WO2016183653A1

WO2016183653A1 - Apparatus and method for monitoring surgical textile absorbers, surgical instruments and accessories, with chip tags and monitoring and radiofrequency identification operating at uhf (ultra-high frequency)

Info

Publication number: WO2016183653A1
Application number: PCT/BR2016/050102
Authority: WO
Inventors: Henrique PERETO
Original assignee: Pereto Henrique
Priority date: 2015-05-19
Filing date: 2016-05-09
Publication date: 2016-11-24

Abstract

The invention relates to an apparatus and method for monitoring surgical textile absorbers, surgical instruments and accessories, with chip tag and monitoring and radio frequency identification operating at UHF (ultra-high frequency), and comprises the apparatus, software and method for identifying and continuously directly counting objects inside and outside a surgical field, and for monitoring objects on the instrument table and indirectly in the site of the surgery. In an embodiment, the apparatus has a device for inputting data in two steps, a table for surgical instruments to which the data input device is attached, a hand-held data input device and a scanning output device for generating a detection field and receiving the data that identify said objects. In another embodiment, the apparatus has a plurality of upper and lower antennas to generate a detection field and to receive data identifying said objects. Various surgical and packaging methods were designed to prevent electromagnetic coupling, including the protection of objects and identifiers. The invention provides an apparatus and a method comprising a scanner, laparoscopic surgery probes and techniques for fastening tags to textiles to ensure the safety of a patient during a surgical intervention.

Description

"SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES WITH CHIP LABELING AND MONITORING, OPERATING IN UHF (ULTRA HIGH FREQUENCY)

The present invention relates to an equipment, software and method for monitoring objects in a surgical field, more specifically for controlling the entry and exit of objects in a surgical field, as well as monitoring objects on the instrument table and indirectly. at the surgical site and to determine if these objects are inside the patient.

It is of vital importance that the entry of objects into a surgical field and within a surgical site, as well as their removal, be carefully aligned to prevent inadvertent retention of an object within a patient. Object counting in and out of a surgical field is a conventional procedure in operating theaters. Such practices severely reduce the risk of inadvertently trapping an object inside the patient. Such processes typically involve manual counting of objects in and out of the surgical field, as well as visual examination of them. It is essential that such procedures are completed before the surgical field is closed. In the event that the surgical field should be closed with a minimum delay, it is necessary to complete the verification that there is no object retained in the patient as soon as possible. Accordingly, it is desirable to provide means and methods for monitoring effective and attempted entry, exit and location of objects in the surgical field with a high degree of accuracy and with minimal effort on the part of medical personnel.

Moreover, according to Egorova, the positive predictive value of manual object counting in detecting unintentional object retention in the surgical field is only 1.6%. Also in 84% of unintentional retention cases, manual counting was correct and This fact makes the manual counting method a very limited way to avoid these events.

Devices and methods are provided for monitored objects to have identifiers in a surgical field. These objects may include surgical aids such as surgical sponges, surgical instruments such as scalpels and needles, medical supplies, and other tools used by medical staff in a surgical field, such as writing instruments. Additional examples include items in the surgical field that may or may not be used in a surgical procedure. Other objects may include, for example, personal items worn by clinical or surgical patients, such as watches, glasses, dentures, hearing aids, caps, surgical gloves and ID cards. An identifier of an object to be monitored may be a radio frequency (RF) tag or an integrated circuit technology that utilizes any other suitable object identification device. Alternatively, an object may be equipped to emit spontaneous electromagnetic waves containing identifying information that can be read by antennas. A barcode can also be linked to an object in order to identify it. An object can also be identified using pattern recognition technology, where a graphic image of the object is obtained and control circuit algorithms are used to identify the object from the image. Any other suitable identifier or combination of identifiers may also be used.

The apparatus may include an object input detection zone, a surgical field monitoring zone and an object detection output zone. The object entry detection zone can be adapted to receive new objects from a shelf or cabinet prior to introduction into a surgical field, the surgical field monitoring zone can be adapted to directly monitor the instrumental table and directly or indirectly to monitor the instrument. surgical site at the same time the detection zone output can be adapted to receive the unloaded objects for this after leaving the aforementioned surgical field.

One or more scanning devices may be operatively associated with the detection object input zone, the control zone and the object output detection zone, respectively. Said scanning device may contain one or more antennas that can detect a single object or simultaneously a plurality of objects, for example by issuing a detection field directed to the detection zone. Antennas can also detect objects after direct entry into the surgical field, for example by emitting detection fields below the instrumentation table. A control circuit may be operatively associated with the verification devices to control their operation.

Several approaches to controlling antenna signals are provided. In one embodiment, all antennas are sequentially powered and controlled for a certain period of operation by the control circuit 21 turning the antennas on and off such that when one antenna is powered, the others are de-energized. In another embodiment, control is effected by switching power and antenna adjustment.

In another embodiment, the invention further provides a plurality of antennas preferably disposed within a probe for detecting field-emitting and sensing objects within the patient or otherwise at or around the surgical site. In another embodiment, an antenna or group of antennas are positioned above or below the operating table to detect objects within the patient.

Another improvement of this embodiment involves an upper antenna, which may be a portable device to aid direct field detection. In one embodiment, the upper antenna may scan the open cavity in and around the surgical field. 001 1 Several approaches to protect data deterioration are provided. The use of the latest generation of CHIPS 300 shown in FIG. 20A for mounting an RFID tag shown in FIGS. 20A and 20B grants 10 years of data retention. In certain embodiments, the CHIPS 300 may be antenna sealed within biocompatible plastic, such as PET (ethylene terephthalate) shown in FIG. 20A1 and FIG. 20A6 or directly attached to the radiant marker as seen in FIG. 17 or directly attached to the textile loop yarn shown in FIGs. 18 and FIG. 19, covered by a protective layer of biocompatible plastic.

Various approaches to preventing electromagnetic coupling between identifiers are also provided. In one embodiment, the tags are covered with a layer of gauze to increase the distance between tags, best seen in FIG. 14A and FIG. 14B. They can also be placed at strategic locations on objects that increase the distances between identifiers. The objects may be packaged in an alternative arrangement so that the mark of an object is placed in the opposite position of the objects above and below it, which gives a greater distance between the marks in that order, shown in FIG. 19. In another embodiment, the objects may be packaged or encapsulated in protective wrapper 100 best seen in FIG. 2.

For a better understanding of the invention it is proposed to be described below with reference to the accompanying drawings in which:

0014 FIG. 1 is a schematic illustration of a system as a constructive option of the present invention;

FIG. 2 shows an example of a protection set containing a group of objects in a constructive option of the invention;

FIGS. 3 and 4 are perspective views taken from opposite sides of a cabinet 20 containing substructure 32 with electronics installed, monitors 30 and 31 and antenna ANT 5 (not shown) constructed under activation zone 9; FIG. 5 and 6 are perspective views taken from opposite sides of a basket containing antenna ANT 7 detecting output detection zone 11;

0018 FIG. 7 shows a perspective view of cabinet 20 showing the activation zone in a constructive option of the invention;

FIG. 8 shows the 4 drawers of the invention, the upper one being the so-called EMERGENCY DRAWER, the second and third are monitors of objects received therein, such as textiles, and the fourth is a container for system accessories such as cables and antennas;

FIG. 9 shows the lower drawer partition 20D4 in lower storage drawer and upper substructure 32;

0021 FIG. 10 shows the arrangement of electronics within the substructure 32 shown in FIG. 9, with the specific arrangement of the main components to avoid electromagnetic interference;

0022 FIG. 11 shows a schematic elevation and plan illustration of the instrument table with the system monitoring detection zone 10 conferred by the pair of antennas 6 below it. The table top is made of materials that are permeable to radio frequency;

0023 FIG. 12 shows another embodiment of the arrangement of the electronics within the substructure 32 shown in FIG. 9, in order to avoid electrical interference;

0024 FIG. 13 shows a schematic elevation and plan illustration of the instrument table with a pair of ANT antennas 6 and control circuit 21 under it compatible with the embodiment shown in FIG 12;

FIG. 14 shows a surgical gauze unfolded with an RF tag attached and covered by a gauze pad. The gauze is made using a crochet technique that prevents shredding and allows the label to be sewn inside it.

0026 FIG. 14 B shows the gauze shown in FIG 14 A, folded into four layers; FIG. 14C shows a laparoscopic gauze consisting of a flat gauze with the RFID tag inside wrapped and stitched at the ends with a long thread to allow retrieval thereof from the cavity in one embodiment of the invention;

0028 FIG. 15 shows a detail of a surgical bandage with an RFID tag attached within a gauze pad in one embodiment of the invention;

FIG. 16 shows a detail of a surgical bandage with an RFID tag attached without a gauze pad in one embodiment of the invention;

FIG. 17 shows a detail of a surgical dressing with an RFID tag attached to the radiant marker in the embodiment of the invention;

FIG. 18 shows a detail of a surgical dressing with an RFID tag attached to the dressing wire in another embodiment of the invention;

0032 FIG. 19 shows details of the arrangement of the bandage or surgical gauze within the package to prevent electromagnetic coupling in an embodiment of the invention;

0033 FIG. 20 and details show two different concepts of RFID tags with their composition shown in figure 20A. Layers 1-6 are polyethylene, CHIP, aluminum antenna, anisotropic conductive adhesive, ethylene vinyl acetate and polyethylene;

0034 FIG. 21 shows a side view and FIG. 21B is an oblique view of portable antenna ANT 8 with the field represented by darkened circles in a schematic illustration of the cavity probe in one embodiment of the invention;

FIG. 21 C shows three views of the near field portable antenna ANT8, in a schematic illustration of the off-wall probe in one embodiment of the invention;

FIG. 22 shows the system logo;

FIG. 23-1 through 18 show the operation chart, system logic and method of one embodiment of the invention; 0038 FIG. 24 is a representative diagram of the 96 bits of information contained in the tag chip. The first 14 digits represent the header, filter and partition. The next 26 digits represent SurgiSafe's GTIN-13 code, followed by 20 digits for the GTIN-13 product code. The last 38 digits are the serial area where a mathematical algorithm certifies the chip, avoiding uncertified textiles, for secure label attachment;

For a better understanding, some terms will be further explained below for a good understanding of the proposed invention.

As used herein, the term "patient" means a member of the animal kingdom, including humans.

As used herein, "surgical site" means the portion of the patient's body at which surgery was or will be performed and the adjacent portions, including support table or bed.

As used herein, "surgical field" means the sterile environment that includes the patient, equipment and personnel that is or may be used during a surgical procedure.

As used herein, the term "non-optical" refers to a method or system that does not require line of sight using visible light.

As used herein, the term "object within a surgical field" or "object" refers to objects found in a sterile environment, which includes the patient, equipment and personnel, which will or may be used during a procedure. surgical.

With reference to FIG. 1, a plurality of objects 1, 2, 3 and 4 are shown, each equipped with an RFID tag (not shown) which each object can be distinguished from other group members. Objects 1, 2, 3 and 4 may be contained in individual packages. If objects 1, 2, 3 and 4 have packages, identifiers can be placed directly over each object only. The outer packaging label of the object may contain the barcode and manufacturer and content information. For example, FIG. 2 shows package 100, which may contain only a specific number of previously known objects. THE Each unit identifier includes a numeric identifier in the EPC serial area of the chip that is marked with an encryption algorithm and a 12-digit barcode on the GTIN segment of the chip according to GTIN-13 standards, which can identify and count objects within the surgical field. The serial number is unique for each unit, giving the object a unique and individual identity t for software running on circuit 22. In addition, additional information may be provided within the chip, such as the specific object type (GTIN- 13), the manufacturer, the factory in which it was produced, the total number of objects in a package and any other desired information.

The user may be able to differentiate between packets belonging to different objects by the label and code GTIN-13 on the chip CPE within each content unit within each packet. Depending on the type of object, the number of objects within each package defaults, and each package is checked for contents during activation.

0047 The system is configured to read all packet quantity identifiers to determine the packet identity and the number of objects that should be in the packet. The system counts the number of objects activated by detecting the unique identifier of each object in the package. The system can compare the number of objects that must be in the package with the number of objects in the package to verify that the package is complete before using it in a surgical field. If the system detects that a package is incomplete, the user may be warned that the package may be incomplete, or that the identifiers of one or more objects in the package may not be working correctly.

A control circuit 22 can be programmed with the expected amount inside the package of a GTIN-13 unique identification number to determine if the amount inside the package is what is expected. It can also be programmed to identify GTIN-13 items within the surgical field not yet activated. THE The software can use this to monitor all other items in the list of detected items in monitoring detection zone 10. Although the software does not include unique identifiers for these unread items, it creates a secondary counting algorithm for them. This data is entered into three different mathematical algorithms. This provides a user who has forgotten to scan a package for a more accurate representation of surgical inventory than could be obtained to date. Using the algorithms as well as the amount of data, the software can avoid confusion in case another partial packet is discarded before being scanned. It also creates redundancy to check the number of objects within the surgical field.

Identifiers for an object can also be programmed with information about the object's treatment history, such as sterilization. For example, when an object is sterilized, the label may be programmed with information such as the sterilization date, the specific process used for sterilization, the sterilization expiration date of the object and any other desirable information. When an object is received in object entry detection zone 9, the system can check the sterilization expiration date. The user can be warned if sterilization of the object has expired. In addition, the system may decode encoded information stored on the tag, which identifies the sterilization process used, in particular the article, and may issue a warning or take other appropriate action if the object has not been sterilized using a validated process.

Objects 1, 2, 3 and 4 can be activated in the object scan detection zone 9 and sequentially validated by the antennas within the instrument table zone 10. A single ANT5 antenna can be operatively associated with the activation detection zone. 9 to detect and read data from tags. Antenna ANT 05 may provide a field from the cabinet table 20, and thus may facilitate the determination of the identity of each input object in the input detection zone 9. Data received by the ANT5 antenna can be read and decoded by circuit 21 and then delivered to control circuit 22, which can record data for each input object in input detection zone 9. Control circuit 21 can also function as a controller to supply power to all ANT antennas 5, 6, 7 and 8 and to control their operation with respect to various parameters and in the correct sequence to allow substantially simultaneous identification of a plurality of objects. The display unit 30 may be controlled by a control circuit 22, and may provide a visual display of any information that is required for each object 1, 2, 3 and 4, being input to the input detection zone 9. An object 2 with larger dimensions is activated directly on the instrument table in detection zone 10. The contents inside the emergency drawer are previously activated and can be used before turning on the system in case of an emergency.

Objects in detection zone 10 are continuously monitored with real-time inventory providing circuit 22 with continuous data about objects within it through circuit 21.

While the system may employ a single antenna for detection zone 9, objects in detection zone 10 are monitored by two or more antennas, identified in figure 1 as ANT 6 and are represented in figures 11 and 13 in two configurations. many different.

All antennas are circular in orientation, allowing detection in any orientation with respect to the antenna. All antennas, but ANT8, are structured to generate an upward directed detection field. The ANT8 is normally turned off and is enabled to scan the patient and surroundings when needed.

In operation, objects 1, 2, 3 and 4 can be delivered by hand from placement in the drawers. A two step activation process is required. Objects 1, 2, 3 and 4 must be activated in detection zone 9 and validated in sequence in detection zone 10. Detection zone 0 without prior activation in zone 9 generates a warning for circuit 22 in 30 and 31 monitors. Manual activation is offered by circuit 22 and must be confirmed on the monitor touch screen 30.

Objects that are used in the surgical field may be introduced into the exit detection zone 11 after use. This zone monitors the output of objects 1, 2, 3 and 4. A single antenna ANT7 is placed within the basket 30 at a specific angle, providing readability throughout the basket, shown in FIG. 5 and 6. The system may alternatively be used with multiple antennas to detect input zone 9 or output zone.

This can be done in a manner to be described below for a plurality of objects simultaneously. The received data can be decoded by circuit 21 and can be supplied to control circuit 22 with different outputs being displayed on visual monitors 30 and 31. Visual Display 30 can be provided with controls that allow simultaneous viewing of input and output objects and balance, as well as other desired information and controls.

At this point, the control circuit may have a record of each specific object entering the field of surgery through detection zone 9, as well as objects on the monitored instrument table in detection zone 10 and unloaded monitored items. in the 1 1 zone.

Objects within the surgical site can be determined by simple mathematical algorithms performed by control circuit 22: Activated less zone 10 content less zone 11 content 1 will be equal to the surgical site content

In order to provide security, a second algorithm is simultaneously driven by circuit 22: less detected objects in zone 10 less detected objects in zone 11 will be equal to objects detected within range.

0060 If all objects detected by the antennas are within range, at the end of the procedure no objects detected are left inside. A third algorithm executed by circuit 22 determines that the sum of all activated objects must be a multiple of 5.

If any of the above algorithms suggest the retention of a foreign object, the patient can be scanned by antenna 8, connected to power circuit 21 and data exchange.

In one embodiment antenna 8 is a handheld probe within a hand wand identified in Figure 21 A (side view) and B (top view). It consists of two opposing fields generated by a single antenna that can be inserted into the open cavity covered with sterile plastic. It can slide along the cavity to determine if any mark can be detected. In another embodiment identified in Fig. 21D, antenna 8 is a simple device that can be positioned close to the body surface and can detect the label through the patient cavity wall. In another embodiment, two planar antennas are positioned at an angle 90 ^Q scan through the wall of the patient. In another embodiment, antenna 8 (Fig. 21 C) is a 9 mm diameter antenna. Its circular appearance and small diameter allow insertion through a 10 mm laparoscopic trocar, allowing inspection of the cavity during laparoscopic interventions.

Control circuit 21 can validate objects 1, 2, 3 and 4 by their serial number. An encryption algorithm can validate content coming into the surgical field. This algorithm filters out other RFID devices present in the operating room. It also checks the quality of the textiles and materials provided, preventing labels from being disconnected from their related objects. You can also control data received from the ANT7 antenna, avoiding continuous recounting of already downloaded tags.

Control circuit 22 may be controlled by software with its orientations and flow chart which are described in FIG. 23-1 through 18. Control circuit 22 can then store object identifier and unique serial number information and, until the end of surgery, Create a record of specific objects 1, 2, 3 and or 4 used during surgery and free. It can also report if the loss of any object occurred.

Control circuit 22 may also store other information about a variety of objects, herein identified as object 2, such as their size. In one embodiment, large objects may bypass activation in zone 9 and may be manually activated in activation zone 10.

0067 The function and integrity of identification data can be verified in input 9 and output detection zones 1 1. In one embodiment, when an object enters detection zone 9, a control circuit 22 may be used to compare data read from the object identifier to the preprogrammed data for a control circuit 22. If the number of object identifier units do not match the preprogrammed data in the control circuit 22, the user may be alerted. This can ensure that all identifiers are functional. This can, for example, prevent incorrect object counting or other errors.

Where multiple antennas, such as ANT6 antennas cooperate with respect to a particular detection zone 10, it may be preferred that they operate individually with the control circuit 21, controlling the sequence and manner of each antenna function. For example, control circuit 21 may be structured to adjust power, focus and disconnect antennas within a group such that during a period of operation of an antenna within a group, it is set to a resonant frequency. specific, remaining antennas in the group are disconnected. Power may be supplied differently for each of the ANT5, 6, 7, and 8 antennas for tuning purposes.

The antennas of each group (ANT6) can be connected in this way, so that each antenna is subjected to each parameter separately. Any suitable antenna orientation, or a combination of antenna orientation can be used additionally. Within ANT5, 6, 7 and 8, an RFID tag with its specific GTIN-13 identifier related to its function is established. Control circuit 22 will verify that the correct GTIN-13 identifier is being detected on the correct antenna. This solution avoids wrong connection of an antenna to the control circuit 21.

Referring to Figs. 3 and 4, they show two perspective views of a cabinet 20 which, in the form shown, may contain object detection zone 9, touch screen 30, 31 and substructure display 32. It also contains four drawers, better 8 and 9. Drawer 20D1 has a locking latch and is intended to contain the emergency source of surgical textiles. Drawers 20D2 and 20D3 are intended for storing surgical gauze at the top and surgical bandages at the bottom. The 20D4 drawer is divided into two levels. The lower level is intended for storing system accessories such as antennas and cables. The superior receives the substructure 32.

In one embodiment, substructure 32 maintains all electronics as described in Figure 10. The substructure is divided into sectors according to electrical characteristics, avoiding interference with each other. At the front of the subframe a window exposes the front of the control circuit 22 described in figure 9. At the rear, a power cable connector and a main switch are located on the left side, while four RF connectors are exposed on the right side, best seen in figure 3. In another embodiment the substructure 32 holds part of the electronics (figure 12), and the control circuit 21 is installed between the two instrument panel antennas as shown in figure 13. Alternatively, the upper three drawers and the locking latch can be electrically controlled by the control circuit 22.

As shown in FIG. 3 and 4, the device has two flat panel monitors which are attached to a hinged bracket, giving slight vertical and horizontal tilt. The monitor 30 is equipped with touch screen technology, allowing integration with the system without keyboards, a common reservoir of microorganisms. THE Monitor 31 is equipped with anti-reflective technology allowing better view to the surgical team.

FIGS. 5 and 6 show two perspective views of a basket 30 which, in the form shown, may contain the object detection zone 11. An ANT7 antenna is positioned on the inner side of the slightly sloping upward side wall. This antenna is connected to control circuit 21 as an RG58 cable (not shown).

With reference to FIG. 2, a plurality of objects are present in a single package, each object having an identifier. Prior to introducing objects into the surgical site, control circuit 21, which may be within substructure 32 (FIG. 10) or under instrument table 40 (FIG. 13) in a manner to be described below, energizes the antennas. It captures the chip response, decodes and sends this data to the control circuit 22, shown in figures 10 and 12. Circuit 22 can monitor the unique identification of each zone 9 object and store input detection data. This can make it easier to identify the specific object (ie its type and other characteristics) as well as the number of objects entering the surgical field. Cabinet 20 may also contain a first visual display for displaying data processed by circuit 22. With touch screen technology, data can be entered via monitor 30 as well. The visual display by the second monitor 31 can display data exclusively related to the surgical field and is linked to the surgical team vision. The substructure 32 may be attached to the upper part of the lower frame. The substructure is the platform on which the control circuit 21 and the circuit and control 22 are attached. The power connection is located in the right rear quadrant, the control circuit 22 in the right anterior quadrant, the control circuit 21 in the left anterior quadrant and the RF connections in the left posterior quadrant as shown in figure 10. In another form of In this embodiment the control circuit 21 is not located on the substructure 32, but between the ANT antennas 6 under detection zone 10. In its place is a POE (Power Overload) generator. Ethernet) is installed, as shown in FIG. 12. This distribution is intended to prevent electromagnetic interference from alternating current.

Monitors 30 and 31 may be, for example, LED displays or any other suitable displays.

In another embodiment, monitors 30 and 31 may be integrated into a single visual display and may be a separate device from cabinet 20. For example, the visual display may be a wall mounted monitor communicating with control circuit 30 through wired or wireless access. The visual display can be an LED, LCD or other suitable monitor.

All objects that are removed from the surgical site can be introduced through the upper opening of the basket 30 reaching the exit detection zone 11. Objects can be identified and counted. Object data can be displayed on displays 20 and 31 of cabinet 20. Objects identified in detection zone 1 1 can then be manually selected. Permanent-use items can be removed and disposable items can be collected in a wastebasket in basket 30. The wastebasket can be a plastic bag of suitable size and strength, and can be easily removed from the basket. 30 through the front door (Fig. 5) for operator safety.

Monitors 30 and 31 in Figs. 3 and 4, can visually display different data and quantities of objects within the field. You can also display the consistency of the data presented with a color-coded visual alert and audible alerts as well. For example, monitors 30 and 31 may display the contents shown in FIG. 23-1 to 23-18 according to the software flowchart specially developed for this use. Various other means of providing the desired information about the monitored objects in and out of the surgical field can be visually displayed on monitor screens 30 and 31, according to the desired information. Referring to Figs. 5, 7, 11 and 13, the object input detection zone 9, the instrument table detection zone 10 and an output zone 11 may be structured to monitor each of a plurality of objects which pass through them substantially simultaneously, regardless of object orientation. Antennas can be designed, positioned and used to allow simultaneous control. Also, as the scanner may be non-optical, the presence of blood, other body fluids or tissues on the object or the identifier will not interfere with accurate readings. Cabinet 20 as above may have wheels 25, 26, 27 and 28 at the corners as well as manually operated brakes 23 and 24, each associated with a wheel 27 and 28. In the illustrated form, a handle projection 22 is provided. for ease of movement of cabinet 20. This handle projection may optionally be used in conjunction with any embodiment of the invention. The cabinet body 20 may be made of any suitable materials that are structured to have sufficient strength to withstand the equipment in order to avoid interference with the operation of the equipment and to be able to maintain the required cleanliness in a surgical field. Suitable materials that can be used include resin, rust-treated ferrous plastics and non-ferrous metals and medium density fiber (MDF) wood, to name a few. To avoid radio frequency interference from other devices, metallic materials are preferred. Basket 30 as above may have wheels 35, 36, 37 and 38 at the corners as well as manually operated brakes 33 and 34, each associated with a wheel 37 and 38. In the illustrated form, a handle 32 is provided to facilitate basket circulation 30. This handle may optionally be used in conjunction with any embodiment of the invention. The basket body 30 may be made of any suitable materials that are structured to have sufficient strength to withstand the equipment in order to avoid interference with the operation of the equipment and to be able to maintain the required cleanliness in a room. surgical field. Suitable materials that may be used include resin, rust-treated ferrous plastics and non-ferrous metals and medium density fiber (MDF) wood, to name a few. To provide adequate detection at all levels of basket 30, the inner walls are made of metal so that radio frequency waves propagate within it.

Referring to circuit 21 shown in Figs. 10 and 13, which consists of a commercially available radio frequency reader with important system features described herein. It operates in UHF with a maximum reading capacity of 1200 tags per second. It also has circuit protection for the antennas, preventing channel burnout when switching antenna with the equipment turned on. It also operates in the frequency range defined by local law. The electrical behavior of the antennas is configured and controlled by software and hardware to emit the minimum amount of radio signal required for the system to function, preventing interference with other medical equipment. The ANT5, ANT6, and ANT8 antennas connected to circuit 21 are field proximity intensity detection antennas. The ANT7 antenna is a hybrid with an important field proximity component. This grants multi-level detection within basket 30 in detection zone 1 1. Proximity to field is characterized by its unique magnetic feature with a maximum range of 50 cm or 22 inches. Working preferably in close proximity decreases interference between other electronic devices commonly present in an operating room, as well as accidental detection of objects 1, 2, 3 or 4 located away from the surgical field, for example textiles in another room. of operation. The ANT5, ANT6, ANT7, and ANT8 antennas are dedicated to specific functions and therefore have different sizes and shapes. In essence, they are commercially available antennas that test and adapt to each of the specific functions in this system. An antenna can also be a combination of two or more commercially available antennas in order to to grant specific characteristics needed specifically in this system. Antennas ANT5, ANT6, ANT7 and ANT8 may be powered and controlled by a control circuit 21 of FIG. 10. ANT5, ANT6, ANT7 and ANT8, as shown, may be made of hard aluminum sheet and thus self-supporting. Other self-supporting or non-self-supporting materials provided with additional supports may also be used. Each ANT5, ANT6, ANT7, and ANT8 antenna can be a noncircular facing field that projects to zones 9, 10, 11, and 12 where objects 1, 2, 3, and 4 are scanned.

ANT5, ANT6, ANT7, and ANT8 antennas, when operating as a unit consisting of several antennas, may be arranged coplanar to one another and may form angles to one another. The ANT5, ANT6, ANT7 and ANT8 antennas can be controlled by a control circuit 22 via the control circuit of the 21.0 control circuit 22 can warn the user if the antennas do not detect the respective GTIN-13 chip code inside the control. antennas or detect the wrong GTIN-13 code. This ensures safer use of the device by granting that antenna connections are not crossed and the integrity of connections and cables.

The control circuit 22 as shown may be disposed within the cabinet 20 fixed to the substructure 32. The control circuit 22 may control and coordinate detection fields emitted by each successive antenna through circuit 21. As indicated above, the control circuit 22 may be structured to adjust and control any antennas such that during patient verification, an ANT8 antenna is only connected at that time, while in normal mode, ANT8 is off. This may prevent unintentional identification of other objects 1, 2, 3 or 4 outside the surgical field. Control circuit 21 receives data from a plurality of objects at substantially the same time (for example, in the order of up to 1200 objects per second), regardless of object orientation. Antenna detection field strength control determines the spatial position of object 1, 2, 3, or 4. Circuit 21 features automated intensity control to the limits determined by circuits 21 and 22. In this configuration, antennas ANT5, ANT6, and ANT7 are operating continuously, while ANT8 is switched on only when determined by control circuit 22. .

Referring to Figs. 5 and 6, with reference to the exit from the detection zone 11, the basket structure 30 is metallic, with a niche for positioning an antenna on a side wall. The antenna position is slightly tilted upwards. This configuration allows the radio frequency to reflect within the basket 30 which provides a multi-level detection zone, including the upper opening, where normally unloaded objects 1, 2, 3 or 4 are maintained by manual selection before final discharge. into the collection container (plastic bag) into basket 30. The multi-level detection provided by the ANT8 antenna and the metal basket work together to provide multi-level detection. The antenna attached to the side prevents liquid collected at the bottom from blocking the radio frequency signal. The upwardly open recess 30-30 into which objects emerging from the surgical site may be introduced is the upper limit of the detection zone 11, and the lower interior of the basket 30 the lower limit thereof.

A control circuit 22 may be programmed in a manner known to those skilled in the art to determine whether a zone 9, 10, 11 or 12 functions as an object input zone, an object monitoring zone, an object zone. or patient scan zone and surroundings. In one embodiment, a control circuit 22 may be based on objective data sent as a response from the tag to determine how many and which are detected within a single packet. The number of objects is determined by the different label serial numbers detected by ANT5, ANT6, ANT7 or ANT8. The object type is determined by the barcode inserted into the GTIN topography within the label. Each object type It has a different GTIN-13 code and is identified by the system through it. Each time an object code is read by the antenna, the GTIN-13 code and serial number are read, precise identification granting on the object count 1, 2, 3 or 4. A control circuit 22 can also be used to prevent reuse of previously used objects. Control circuit 21 may prevent continuous reading of contents in output zone 11 by considering all elements discharged within the output zone.

A control circuit 22 can also store the serial and GTIN-13 numbers of each tag activated and unloaded in a surgical procedure. This serial number is a unique long numeric sequence that belongs to each particular tag, as can be seen in FIG. 24. After the procedure is completed, a list of GTIN-13 serial numbers and identification is generated and electronically linked to the medical record shown in fig. 25. In another embodiment, reports with the GTIN-13 label and serial number list can be printed and by adding the physical medical record also shown in FIG. 25. Serial label numbers not detected by antennas At the end of the procedure they are considered as labels within the surgical site. Control circuit 22 can alert you of this occurrence as well as outline the steps of the following guideline. If the object is not detected, a message is sent to the medical director and the head nurse to monitor a sentinel event. The control circuit 22 can be programmed to compare the list of detected identifiers in the detection zone output 11 to a list of detected identifiers in the input detection zone 9 and monitoring zone 10. If an identifier is found in the identifier list detected in the outbound detection zone, but not in the list of identifiers detected in the inbound detection zone, the identifier may be added to the list of identifiers detected in the outbound detection zone after agreement by message on the monitor 30 Alternatively, the user can be activated to activate the objects detected by control circuit detection zones 21 within detection zones 10 and 11. This may be desirable, for example, in the case of an object that has been inadvertently opened directly within the surgical field. Control circuit 22 may also be programmed to assist in emergency situations. Pre-scanned textiles are available inside the 20D1 emergency drawer. This drawer is equipped with a seal that can be opened in an emergency situation. All tissues should be offered to the surgical team while the system is being powered on and initialized. Circuit 22 is programmed with an emergency touch shortcut button. When pushed, all previously digitized textile products are considered within the surgical field.

Additional features which may be advantageously provided via the control circuit 22 are various alarms and warning systems. In one embodiment, the control circuit may be programmed to compare the identity and number of objects processed by the input scanning device with objects processed in the control zone and processed by the output device. The control circuit may confirm that all objects that have entered the surgical field have been removed from the operating field and may initiate an alarm if, at the end of a surgical procedure, data comparison from the input device with data from the tracking and output scanning devices indicate that not all objects that entered the surgery site left it.

0088 It can also provide a warning if an object packet does not contain the correct number or type of objects or if an identifier is not working correctly in parsing in input detection zone 9. In another embodiment, the bag or container may include an identifier ID. In addition, the control circuit can be programmed to sound an alarm if an attempt is made to scan the same object or object packet in the input area twice. From one Known to those skilled in the art, the alarm may be in the form of an alert / audible alarm, a visual alert / alarm or any other suitable alert / alarm or a combination thereof. The control circuit may, for example, give the visual alarm on the monitor.

Figures 23-1 through 23-18 show the software flowchart sequence with warning signals, alarms and algorithms.

It will be appreciated that a variety of materials, configurations and properties may be used in the antennas and labels of the present invention. An object identifier to be monitored, in certain embodiments, may be an RF tag that utilizes an integrated circuit connected to an antenna specifically designed to identify objects. The RF tag chip has different topographies where data can be entered and read (FIG. 24). In the present invention, the GTIN topography of the chip is programmed with a GTIN-13 numeric 12-digit sequence according to GS1 Global Standards. In the present invention, the chip serial number is used as a unique object identification. It contains 38 numeric digits (38 bits) and is validated through bank encryption. An invalid serial number will be blocked by control circuit 21. This solution confers the quality of textile used as well as the proper attachment of labels to objects 1, 2, 3 and 4. An identifier of the present invention is a combination of a bar code inserted in the chip and the chip serial number. . The barcode identifies object type 1, 2, 3, or 4. The individual serial number allows the control circuit 22 to count objects with the same GTIN-13 code and different serial numbers.

Identifiers such as radio frequency tags can have various shapes and dimensions. In the present invention, the chip antenna was developed specifically for this purpose as well as the encapsulation. Labels and associated antennas can be operated at a frequency range determined by your local government. The elements that make up the specially developed RFID tag for this system is shown in FIG. 20. The CHIP 300 is connected to the specially designed aluminum antenna 301 and sealed between 2 layers of PET 302 and 303. The tag is passive and therefore will not work if there is no detection field capable of recognizing its frequency. In one embodiment of the RFID tag is sutured to the surgical dressing next to the attachment thread, which can be shown in FIG. 16. In another embodiment, the CHIP 300 is connected to an aluminum antenna and sealed between two layers of PVC and barium composite radiant marker. This marker is usually sutured to surgical tissues as shown in FIG. 17. In another embodiment, the RFID tag is fused to the end of the anchor wire. By stitching the thread for surgical RFID tag dressing is fixed to the textile. In another embodiment, the radiating wire and RFID tag is attached to its tip, as shown in Figure 19.

Considering surgical gauze (sponge), the RFID tag is attached to one end of the open gauze coated with other gauze or not. The gauze is manufactured with crochet machines to prevent the destruction of sturdy stitching and to prevent label separation. The open gauze is depicted in FIG. 14A is folded into four layers in FIG. B. The gauze can also be wrapped in itself with the attached RFID tag. A stitch at the top and bottom ends stabilizes the gauze so it won't unwrap. It also serves as a recovery guide. This gauze is intended for use in laparoscopic surgery.

Memory chip label 300 may store additional information such as the object's date of manufacture, sterilization expiration date, and any other desirable information.

0094 Identifiers can be protected from accidental or intentional data corruption and corruption. For example, the identifiers may be encapsulated in inert biocompatible plastics. The plastic filler materials that the handles are encapsulated may be waterproof, liquid impervious and waterproof. gas; Identifiers can resist degradation when exposed to gas sterilization methods. Identifiers can also be encapsulated in an outer material that has electromagnetic shielding properties to prevent data damage due to the presence of other electromagnetic waves. For example, FIG. 20 shows the protective encapsulation of an embodiment of the invention with one. In FIG. 2, the package 100 may have electromagnetic shielding properties.

0095 Identifiers can also be protected from electromagnetic coupling with other identifiers, preventing reading range reduction. The effects of electromagnetic coupling are generally greatest when the tags are packed in close proximity and are stacked center to center. In one embodiment, the electromagnetic coupling between the tags may be reduced by positioning the tags from the center of the objects. The identifier for each object may be positioned in an alternating position such that when each object is wrapped with another object, there is the maximum spacing between its identifiers. For example, the identifiers may be placed in the same corner of the object, but packed ^Q 90 relative to each other so that the maximum vertical spacing between the markers can be achieved, as shown in FIG. 19

The system provided by the present invention may be used alone or in combination with other systems. If the system is used alone as a standalone device, in a surgical field it can be configured to communicate with other standalone devices. This can facilitate information gathering. Alternatively, a simple standalone device can be adapted to store information in various surgical fields and combine this information in a way that helps the user to control the total number of objects in various surgical fields. For example, the user may be able to determine the total number of a particular object used in multiple surgical fields. The control circuit 22 can also be configured to collect all data about objects detected by different autonomous devices, and to compile the data into a database.

Circuits 21 and 22 may be those commercially available, with their patents and rights recognized by the present invention.

The methods and apparatus of the present invention may be used alone or in conjunction with other systems, methods and apparatus. It will be appreciated that the present invention provides a number of effective methods for accurately controlling and effectively controlling the shape, detection, identification and counting, in some cases, better characterization of objects into and out of a surgical field. to avoid inadvertent retention of an object within a patient.

Considering particular embodiments of the invention have been described herein for illustration purposes, it will be apparent to those skilled in the art that numerous variations of the details may be made without departing from the scope of the invention as defined in the appended claims.

Claims

ΙΈαυΐΡΑ ΕΝΤΟ Ε METHOD ΟΕ CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND ACCESSORIES SURGICAL, WITH LABEL AND CHIPING AND RADIUS IDENTIFICATION OIÁ, OPERATING IN UHF software, characterized by UHF, ULTRA-FIXED software, OPERATING IN UHF and method for the identification and continuous counting of objects directly into and around a clear field, as well as the monitoring of objects on the instrument table and indirectly at the focal point of the surgery, and in one embodiment, the apparatus has a 2-step input scanning device, a surgical instrument table with attached scanning device, a handheld scanning device and a scanning output device for generating a detection field, and for receiving the data that identify the mentioned objects and in another embodiment the apparatus has a plurality of antennas the upper and lower ones for the generation of a detection time, and I stopped receiving data identifying the mentioned objects; Various surgical and packaging methods have been designed to prevent electromagnetic coupling including the protection of objects and identifiers, the invention providing an apparatus and method comprising a scanner, laparoscopic and surgical probes, and techniques for securing textile labels for bonding. 2. "EQUIPMENT AND METHOD OF CONTROL. SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MOTIVATION: 0tvt CHIP AND IDENTIFICATION BY RADIOFREQUENCE, OPERATIONAL HYPERFRAGENCY according to claim 1, wherein said input scanning device comprises a cabinet 20 which, in the form shown, may contain the object detection zone 9, touch web 30, 31 and display of the substructure 32 ,. also containing four drawers, drawer 2ÔD1 has a locking latch and is intended to contain the emergency source of surgical textiles, drawers 20D2 and 20D3 are intended for storing surgical gauze at the top and surgical dressings at the bottom and Drawer 2004 is divided into two levels, the lower level for storing system accessories such as antennas and cables, and the upper one receives the substructure 32.

3. ^rt SURGICAL TEXTILE ABSORBENT EQUIPMENT AND CONTROL METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MON1TORAME TO WITH CHIP AND IDENTIFICATION BY AD1 © FREQUENCY, OPERATING AT UHF FRE, according to claim 2 By the fact that in one embodiment, the substructure 32 maintains all the electronics, and is divided into sectors according to the electrical characteristics, avoiding interference with each other so that at the front of the substructure a window exposes the front of the control circuit. 22 and at the rear, a power cable connector and a main switch are located on the left side, while four RF connectors are exposed on the right side, with a control circuit adapted to control relative power, 8 tuning or deleting any signals from at least one input antenna with respect to at least one other input antenna,

4. "EQUIPMENT AND METHOD ^: CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS / ACCESSORIES, WITH EMOI TO RA ME TO LABEL WITH CHIP AND

UHF (ULTRA HfGH FREQUENCY} OPERATIONAL IDENTIFICATION according to claim 2, characterized in that u in the other embodiment the substructure 32 holds the electronics and the control circuit 21 is installed between the two antennas. alternatively the three upper drawers and the locking latch may be controlled by the control circuit 22.

5. "SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND CHIP ID AND IDENTIFICATION BY RADIO UF _. Claim 1, characterized in that the device has two screen monitors, which are connected to a hinged support, giving a slight vertical and horizontal inclination, the monitor 30 being equipped with a web-sensitive technology. touch and the 31 monitor is equipped with anti-slip technology,

6 TEQ UJ PA ENTQ AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH EMOH UORFIM LABELS WITH CHIP AND RADIOFREQUENTIAL IDENTIFICATION, OPERATING AT UHF / i / uh \ uFHF An indication 1, characterized in that said output object detection zone comprises a basket 30 provided with an ANT7 antenna positioned on the inner side of the slightly inclined side wall above said antenna connected to the control circuit 21. than a type RG58 cable.

/." EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE Sorbents, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH CHIP LABEL AND IDENTIFICATION BY RA DIOFREQU È N CIA, OPERATING IN UHF (according to UTRA) Claims 1 and 2, characterized in that a plurality of objects are present in a single package, each object having an identified one and that, prior to the introduction of objects to the surgical site, the control circuit 21, which may be inside from the substructure 32 or under the instrument table 40, energize the antennas, capture the chip response, decode and send this data to the control circuit 22, the circuit 22 can monitor the unique identification of each zone 9 object and store input detection data, facilitating object identification (ie, its type and other characteristics), as well as the number of objects entering the surgical field, the arary 20 may also contain a first visual display for displaying data processed by the circuit 22 and, with the above-mentioned technology. Touch screen, the data can be entered through the monitor 30 as well, the visual display by the second monitor 31 being able to display data exclusively related to the surgical field and is unconnected to the surgical team view, said substructure 32 may be icy on the back. upper and lower frame and defining the platform on which control circuit 21 and control circuit 22 are attached, with the power connection being located in the rear right quadrant, control circuit 22 in the front right quadrant, control circuit 21 in the left anterior quadrant and the RF connections in the left anterior posterior quad.

^ SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITORING, CHIP AND IDENTIFICATION BY RADIOFREQUENCE, OPERATING AND UHF (according to the fact, in accordance with 7). In this embodiment, the control circuit 2.1 is not located on the substructure 32, but between the ANT6 antennas under detection zone 10 and instead a POE type generator.

Over Ethernet) is installed, and this distribution is intended to avoid the interference from the alternating current,

9. "SURGICAL TEXTILE ABSORBENT EQUIPMENT AND METHOD OF CONTROL, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MOBILE IDENTIFICATION, OPERATING AT UHF (ULTRA HIGH FREQUENCY), ULTRA HIGH AID 2" , characterized by the fact that said monitors 30 and are, for example, LEO screens or any other suitable webs. I Ô "FLOOR CONTROL EQUIPMENT AND METHOD AND SURGICAL TEXTILE, INSTRUMENTS AND ACCESSORIES

SURGICAL, WITH LABEL AND RAM IN TO WITH CHIP AND UHF OPERATING ID (ULTRA HIGH FREQUENCY) ", according to claim 2, characterized in that in another embodiment monitors 30 and 31 may be integrated on a single visual display that can be a separate device from cabinet 20 such as a wall mounted monitor communicating with control circuit 30 through wired or wireless access with visual display in LED, LCD or other suitable monitor.

II .- "ABSORBABLE CONTROL EQUIPMENT AND METHOD OF SURGICAL TEXTILE, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITOR AND TQ WITH CHIP AND RADIO IDENTIFICATION, OPERATING AT UHF (with ULTRA indication)" , characterized by peto faio that the objects that are removed from the loca! can be introduced through the upper opening of the basket 30 reaching the exit detection zone 11. said objects can be identified and counted and their data can be displayed in displays 30 and 31 of cabinet 20, and the objects identified in detection zone 11 then be manually selected so that permanent objects can be removed and. disposable objects can be eoletted into. a pickup container in basket 30, this pickup container may be a plastic bag of suitable size and strength, e) can be easily removed from the basket 30 by means of a rack 12. portaθυΐΡΑΜΕΝΤΟ AND ABSORBENT CONTROL METHOD SURGICAL TEXTILE, INSTRUMENTS AND SURGICAL ACCESSORIES, WITH LABEL AND MOVEMENT WITH CHIP AND RADIO FREQUENCY IDENTIFICATION, OPERATING IN UHF (ULTRA HIGH FREQUENCY) "according to claim 2, It is characterized by the fact that monitors 30 and 31 can visually display different data and number of objects within the field, and it is also possible to display the consistency of the data presented with a color coded visual alert and audible alerts as well, such as monitors 30 and 31 may display the contents according to the software flowchart specially designed for this use and various other means of providing the desired information on the monitored objects in, within and outside the surgical field.

displayed visually on screens of monitors 30 and 31, according to the desired information.

1S. "ABSORBENT CONTROL EQUIPMENT AND METHOD

SURGICAL TEXTILE, SURGICAL INSTRUMENTS AND ACCESSORIES, - LABEL AND MOTOR WITH CHIP AND RADIO-FREQUENCY IDENTIFICATION, OPERATING IN UHF ULTRA HI FREQUENCY FREQUENCY) ", according to claim 1, characterized by the fact that the input has a Object 9, the instrument table detection zone 10 and an output section 11 may be structured to monitor each of a plurality of objects passing through them substantially simultaneously, regardless of the orientation of objects and the objects. Antennas can be designed, positioned and used to allow simultaneous control, and in addition, said scanning device may be non-optical.

14. "SURGICAL TEXTILE ABSORBENT EQUIPMENT AND METHOD OF CONTROL, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND 1 TO RAM AND NT WITH CHIP AND

IDENTIFICATION FOR OPERATING RADIQFREQUENCE AND UHF

(ULTRA NIGH FREQUENCY) "according to rer Medication 2, characterized in that the cabinet 20 may have wheels 25, 26, 27 and 28 in the corners, as well as manually operated brakes 23 24, each associated with a wheel. 27 and 28, in addition to a handle projection 22 provided to facilitate movement of the cabinet 20, which may be optionally used in conjunction with any embodiment of the invention.

15. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND

SURGICAL, WITH LABEL AND MON ITORÂM AND TQ € OfV! UHF OPERATING CHIP ^' AND RADIO FREQUENCY IDENTIFICATION * according to claim 6, characterized in that the basket 30 may have wheels 35, 36, 37 and 38 at the corners as well as brakes operated 33, 34 ^' each associated with a wheel 37 and 38, plus a handle 32 to facilitate the movement of the basket 30, this handle being optionally used in conjunction with any embodiment of the invention.

16. "£ QU! SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND CHIP MONITORING CONTROL AND METHOD OF ^' RADIO FREQUENCY FREQUENCY, OPERATING AT UHF a.' claim 1, characterized in that the circuit 21 consists of a radio frequency reader. commercially available with important features of the described system, operating in UHF with a maximum capacity of 1200 tags per second and having loop protection for antennas, avoiding channel burnout when switching antenna with the equipment on and operating in the ideal range. frequency defined by local legislation.

17. "SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH CHIP AND MONITORING

RADIO FREQUENCY IDENTIFICATION OPERATING IN UHF

(ULTRA HSGH FREQUENCY) "according to claim ^{" is} characterized by the fact that the electrical behavior of these antennas is configured and controlled by the @ hardware software to output the minimum amount of radio signal required for the system to function, preventing interference with other medical equipment ...

Ιδ.ΈθυΐΡΑ ΕΝΤΟ AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITOR WITH CHIP AND RADIOFREG.UENCE IDENTIFICATION, OPERATING AT UHF a, according to "H, a", according to UHF a) because antennas ANT5, ANT6, and A T8 connected to circuit 21 are field strength detection antennas.

19. ^!! SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITOR WITH CHIP AND RADIO IDENTIFICATION, OPERATING AT UHF (a), according to, a. that the antenna A T7 is a hybrid with an important component near field proximity. This provides multi-level detection within basket 30 in detection zone 11.

20, ΈθυΐΡΑΜΕΝΤΌ, absorbent CONTROL METHOD TEXTILE SURGICAL, INSTRUMENTS AND ACCESSORIES SURGICAL WITH LABEL AND MONITORING WITH CHIP AND IDENTIFICATION OF RADIOFREGUÊNCÍA operating and UHF (Ultra, high frequency) ", ₅ according to Claims 18 and 19, characterized _, Peio fact that antennas ANT5, ANT8 _r ANT7 and T8 are dedicated to specific functions and therefore have different sizes and shapes.

21. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND ACCESSORIES

SURGICALS WITH EMQ NI TO RAM EN TO LABEL WITH CHIP AND ULTRA HIGH FREQUENCY (UHF) RADIO IDENTIFICATION "according to claim 20, characterized in that the antennas are commercially available antennas with the test and adaptation to each of the functions specific to the system, where an antenna may also be a combination of two or more commercially available antennas in order to provide specific characteristics specifically required in the system.

22. "EQUÍPAMENT0 ABSORBERS AND CONTROL METHOD OF SURGICAL TEXTILE, AND ACCESSORIES SURGICAL INSTRUMENT WITH LABEL AND CQM then ONfTORA radio frequency identification chip and operating in the UHF (Ultra ΗΙΘΗ Frequency) '\ according to King ⁱ ndicação 20, characterized The fact is that ANT5, ANT6, ANT7 and ANT8 antennas can be powered and controlled by the control circuit.

23. "SURGICAL TEXTILE ABSORBENT EQUIPMENT AND METHOD OF CONTROL, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH OM CHIP LABEL AND MONITORING, OPERATING IN UHF

(ULTRA HK3H FREGUENCYf according to claim 20, characterized in that each antenna ANT5, ANT6, A T7 and ANT8 can be a noncircular facing field that prophesies for zones .9, 10, 11. and 12 wherein the jets i, 2, 3 and 4 are checked.

24. "SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MON 1TOR WITH CHIP AND RADIO FREQUENCY FREQUENCY IDENTIFICATION, OPERATED AT UHF, ULTRA BJD, ULTRA BJD, JULF, ULTRA BJD I believe that the antennas ΑΝΤ5, · A T6, ANT7 and ANT8, when operating as a unit consisting of several antennas, may be copied together and may form angles with each other.

25. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES WITH CHIP LABEL AND RADIO-FREQUENCY IDENTIFICATION OPERATING IN UHF (ULTRA HIGH FREQUENOY] "according to Claim 20, characterized in that the ANTS, A T6 ÃNT7 and ANT8 antennas can be controlled by a control circuit 22 through control circuit 21.

26. "EQUIPMENT AND METHOD AND CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITORING € CHIP AND

RADIO FREQUENCY IDENTIFICATION OPERATING IN UHF (ULTRA HIGH FREQ-UENCY) "according to References 1 and 20, characterized in that the control circuit 22 can warn the user if the antennas do not detect the respective code. GTIN-13 chip inside the antennas or detect the GTIM-13 code above.

27..ΈΟ: ϋΙΡΑΜΕΝΪΟ AND METHOD OF CONTROL OF SURGICAL TEXTILE Sorbents, INSTRUMENTS AND SURGICAL PROCESSES. WITH LABEL AND MON ITORAW BETWEEN THE CHIP AND IDENTIFICATION BY ULTRA HIGH FREQUENCY (UHF) OPERATION "according to claim 1, characterized in that the .22 control circuit can be arranged inside the cabinet 20, fixed to substructure 32.

28. "EGU pment and sorbents CONTROL METHOD TEXTILE SURGICAL, INSTRUMENTS AND SURGICAL XCESSÓRI.OS WITH LABEL AND MONITORING AND CHIP 20M radio frequency identification, OPERATING IN UHF (ULTRA HIGH FREQUEMCY}", according to air ^• <eiyind- 1, characterized by the fetus that the control circuit 22 can control and coordinate detection fields emitted by each successive antenna through circuit 2.1.

29. "EQUIPMENT AND METHOD OF. CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH CHIP LABEL AND RADIO-FREQUENCY IDENTIFICATION, OPERATING EJVI HF FR, according to ULJ, cf g fatof¾Slgfkldo by the fact that the control circuit 22 can be structured to adjust and. control any antennas so that during patient verification, an ANT8 antenna is only switched on at that time, while in normal mode the ANT8 is turned off and may prevent unintentional identification of other objects 1, 2, 3, or 4 outside of the surgical field. j

30V'EGUtPA BETWEEN AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND

SURGICAL, WITH LABEL AND CHIP MONITORING AND RADIOFREQ.UENCJA IDENTIFICATION. UHF (ULTRA HIGH FREQUENCY) OPERATION "according to claim 1, characterized in that the control circuit 21 receives data from a plurality of objects at substantially the same time (for example, on the order of up to 1200 objects per square meter). second), regardless of the object's orientation.

31. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND

SURGICAL, WITH LABEL AND CHIP MONITORING AND RADIOFREQ IDENTIFICATION. NC IA, UHF (ULTRA HIGH FREQUENCY) OPERATING "according to claim 1, which means that the control of the antenna detection field strength determines the spatial position of the object jl, 2, 3 or 4

32TEQO] PAGE <3 AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITORING WITH CHIP AND RADIO-FREQUENCY IDENTIFICATION, OPERATED AT UHF (a) that circuit 21 has automated intensity control to the limits determined by circuits 21 and 22.

33,. "EGUi.P SURGICAL TEXTILE ABSORBENT CONTROL MENT AND METHOD. INSTRUMENTS AND ACCESSORIES SURGICAL, WITH LABEL AND CHIP MONITORING AND UHF (ULTRA HIGH FREQUENCY) IDENTIFICATION "according to claim 1, characterized in that, in a particular configuration, ANTS, ANT8 and ANT7 antennas are operating continuously, while ANT8 is turned on only- when determined by control circuit 22,

TEQU IP ENVIRONMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITORING WITH CHIP AND IDENTIFICATION BY RADIO FREQUENCY (ULTRA HIGH FREQUENCY) 1. In a given configuration, ANT5, ANT6, and ANT7 antennas are operating continuously, while ANTS is on only when determined by the control circuit.

33 "QUICK EQUIPMENT AND METHOD OF CONTROL AND SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND CHIP ID AND IDENTIFICATION BY RADIOF REQUIRED, OPERATING AT UHF} a , SH§5 0I§ p. P ^eto fetal a control circuit 22 may be programmed in a known manner to determine if a zone 9, 10, 11 or 12 works as an object entry _zone, a zone object monitoring, an exit zone object or patient scan zone and surroundings,

36. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND ACCESSORIES

SURGICAL, WITH LABEL AND CHIP MONITORING AND RADIOFREGUEN IDENTIFICATION, UHF OPERATION

(ULTRA HIGH FREQUENCY} "according to claim 1, characterized in that, in one embodiment, a control circuit 22 may be based on data sent as a response from the label to determine how many and which are. detected within a single packet, the amount of objects is determined by the different serial numbers of the tags detected by ANT5, ANT6, ANT7 or ANT8 and the object type is determined by the barcode inserted into the GTIN topography inside the label. _» Since each object type has a different GTIN-13 code and is identified by the system through it, and each time an object code is taken by the antenna, the GTIN-13 code and the number of: series are read, precise identification granting on object counting 1 2, 3 or 4 a control circuit 22 may be programmed in a known manner to determine whether a zone 9, 10, 11 or 12 functions as an object input zone, a object monitoring, an output zone object or patient scan zone and surroundings.

37. "EQUFPA BETWEEN AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND

SURGICAL, WITH CHIP LABELING AND ONITORING AND RADI OFFERING IDENTIFICATION OPERATING IN UHF (ULTRA HIH FREQUENCY FREQUENCY) "according to claim 1 characterized in that a control circuit 22 may also be used to prevent reuse of objects already used B control circuit 21 can prevent continuous reading of contents in output zone 1 by considering all discharged elements: within the output zone.

38 SURGICAL TEXTILE ABSORBENT CONTROL METHOD AND METHOD OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND ACCESSORIES, WITH LABEL AND RADI IDENTIFICATION BY RAD IOF REQUIRES, OPERATING AT UHF (ULTRA H) agreement (ULTRA H) claim 1, wherein a control circuit 22 may also store the serial and GTIN-13 numbers of each tag unloaded and unloaded in a surgical procedure, such serial number being a unique long numeric sequence belonging to every tag in particular, and after the procedure is complete, a GT1N-13 Serial Number and Identification System is generated and electronically linked to the medical record.

39. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND THE! TORA, fvl AND NTO WITH CH PE IDENTIFICATION BY RA DIOFREQU È NC iA, H ULTRA, HIGH ULTRA according to claim 38, further characterized by the fact that in another embodiment, reports with the list with the serial numbers of the label and identification GT! N-13 may be printed and by adding the physical medical record, The serial numbers of undetected labels and antennae at the end of the process are considered to be labels within the surgical focal, and the control circuit 22 can alert you of this occurrence, as well as outline the steps of the following guideline, so that in this case If the object is not detected, a message is sent to the medical director and the head nurse to monitor a sentinel event.

40. SURGICAL TEXTILE ABSORBENT CONTROL METHOD AND METHOD. SURGICAL INSTRUMENTS AND ACCESSORIES WITH LABEL AND MONITORING Glvt CHIP AND RADIOFREGUÈHCtA IDENTIFICATION OPERATING IN ULH HIGH FREQUENCYf according to claim 39, characterized by the fact that the .22 control circuit can be programmed to compare the list. identifiers detected in the output of detection zone 11, with a list of identifiers detected in input detection zone 9 and monitoring zone 10, and if an identifier is found in the identifier list detested in output detection zone, roas is identified in the list ^* s detected in the input detection zone, the handle can be added to the list identifiers cie detected in the input detection zone after agreement by message on the monitor 30,

41. "SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH CHIP AND LABEL ENTG TYPE AND RADIO FREQUENCY IDENTIFICATION. OPERATING AT UHF (according to 40, a, p. In fact, in an alternative, the user may be activated to activate objects detected by control circuit detection zones 21 within detection zones 10 and 11, which may be desirable, for example, in the case of an object. unintentionally opened directly inside the operating room. - «." SURGICAL TEXTILE ABSORBENT, SURGICAL INSTRUMENTS AND ACCESSORIES CONTROL EQUIPMENT AND METHOD, WITH CHIP LABELING AND MONITORING, ^■ ULTRAFRECTION IDENTIFICATION, HIGH FREQUENCY) "according to claim 1, characterized in that the control circuit 22 can also be programmed for emerges when pre-scanned textiles are available inside the 20D1 emergency drawer, and this drawer is equipped with a seal that can be opened in an emergency situation. 43 "AND THE, IU PAM AND AND THE METHOD OF SURGICAL TEXTILE ABSORBENT, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITORING WITH CHIP AND RADIO IDENTIFICATION, OPERATING AT UHF}, according to claim, characterized by, a This is because all tissues must be offered to the surgical team while the system is being turned on and initialized.

44. "SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES WITH CHIP LABEL AND MONITORING, OPERATING IN UHF (ULTRA HIGH FREQUENCY) "according to claim 1, characterized in that circuit 22 is programmed with a touch-sensitive shortcut emergency button which, when pushed, all previously scanned textiles are considered within the field. surgical j

45. "SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MOBILE IDENTIFICATION, OPERATING AND UHF (according to claim 1) because control circuit 22 can also be used to prevent reuse of objects already in use and control circuit 21 can prevent continuous reading of contents in output zone 11 by considering all elements discharged within the control zone. get out

46TEQU! MBP and TG, absorbent CONTROL METHOD TEXTILE SURGICAL, INSTRUMENTS AND ACCESSORIES SURGICAL WITH LABEL AND MONfTORAMENTO chip and radio frequency identification, operating in the UHF (Ultra B1ÔH FREQUENCYV ¹ according to claim 1, characterized Peio fact that a The object identifier to be monitored, in certain embodiments, may be an RF tag that utilizes an integrated circuit connected to a specifically designed antenna to identify the means, and the RF tag chip has different topographies where the data can be inserted and read and in the present invention, the chip's β ^' Ν topography is programmed with a sequence of GTfN-13 numeric digits according to GS1 Global Standards and the ehíp serial number is used as a unique identification. of the object, number è $ te contain 38 numeric digits (38 bits) and is validated through bank encryption, where a serial number inv read will be blocked Peio control circuit 21. 4?, ΈΟϋ! ΡΑ ΕΝΤΟ AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND M-ONITCHRATION WITH CHIP AND 1 DENTI FI RADIOFrequency OPERATION, IN ULTRA HYPHONE} according to claim 1, characterized in that an identifier of the present invention is a combination of a bar code inserted into the chip and the chip serial number, wherein the bar code identifies object type 1,

2, 3 or 4; The individual serial number allows the control circus 22 to count objects with the same GTiN-13 code and different serial numbers.

48. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, INSTRUMENTS AND

SURGICAL, WITH LABEL AND MONITOR AND TÔ WITH CHIP AND RADIO FREQUENCY IDENTIFICATION, OPERATING IN UHF (ULTRA HIGH FREQ-UENCY} ", according to claim 1, characterized by the fact that the CHIP 3G0 is connected to the aluminum antenna specially 301 and sealed between 2 layers of PET 302 and 303, the label is passive and therefore will not work unless there is a detection field capable of recognizing the frequencies.

49. "EQUIPMENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITORING WITH CHIP AND

UHF OPERATING RADIO FREQUENCY IDENTIFICATION "according to claim 1, characterized in that in one embodiment the RFID tag is sutured to the surgical dressing along the attachment wire.

δΟ.ΈθυΐΡΑΜΕΝΤΟ AND METHOD FOR CONTROLING SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND MONITORING WITH CHIP AND RADIO-FREQUENCY IDENTIFICATION, OPERATING AT UHF (a), according to ULTRA H, a, a, a characterized in that in another embodiment, the CHIP 300 is connected to an aluminum antenna and sealed between two layers of radiant marker composed of PVC and barium.

51. "SURGICAL TEXTILE ABSORBENT CONTROL EQUIPMENT AND METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES, LABELING AND MONITORING WITH CHIP AND RADIO-FREQUENCY IDENTIFICATION, OPERATING AT UHF-1 according to ULTRA HIGH FREGU." , characterized in that in another embodiment, the REID tag is fused to the end of the attachment thread, and the RFID tag surgical dressing thread is attached to the stitch-fastened textile,

52. "EGU I PATIENT AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND CHIP MONITORING, OPERATING AT UHF} (a), according to UHF a) characterized by the fact that in another embodiment the Beaming wire and RFID tag are attached to its tip,

53. "EQU3PA AND METHOD OF CONTROL OF SURGICAL TEXTILE ABSORBENTS, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND TYPE E. WITH CHIP AND RADIO FREQUENCY IDENTIFICATION, OPERATING AT UHF} (a), according to UHF a) characterized by the fact that the memory tag 300 can store additional information, such as the object's date of manufacture, sterilization expiration date, and any other desirable information.THE SURGICAL TEXTILE ABSORBENT CONTROL TYPE AND METHOD SURGICAL ACCESSORIES, WITH LABEL AND MONITOR - AND TO CHIP AND P RADIO FREQUENCY IDENTIFICATION, OPERATING IN ULTRA HIGH FREQUENCY} "according to claim 1, characterized in that the identifiers may be protected from accidental deterioration and corruption of cia! or intentional. For example, the identifiers may be encapsulated in inert bi-compatible plastics.

55. ΈΟϋ1ΡΑΜΕΝΤΟ £ SURGICAL TEXTILE ABSORBENT CONTROL METHOD, SURGICAL INSTRUMENTS AND ACCESSORIES WITH CHIP LABEL AND RADIO IDENTIFICATION _» OPERATING IN UHF a), characterized by hi-frequency a) whereas the plastic and filler materials in which the tags are encapsulated may be water impermeable, liquid impermeable and gas impermeable, the identifiers may resist degradation when exposed to gas sterilization methods. has etetrornagnetic shielding properties to prevent data damage due to the presence of other electromagnetic waves,

56. "ABSORVE EQUIPMENT AND METHOD OF CONTROL FOR SURGICAL TEXTILE, INSTRUMENTS AND ACCESSORIES

SURGICAL, WITH EMO i TO RAM LABEL AND ULTRA HIGH FREQUENCY (UHF) ID ", according to claim 1, characterized in that identifiers can also be protected from electromagnetic coupling with the other tags, preventing reading range being reduced, since the effects of effective electromagnetic coupling are generally greater than the tags ^, the tags are packed in close proximity and are stacked center-to-center,

57. "ABSORBENT CONTROL EQUIPMENT AND METHOD

SURGICAL TEXTILE, SURGICAL INSTRUMENTS AND ACCESSORIES, WITH LABEL AND CHIP MONITORING AND RADIO FREQUENCY IDENTIFICATION, OPERATING IN UHF (ULTRA HIGH FREQUENCY) "according to claim 1 It is characterized by the fact that in one embodiment, the magnetic coupling between the identifiers can be reduced by placing the tags from the center of the objects, and the identifier for each object can be positioned in an alternate position such that when each object is wrapped with another object _. If there is the maximum spacing between their identifiers, for example, the identifiers may be placed in the same corner of the object but packed 90 ° relative to each other so that the maximum vertical spacing between the markers can be achieved.