery in urology continues to expand, offering patients more effective and less invasive treatment options.

Unparalleled Precision and Accuracy with Robotic Surgery in Urology

One of the most significant advantages of robotic surgery in urology is its unparalleled precision and accuracy. The robotic system’s articulated instruments can perform intricate maneuvers that surpass the capabilities of the human hand.

This precision is crucial in urological surgeries, where millimeter accuracy can significantly impact outcomes, particularly in procedures involving delicate structures such as nerves and blood vessels. Enhanced 3D visualization provides surgeons with a magnified, high-definition view of the surgical field, allowing for better identification and preservation of critical anatomical features.

The stability of the robotic arms reduces the risk of tremors, ensuring consistent and precise movements. This level of control minimizes the risk of complications, such as inadvertent damage to surrounding tissues.

Consequently, robotic surgery often results in fewer intraoperative and postoperative complications, contributing to better patient outcomes. The ability to perform complex dissections and suturing with high accuracy also allows for more successful reconstructions, such as creating a neobladder after cystectomy.

Overall, the precision and accuracy of robotic surgery enhance the effectiveness of urological procedures, leading to improved patient safety and satisfaction.

Minimally Invasive Nature or Robotic Surgery in Urology

The minimally invasive nature of robotic surgery in urology offers numerous benefits compared to traditional open surgery. Robotic procedures typically involve small incisions, through which the robotic instruments and camera are inserted.

These smaller incisions result in less trauma to the body, reducing postoperative pain and discomfort. Patients who undergo robotic surgery often experience shorter hospital stays and quicker recoveries, allowing them to return to their daily activities sooner.

The reduced tissue disruption also leads to lower rates of infection and other complications associated with larger surgical wounds. Additionally, the cosmetic outcomes are improved, as smaller scars are less noticeable. The minimally invasive approach is particularly advantageous in urological surgeries, where access to deep and confined anatomical areas is required.

The robotic system’s enhanced dexterity and visualization capabilities enable surgeons to perform complex procedures through these small incisions with high precision. This approach not only enhances the patient’s experience but also reduces healthcare costs by minimizing the need for extended postoperative care.

The minimally invasive nature of robotic surgery thus represents a significant advancement in the field of urology, offering safer and more efficient surgical options.

Robotic Surgery in Urology

Improved Outcomes

Robotic surgery in urology is associated with improved outcomes, offering significant benefits over traditional surgical methods. Patients undergoing robotic procedures often experience lower complication rates, such as reduced blood loss and lower risk of infection, thanks to the minimally invasive nature of the surgery

The precision and control provided by robotic systems enable surgeons to perform more accurate and delicate procedures, which translates to better surgical results. For instance, in robotic prostatectomy, the ability to precisely remove the prostate while sparing surrounding nerves reduces the likelihood of side effects such as incontinence and erectile dysfunction.

Similarly, in robotic nephrectomy and cystectomy, the enhanced visualization and dexterity allow for more effective tumor removal and tissue preservation. These factors contribute to faster recovery times and shorter hospital stays, which are significant benefits for patients.

Furthermore, the high-definition 3D imaging used in robotic surgery improves the surgeon’s ability to assess and navigate the surgical field, leading to more successful outcomes.

The overall patient experience is enhanced due to less postoperative pain and quicker return to normal activities. These improved outcomes make robotic surgery an increasingly preferred choice for urological procedures.

Preoperative Considerations

Preparing for robotic surgery involves several preoperative considerations to ensure the best possible outcomes. Patients must undergo a thorough evaluation, including medical history, physical examination, and necessary diagnostic tests, to determine their suitability for the procedure.

Preoperative imaging studies, such as CT scans or MRIs, are often conducted to provide detailed views of the surgical area and assist in planning the surgery. Patients are typically advised to follow specific preoperative instructions, which may include fasting, medication adjustments, and lifestyle changes such as quitting smoking.

These measures help optimize the patient’s condition for surgery and reduce the risk of complications. Informed consent is a critical part of the preoperative process, where the surgeon explains the procedure, potential risks, benefits, and alternatives, ensuring the patient is well-informed and comfortable with the planned surgery.

Patients may also receive preoperative counseling to address any concerns and provide guidance on what to expect during and after the procedure. Proper preparation is crucial for a successful surgical outcome and smooth recovery, making preoperative considerations a vital aspect of robotic surgery in urology.

Surgical Team and Training

The success of robotic surgery in urology relies heavily on the expertise and training of the surgical team. Surgeons must undergo specialized training to master the use of robotic systems, which includes understanding the technology, developing proficiency in robotic techniques, and gaining experience through hands-on practice.

This training is typically conducted in simulation labs and through proctored surgical procedures, where experienced robotic surgeons mentor new users. In addition to the surgeon, the surgical team includes anesthesiologists, nurses, and surgical technicians who must be familiar with the robotic system and its requirements.

Effective communication and coordination among team members are essential for the smooth execution of robotic surgeries. Continuous education and training are important to keep the team updated on the latest advancements and techniques in robotic surgery.

Institutions often provide ongoing training programs and workshops to ensure the surgical team maintains their skills and knowledge. The investment in comprehensive training and teamwork ensures that patients receive the highest standard of care, contributing to the overall success and safety of robotic urological procedures.

The Surgical Procedure in Robotic Urology

The surgical procedure in robotic urology involves several key steps, starting with patient preparation and positioning. Once the patient is under anesthesia, small incisions are made to insert the robotic instruments and camera.

The surgeon operates from a console, controlling the robotic arms and viewing the surgical field in high-definition 3D. The procedure’s specifics vary depending on the type of surgery being performed, such as prostatectomy, cystectomy, or nephrectomy. Throughout the surgery, the robotic system’s precision and stability allow for meticulous dissection and suturing.

The surgeon’s movements are translated into real-time actions by the robotic arms, ensuring accuracy and reducing the risk of errors. The procedure duration can vary but is often shorter than traditional open surgeries due to the efficiency and control provided by the robotic system.

After completing the surgery, the instruments are carefully removed, and the incisions are closed with minimal sutures. The patient is then monitored in the recovery room to ensure stable vital signs and smooth emergence from anesthesia. The detailed and controlled nature of the robotic surgical procedure enhances patient safety and contributes to better postoperative outcomes.

Postoperative Care in Robotic Urological Surgery

Postoperative care is a critical component of the recovery process following robotic urological surgery. Immediately after the procedure, patients are monitored in a recovery room to ensure stable vital signs and manage any initial pain or discomfort.

The minimally invasive nature of robotic surgery typically results in less postoperative pain and quicker recovery compared to traditional open surgeries. Patients are often encouraged to mobilize early to reduce the risk of complications such as deep vein thrombosis and to promote faster healing.

Pain management is an important aspect of postoperative care, and patients may receive medications to control discomfort. Follow-up appointments are scheduled to monitor the patient’s recovery, assess surgical outcomes, and address any concerns.

During these visits, the surgeon may review the patient’s progress, remove sutures, and discuss any necessary lifestyle modifications. Patients are advised to gradually resume their normal activities, with specific guidelines provided based on the type of surgery performed.

Proper postoperative care ensures that patients recover smoothly and achieve the best possible outcomes from their robotic surgery, highlighting the importance of comprehensive care before, during, and after the procedure.

Technical Challenges in Robotic Surgery

While robotic surgery offers numerous advantages, it also presents certain technical challenges that need to be addressed. One of the primary challenges is the steep learning curve associated with mastering the robotic system.

Surgeons require extensive training and experience to become proficient in robotic techniques. Additionally, the cost of robotic systems and the maintenance required can be significant, posing financial challenges for healthcare facilities.

Technical failures, although rare, can occur, necessitating robust backup plans and skilled support staff to manage any issues that arise during surgery. Another challenge is the limited tactile feedback provided by robotic systems, which can make it difficult for surgeons to gauge tissue resistance and texture.

This lack of haptic feedback requires surgeons to rely heavily on visual cues, which may not always provide a complete picture. Ensuring the seamless integration of advanced imaging and navigation technologies with robotic systems is also essential for optimal performance.

Addressing these technical challenges involves ongoing research and development, continuous training for surgical teams, and investments in infrastructure and technology. By overcoming these hurdles, the full potential of robotic surgery in urology can be realized, leading to improved patient outcomes and broader adoption of this innovative approach.

Robotic Surgery in Urology

Emerging Technologies

The future of robotic surgery in urology is promising, with emerging technologies poised to enhance its capabilities and outcomes. Advances in artificial intelligence (AI) and machine learning are set to revolutionize surgical planning and execution.

AI can assist in preoperative planning by analyzing patient data and predicting surgical outcomes, helping surgeons make more informed decisions. During surgery, AI algorithms can provide real-time feedback and guidance, improving precision and reducing the risk of errors.

Developments in imaging technologies, such as augmented reality (AR) and virtual reality (VR), are enhancing the surgeon’s visualization of the surgical field. These technologies can overlay critical information onto the surgeon’s view, providing enhanced guidance and improving accuracy.

 Additionally, improvements in haptic feedback are being explored to give surgeons a better sense of touch during robotic procedures. Miniaturization of robotic instruments and the development of flexible robotics are expanding the range of procedures that can be performed robotically.

These advancements are expected to make robotic surgery more versatile, accessible, and effective, ultimately leading to better patient outcomes and wider adoption in the field of urology.

Expanding Applications of Robotic Technology in Urology

As robotic technology continues to advance, its applications in urology are expanding beyond traditional procedures. New techniques and procedures are being developed to address a broader range of urological conditions using robotic systems.

For instance, robotic surgery is increasingly being used for complex reconstructive surgeries, such as ureteral reconstruction and bladder augmentation. These procedures benefit from the precision and minimally invasive nature of robotic surgery, resulting in better outcomes and faster recovery times for patients.

Robotic-assisted kidney transplantation is another emerging application, offering a less invasive option with improved graft survival rates. In pediatric urology, robotic systems are being used to perform delicate surgeries on children, minimizing trauma and enhancing recovery.

The integration of robotic surgery with other emerging technologies, such as genomic medicine and personalized treatment plans, is also being explored. This integration aims to tailor surgical approaches to individual patients based on their genetic profiles, improving the effectiveness and safety of procedures.

As research and innovation continue, the scope of robotic surgery in urology is set to broaden, providing new and improved treatment options for a wider range of urological conditions.

FAQs About Robotic Surgery in Urology

Robotic surgery in urology involves the use of robotic systems to perform minimally invasive surgeries on the urinary tract and male reproductive organs, offering enhanced precision and control.

Robotic surgery uses small incisions and robotic arms controlled by the surgeon, whereas traditional surgery often involves larger incisions and manual operation, resulting in more trauma and longer recovery times.

Benefits include smaller incisions, less blood loss, reduced pain, shorter hospital stays, quicker recovery, and improved surgical precision, leading to better outcomes.

While robotic surgery is generally safe, risks can include infection, bleeding, and technical issues with the robotic system. However, these risks are similar to those of traditional surgery.

Patients should follow preoperative instructions from their surgeon, which may include fasting, adjusting medications, and undergoing necessary diagnostic tests to ensure they are fit for surgery.

Recovery is typically faster than with traditional surgery, with less pain and quicker return to normal activities. Follow-up care is important to monitor healing and address any concerns.

Surgeons undergo specialized training that includes simulation practice, proctored surgeries, and continuous education to master robotic techniques and ensure proficiency.

The future includes advancements in AI, imaging technologies, and expanded applications, making robotic surgery more precise, accessible, and effective for a wider range of urological conditions.

Surgeons trained in robotic urology can be found in major hospitals and medical centers. Patients can seek referrals from their primary care physicians or search online for specialists in their area.

Conclusion

Robotic surgery in urology represents a significant advancement in medical technology, offering numerous benefits over traditional surgical methods. Its precision, minimally invasive nature, and improved outcomes make it an increasingly preferred option for treating various urological conditions.

As technology continues to evolve, the scope of robotic surgery is expanding, providing new possibilities for patient care. Despite some challenges, ongoing research, training, and innovation are paving the way for broader adoption and accessibility of robotic surgery.

By understanding the advantages, applications, and future potential of this technology, patients and healthcare providers can make informed decisions about its use in urological treatments.

The future of urology looks promising with the continued integration of robotic systems, ultimately improving patient outcomes and advancing the field of medicine.

PARTIAL PENECTOMY
  • Partial penectomy is done in cases where glans and distal penis is involved with carcinoma. 
  • Partial penectomy is a type of organ-preserving surgery. Preservation of sexual and micturational function depends on the surgical dissection and reconstruction of residual urethra.
Kidney Stone Removal
  • Patients who develop stones in the kidney or ureter, often experience severe pain.
  • This condition usually needs a procedure to remove the kidney stones.
  • This procedure is called ureteroscopy and is performed very commonly.
  • It does not require any cuts and hence it is painless.
  • The procedure is performed with an endoscope inserted through the penis under spinal anesthesia.
  • The scope is inserted through the penis into the kidney and stones are dissolved with a laser.
  • The procedure takes about 40-50 minutes. 
  • A catheter (urine pipe) is kept after the procedure to drain the bladder. A stent is kept in the kidney at the same time.
  • Patient is mobile and walking in the room the same evening.
  • Hospital stay is one night and patient is discharged the next day after removal of the catheter.
  • Patient has to come back after six weeks to remove the stent in the kidney.
  • Patients can resume office a week after surgery and heavy activities like running, weight lifting, a month after the procedure.
  • We offer fixed packages for this procedure which can be obtained by calling our helpline +91 9967666060.
  • Men with an enlarged prostate, which is a normal ageing changes, often experiencing difficulty passing urine. This condition usually needs a procedure to trim the prostate and relieve the blockage.
  • This procedure is called TURP and is performed very commonly.
  • It does not require any cuts and hence it is painless.
  • The procedure is performed with an endoscope inserted through the penis under spinal anaesthesia.
  • The overgrown prostate is dissolved with a laser bloodlessly.
  • The procedure takes about 40 minutes.
  • A catheter (urine pipe) is kept after the procedure to drain the bladder.
  • Patient is mobile and walking in the room the same evening.
  • Hospital stay is two nights and patient is discharged with the catheter, which is removed after 4 days.
  • Patients can resume office a week after surgery and heavy activities like running, weight lifting, a month after the procedure.
  • We offer fixed packages for this procedure which can be obtained by calling our helpline +91 9967666060.
ROBOTIC ADRENALECTOMY FOR ADRENAL GLAND TUMOUR
  • Robotic adrenalectomy is a sophisticated, complex surgery and it is very important that an experienced surgeon performs this surgery to avoid major complications.

  • Once the anesthesia is done, and patient positioned, three micro cuts (3mm each) are made in the patient’s abdomen.

  • The arms of the Da Vinci robot are connected to the cuts via ports (tubes).

  • Dr. Ramani then sits in the controlling console to perform the surgery.

  • On an average, a robotic adrenalectomy takes one hour.

  • The surgery is almost completely bloodless and there has never been any need to transfuse blood after surgery.

  • A urine catheter and bag to drain the bladder is inserted during surgery.

  • A tiny drain pipe may be inserted in the surgical side of the abdomen, connected to a bag.

  • Patient is kept nil-by-mouth the day of the surgery, with IV fluids. Sips of water are started the next day and solid food by day three.

  • The drain pipe, if kept, is removed in the room on day 2 after surgery.

  • The catheter is removed on day two after surgery.

  • Total hospital stay for robotic adrenalectomy is 4 nights (including night before surgery).

  • Post discharge, a doctor from the surgical team visits the patient at home/ hotel room once every day.

RETURN TO ACTIVITY
  • On the day of discharge, patient is totally self-sufficient. They are able to walk freely without any pain, dress themselves, shower, toilet and they do not need to hire any nurse or help at home. Almost all patients are back to work within 2 weeks of surgery.

  • Heavy activities like running, weight lifting can be resumed after a month

FOLLOW UP AFTER SURGERY
  • Follow up after an adrenalectomy is in the form of CT scans, once a year for 5 years.
    Local patients usually meet Dr. Ramani after two weeks to discuss report.

  • Outstation patients are counselled on a phone consultation.

ROBOTIC SURGERY FOR BLADDER CANCER
  • Dr. Ramani is one of the very few surgeons in India who has the expertise to perform a robotic surgery for bladder cancer, which includes removing the urinary bladder and reconstructing a new bladder robotically.
  • Robotic radical cystectomy is an extremely sophisticated, complex surgery and it is very important that an experienced surgeon performs this surgery to avoid major complications.
  • Once the anaesthesia is done, and patient positioned, six micro cuts (3mm each) are made in the patient’s abdomen.
  • The arms of the Da Vinci robot are connected to the cuts via ports (tubes).
  • Dr. Ramani then sits in the controlling console to perform the surgery.
  • On an average, a robotic radical cystectomy with an ileal conduit takes 3-4 hours.
  • The surgery is almost completely bloodless and there has never been any need to transfuse blood after surgery.
  • A urine catheter and bag to drain the new bladder is inserted during surgery.
  • Two tiny drain pipe in inserted in the surgical side of the abdomen, connected to a bag.
  • Patient is kept nil-by-mouth for 4 days after surgery with IV supplementation of patient’s daily requirements of calories, fats, carbohydrates, proteins and electrolytes.
  • The drain pipes are removed in the room on day 3-5 after surgery.
  • Total hospital stay for radical cystectomy is 8 nights (including night before surgery).
  • Post discharge, a doctor from the surgical team visits the patient at home/ hotel room once every day.
RETURN TO ACTIVITY
  • On the day of discharge, patient is totally self-sufficient. They are able to walk freely without any pain, dress themselves, shower, toilet and they do not need to hire any nurse or help at home.
  • Almost all patients are back to work within 6 weeks of surgery. Heavy activities like running, weight lifting can be resumed after two months.
FOLLOW UP AFTER SURGERY
  • Follow up after a radical a cystectomy is in the form of CT scans, once a year for 5 years.

  • Histopathology report: Local patients usually meet Dr. Ramani after two weeks to discuss report.

  • Outstation patients are counselled on a phone consult. Depending on the report, patient may or may not need chemotherapy after surgery.

  • If chemo is needed, patients may choose to get it done with a medical oncologist of their choice or avail the services of one of the four medical oncologists on our team.

ROBOTIC RADICAL/PARTIAL NEPHRECTOMY FOR KIDNEY CANCER
  • Robotic partial nephrectomy is a sophisticated, complex surgery and it is very important that an experienced surgeon performs this surgery to avoid major complications. Robotic radical (total) nephrectomy is
  • relatively easier but still requires significant experience to consistently deliver results.
  • Once the anaesthesia is done, and patient positioned, five micro cuts (3mm each) are made in the patient’s abdomen.
  • The arms of the Da Vinci robot are connected to the cuts via ports (tubes).
  • Dr. Ramani then sits in the controlling console to perform the surgery.
  • On an average, a robotic radical nephrectomy takes one hour and a robotic partial nephrectomy takes about an hour and half.
  • The surgery is almost completely bloodless and there has never been any need to transfuse blood after surgery.
  • A urine catheter and bag to drain the bladder is inserted during surgery.
  • A tiny drain pipe in inserted in the surgical side of the abdomen, connected to a bag.
  • Patient is kept nil-by-mouth the day of the surgery, with IV fluids. Sips of water are started the next day and solid food by day three.
  • The drain pipe is removed in the room on day 3 after surgery. The catheter is removed on day two after surgery.
  • Total hospital stay for radical/partial nephrectomy is 4 nights (including night before surgery).
  • Post discharge, a doctor from the surgical team visits the patient at home/ hotel room once every day.
RETURN TO ACTIVITY
  • On the day of discharge, patient is totally self- sufficient. 
  • They are able to walk freely without any pain, dress themselves, shower, toilet and they do not need to hire any nurse or help at home. 
  • Almost all patients are back to work within 2-3 weeks of surgery.
  • Heavy activities like running, weight lifting can be resumed after a month.
FOLLOW UP AFTER SURGERY
  • Follow up after a radical/partial Nephrectomy is in the form of CT scans, once a year for 5 years.
  • Local patients usually meet Dr. Ramani after two weeks to discuss report. 
  • Outstation patients are counselled on a phone consultation.