Apparatus, system and method for providing laser steering and focusing for incision, excision and ablation of tissue in minimally-invasive surgery

Abstract

Provided and described herein are exemplary embodiments of apparatus, system, computer-accessible medium, procedure and method according to the present disclosure which can be used for providing laser steering and focusing for, e.g., incision, excision and / or ablation of tissue in minimally-invasive surgery. For example, an exemplary apparatus is provided that can include at least one optical element which can be configured to refract and / or diffract light provided in a structure which can be configured to be inserted into a body, where at least one of the optical element(s) is structured to receive the light at a first angle and generate a refracted and / or diffracted light at a second angle which can be different from the first angle relative to an optical axis. According to a particular exemplary embodiment of the present disclosure, it is possible to control a light propagating arrangement to (i) provide the at least one light toward the optical element(s) at the first angle, and (ii) change a position thereof within the structure(s) to change the first angle.

Description

CROSS REFERENCE TO RELATED APPLICATION(S)[0001]The present application is based on and claims priority from U.S. Patent application Ser. No. 61 / 610,819, filed on Mar. 14, 2012, the entire disclosure of which is incorporated herein by reference.FIELD OF THE DISCLOSURE[0002]The present disclosure relates generally to apparatus, system and method for providing laser facilitating incision, excision and / or ablation of tissue in minimally-invasive surgery.BACKGROUND INFORMATION[0003]Minimally invasive surgical techniques can offer the potential for reliable cancer control with minimal impact on post treatment function of the diseased organ. There have been certain advances in providing instrumentation for minimally invasive surgery of many diseases. Although the use of CO2 lasers has become well established and can be considered to be as effective and precise scalpel, it is likely still largely limited to operations where the surgeon has unobstructed access to the tissue. (See, e.g., Pola...

AI Technical Summary

Benefits of technology

The present patent application is about a system for providing laser facilitating minimally-invasive surgery using a CO2 laser. The technical effects of the patent include the ability to use the CO2 laser in a wider range of surgical procedures and to improve the precision and accuracy of the laser's manipulation in body cavities. The patent also addresses the limitations of current delivery methods, such as line-of-sight and fiber optics, which can restrict the use of the CO2 laser in certain procedures.

Problems solved by technology

Although the use of CO2 lasers has become well established and can be considered to be as effective and precise scalpel, it is likely still largely limited to operations where the surgeon has unobstructed access to the tissue.

However, an exemplary disadvantage of the CO2 laser can be related to its beam's likely inability to travel in any medium other than air.

Since the CO2 laser beam is likely unable to be transmitted along glass or conventional optical fibers, its use has probably been generally restricted to “line-of-sight” applications, in which it can be passed down a hollow, air-filled, straight rigid instrument or endoscope.

Thus, endoscopic applications of this technique and the CO2 laser has likely been restricted to treatment of tumors of the mouth, pharynx, larynx and cervix, for example.

Further, a delivery of any type of surgical laser light into a body cavity by means fiber optics has likely been limited to use in the near field, e.g., by bringing the distal tip of the fiberoptic close to the tissue in order to keep the power density high.

It can be very difficult to facilitate a flexible, variable and accurate maneuvering of such laser beam.

Instrumentation for endoscopic applications of the CO2 lasers and other surgical lasers has undergone refinement and improvement, but access to the larynx and pharynx in certain patients with adverse anatomic features has likely continued to pose a problem.

This limitation of the conventional technology can be largely responsible for the potential benefits of certain surgery being denied to a large number of patients, such as patients whose tumors can be relatively difficult to access for surgical resection with endoscopic CO2 laser instrumentation, for example.

However, the use of such non-surgical “organ preserving” approaches can likely often cause permanent and significant side effects that can drastically alter the lives of patients who survive after treatment.

As described, the fiber can transmit the light from the laser source to its distal end that can be used as a “laser scalpel.” However, the use of the fiber delivery techniques are likely not ideal as they can have some of the limitations of line-of-sight technologies.

Additionally, fiber delivery techniques can introduce certain other problems.

If the fiber is placed too far away (e.g., over one millimeter), the power density can likely drop, and the laser scalpel can become ineffective.

However, if the fiber tip touches the tissue, it can burn and / or become obstructed.

Further, a precise manipulation of the working end of the fiber inside a body cavity can be challenging for the endoscopic surgeon due to the difficulty of maintaining a consistent depth of incision with the laser directed through a hand held fiber moving over an uneven tissue surface in a confined closed space.

Moreover, a complex electro-mechanical system should likely need to be provided for the laser beam to be controlled remotely.

However, the technical requirements of imaging scanners and surgical laser scanners are generally not the same, but rather can be very different.

These systems have certain limitations and associated problems such as spatial and temporal inaccuracies associated with the remote transmission of positioning forces from the external motors to the internal optics.

However, this device requires a tunable laser, and thus would likely not be able to work with surgical lasers like a CO2 laser, for example.

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