CN113576642B

CN113576642B - Reduction system for lower limb fracture, broken bone and rotation deformity

Info

Publication number: CN113576642B
Application number: CN202110873585.8A
Authority: CN
Inventors: 张瑞鹏; 陈伟; 张英泽; 侯志勇; 张奇
Original assignee: Third Hospital of Hebei Medical University
Current assignee: Third Hospital of Hebei Medical University
Priority date: 2020-03-10
Filing date: 2020-03-10
Publication date: 2022-08-30
Anticipated expiration: 2040-03-10
Also published as: CN111329571A; CN113576641A; CN111329571B; CN113576642A; CN113576641B; CN113576643B; CN113576643A

Abstract

The invention discloses a reduction system for lower limb fracture, broken bone and rotation deformity, which utilizes healthy side images of patients to establish a contrast standard when evaluating the fracture deformity, reversely evaluates the fracture deformity, does not set a uniform reference standard, but takes the healthy side of the patients as the reference standard, is different from person to person, more compounds the self condition of each patient, is not influenced by factors such as the shooting angle, the shooting distance, the body placement of the patients and the like of X-ray images, and carries out calculation, analysis and evaluation through a computer, thereby further improving the accuracy of evaluation and reduction, ensuring that the post-operation body has good recovery and two side bodies are symmetrical.

Description

Reduction system for lower limb fracture, broken bone and rotation deformity

The original application numbers of the divisional application are: 202010159773.X, filing date: the invention is named as follows in 10 days 03 month in 2020: a lower limb fracture reduction system.

Technical Field

The invention relates to the technical field of fracture treatment, in particular to a reduction system for lower limb fracture, broken bone and rotation deformity.

Background

Fracture is a common disease in orthopedic surgery, and before the fracture part is permanently fixed, the fracture part needs to be reset, the length of the lower limb needs to be recovered, and the correction of anterior-posterior angulation deformity, lateral angulation deformity and rotation deformity needs to be performed.

The traditional long bone fracture reduction method is that under the direct vision environment, doctors open and reduce by experience and skill, but the open reduction method is easy to destroy blood circulation and soft tissues around the fracture, the operation time is long, bleeding is much, and infection is easy.

The fracture reduction methods proposed in patents US 9524587, US5728095 and EP2767252 can be embodied as the following procedure: firstly, shooting an X-ray positive piece and a side piece of a fracture part containing a complete external fixation bracket; secondly, manually measuring pose parameters between the bone fracture ends and installation parameters between the bone blocks and the external fixed support on the X-ray image, and reading the length of each branched chain of the external fixed support; then, inputting the data into a computer system, and solving the adjustment scheme of each branched chain driving joint by using a certain algorithm to form an electronic prescription; and finally, adjusting the lengths of six branched chains of the external fixing bracket according to the electronic prescription to realize the reduction of the fracture broken end.

The reset method has the following defects: 1) the factors such as the shooting angle, the shooting distance and the patient limb placement of the X-ray image cannot be standardized, the evaluation result has errors, and the resetting effect is not ideal; 2) when the X-ray image is measured manually, various subjective and objective errors exist; 3) the X-ray positive position sheet and the side position sheet can not reflect the rotation deformity of the broken end of the fracture around the axis, and the operation is carried out by the experience of a doctor, otherwise, the reduction is incomplete, and the limb movement is blocked after the recovery.

Disclosure of Invention

The invention aims to provide a lower limb fracture reduction system which utilizes a healthy side image as a reference to reversely evaluate fracture deformity so as to improve the accuracy of evaluation and reduction and ensure good recovery of postoperative limbs.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows:

the reset system comprises:

c-arm machine and computer for pre-operative assessment

The patient lies down upwards, the C-arm machine perspectives the operation section positive piece and the healthy side positive piece symmetrical to the operation section, and transmits the positive pieces into the computer operation interface, and defines four directions of front, back, inner and outer;

computer start-of-form parameter evaluation

(1) Assessment of bone fragment length shift

(1.1) according to the established factor A, a computer evaluates whether the two fractured bones have displacement in the length direction on the operative segment positioning sheet;

(2) assessment of lateral deformities of fractured bones

(2.1) establishing a reference standard on the healthy side, and acquiring a reference value K1 capable of evaluating whether the fractured bone has lateral angular deformity and a reference value K2 capable of evaluating whether the fractured bone has lateral displacement on a normal position sheet on the healthy side by a computer according to the established element B;

(2.2) according to the determined element B, the computer obtains actual values K1 ', K2' on the surgical segment normal sheet relative to the reference values K1, K2;

(2.3) comparing the actual value with the reference value in the computer operation interface and generating a result, if the difference between K1 'and K1 is greater than the allowable error value, then assessing that the fractured bone has lateral angular deformity, if the difference between K2' and K2 is greater than the allowable error value, then assessing that the fractured bone has lateral displacement, otherwise, no lateral deformity exists;

(2.4) if there is a lateral angulation deformity and/or lateral displacement, computer evaluating the inward or outward angulation and/or displacement according to a given factor B1;

the system also comprises a lower limb traction device for intraoperative reduction;

(1.2) if the fractured bone is displaced in the length direction, the lower limb traction device performs traction reduction operation;

(2.5) if the fractured bone has lateral deformity, the lower limb traction device performs reduction operation on the fractured bone lateral deformity;

reevaluation by C-arm machine, computer and lower extremity traction device

And (3) repeating the pre-operation evaluation (1) and (2), re-evaluating whether the reduced operation section has broken bone length displacement and broken bone lateral deformity, and if so, repeating the operation of the reduction (1.2) and (2.5) in the operation until the length of the lower limb is recovered and the medial or lateral deformity is corrected.

The further technical solution is that the preoperative assessment further comprises:

the patient lies down upwards, the C-arm machine perspectives the side sheet of the operation section and the side sheet of the healthy side symmetrical to the operation section, and transmits the side sheets to the computer operation interface to define four directions of front, back, inner and outer;

(3) assessment of deformity around fractured bone

(3.1) establishing a reference standard on the healthy side, and acquiring a reference value K3 capable of evaluating whether the fractured bone is in anterior-posterior angulation deformity and a reference value K4 capable of evaluating whether the fractured bone is in anterior-posterior displacement on a lateral position sheet on the healthy side by using a computer according to the established element C;

(3.2) according to the determined element C, the computer acquires actual values K3 'and K4' corresponding to the reference values K3 and K4 on the lateral position sheet of the operation section;

(3.3) comparing the actual value with the reference value in the computer operation interface and generating a result, if the difference value between K3 'and K3 is greater than the allowable error value, evaluating the presence of anterior-posterior angulation deformity of the fractured bone, if the difference value between K4' and K4 is greater than the allowable error value, evaluating the presence of anterior-posterior displacement of the fractured bone, otherwise, not evaluating the presence of anterior-posterior deformity;

(3.4) if there is anterior-posterior angulation deformity and/or anterior-posterior displacement, computer evaluating the anterior or posterior angulation and/or displacement according to a given factor C1;

the intraoperative reduction further comprises:

(3.5) if the fractured bone has front and back deformity, performing reduction operation on the front and back deformity of the fractured bone;

the re-evaluation further comprises:

and (4) repeating the preoperative evaluation (3), re-evaluating whether the operation section after reduction has front and back deformities, and repeating the operation of intraoperative reduction (3.5) until the front or back deformities are corrected.

(4) assessment of bone fracture rotation deformity

(4.1) establishing a reference standard at the healthy side, and acquiring at least one reference value K5 capable of evaluating whether the fractured bone is rotated and deformed on an orthostatic sheet at the healthy side by the computer according to the established element D;

(4.2) according to the determined element D, the computer acquires an actual value K5' corresponding to the reference value K5 on the surgical segment positive position sheet;

(4.3) comparing the actual value with the reference value in the computer operation interface and generating a result, if the difference between K5' and K5 is greater than an allowable error value, assessing that the fractured bone has rotational deformity, otherwise, not;

(4.4) if the rotation deformity exists, the rotation deformity exists at the far end can be defaulted, and the inward rotation or outward rotation deformity is judged according to the pointing direction of the tiptoe;

the intraoperative reduction further comprises:

(4.5) if the fractured bone has the rotational deformity, carrying out the reduction operation of the internal rotation or the external rotation deformity;

the re-evaluation further comprises:

and repeating the preoperative assessment (4), re-assessing whether the reduced operation section has rotational deformity, and repeating the operation of intraoperative reduction (4.5) until the internal rotation or external rotation displacement is corrected.

The further technical scheme is that the method for evaluating the fractured bone rotation deformity further comprises or is replaced by the following steps:

obtaining a distance value L between the inner side end point of the fracture line at the proximal end of the fractured bone and the inner side end point of the fracture line at the distal end of the fractured bone on the C-arm machine perspective operation segment correction sheet _{Inner part} Obtaining the distance value L between the outer side end point of the fracture line at the proximal end of the fractured bone and the outer side end point of the fracture line at the distal end of the fractured bone _{Outer cover} And generating a result when L _{Inner part} ≠L _{Outer cover} If the fractured bone has the rotation deformity, the fractured bone is evaluated to have the rotation deformity, otherwise, the fractured bone does not have the rotation deformity.

A further technical solution is that the method for evaluating the displacement of two broken bones in the longitudinal direction, which is included in the predetermined element a, includes:

whether a fracture exists between the far end of the near-end fractured bone and the near end of the far-end fractured bone; and

whether the distal end of the proximal fractured bone is distal to the proximal end of the distal fractured bone.

The further technical scheme is that the method for acquiring the reference values K1 and K2 contained in the given element B comprises the following steps:

on a normal position sheet of a healthy side symmetrical with the operation section in perspective of the C-arm machine,making a central axis L of the healthy side near-end bone ₁ And the axial line L of the healthy distal bone ₂ ,L ₁ And L ₂ The intersection angle alpha is recorded as a reference value K1, L ₁ And L ₂ Distance L between two points intersecting the fracture line _AB Reference value K2;

the method for obtaining the actual values K1 'and K2' included in the predetermined element B comprises the following steps:

making a central axis L of the operative side near-end bone in the positive direction on a C-arm machine perspective operation segment positioning sheet ₁ ', and axial line L of the distal bone at the operative side ₂ ’,L ₁ ' and L ₂ The angle of intersection α 'is recorded as the actual value K1', L ₁ ' and L ₂ ' distance L between two points intersecting the fracture line _AB Note as actual value K2'; wherein

The central axis is obtained by the following method:

on the healthy side, two marking lines for connecting the edges of the two sides of each end bone are transversely made in the positive direction of each end bone, and the middle points of the two marking lines are connected to obtain the central axis of the end bone; and on the operation side, the healthy side is mirrored to the operative side, and the healthy side healthy sheet is rotated for the first time to make the healthy side near end coincide with the operative side near end, at this time L ₁ Is at the position of L ₁ ' then, the healthy side orthotopic piece is rotated a second time so that the healthy side distal end coincides with the operative side distal end, at which time L ₂ Is located at a position of L ₂ ’。

The further technical proposal is that in the generated result, when K1' -K1 is more than 2 degrees, the lateral angulation deformity of the fractured bone is evaluated; when K2' -K2 > 2mm, the presence of lateral displacement of the fractured bone is assessed.

A further technical solution is that the determination criterion of the predetermined element B1 is, for example, the distal central axis L ₂ The proximal end of' is located at L ₁ The medial aspect of the' is then inwardly angled or displaced, e.g., about the central distal axis L ₂ The proximal end of' is located at L ₁ The outer side of' is then angled or displaced outwardly.

The further technical scheme is that the method for acquiring the reference values K3 and K4 included in the established element C comprises the following steps:

on the side position sheet of the healthy side which is symmetrical with the operation section in the C-arm machine perspective, the central axis L of the healthy side near-end bone side direction is made ₃ And a medial axis L lateral to the healthy distal bone ₄ ,L ₃ And L ₄ The intersection angle beta is recorded as the reference value K3, L ₃ And L ₄ Distance L between two points intersecting the fracture line _CD Reference value K4;

the method for acquiring the actual values K3 'and K4' included in the predetermined element C includes:

making a medial axis L of the lateral direction of the proximal bone of the operation side on a C-arm machine perspective operation section lateral position sheet ₃ ', and medial axis L lateral to the distal bone ₄ ', L3' and L ₄ The ' intersection angle β ' is recorded as the actual value K3 ', L ₃ ' and L ₄ ' distance L between two points intersecting the fracture line _CD Note as actual value K4'; wherein

The central axis is obtained by the following method:

on the healthy side, two marking lines for connecting the edges of the two sides of each end bone are transversely made in the lateral direction of each end bone, and the middle points of the two marking lines are connected to obtain the central axis of the end bone; and is provided with

In the operation side, the side sheet marked with the central axis on the health side is mirrored on the side sheet on the operation side, and the health side sheet is rotated for the first time to make the health side near end coincide with the operation side near end, at this moment, L ₃ Is located at a position of L ₃ ' then, the side healthy slice is rotated for the second time to make the distal healthy end coincide with the distal operative end, at this time, L ₄ Is located at a position of L ₄ ’。

The further technical proposal is that in the generated result, when K3' -K3 is more than 2 degrees, the presence of angulation deformity before and after the fractured bone is evaluated; when K4' -K4 > 2mm, the presence of anterior-posterior displacement of the fractured bone is evaluated.

A further technical solution is that the criterion of the predetermined element C1 is, for example, the central axis L of the distal end ₄ The proximal end of' is located at L ₃ The anterior aspect of' is then angled or displaced anteriorly, e.g. from the central distal axis L ₄ The proximal end of' is located at L ₃ The posterior side of' is then angled or displaced posteriorly.

The method for acquiring the reference value K5 for evaluating whether the fractured bone is rotationally deformed or not, which is included in the predetermined factor D, comprises the following steps:

obtaining the maximum value L of the width of the knee joint on the healthy side on a healthy side orthotopic sheet which is symmetrical with the operation segment through C-arm machine perspective _Knee And the maximum value L of the ankle joint width _{Ankle joint} ；

The method for obtaining the actual value K5' relative to the reference value, which is included in the given element D, comprises the following steps:

obtaining the maximum value L of the width of the knee joint at the operation side on a C-arm machine perspective operation segment orthoscope _Knee ' and maximum value of ankle joint width L _{Ankle joint} ’；

In the generated result, when L is _Knee ’≠L _Knee When it is determined that the proximal fractured bone has a rotational deformity, L _{Ankle joint} ’≠L _{Ankle joint} When the bone is broken, the distal broken bone has rotational deformity.

Adopt the produced beneficial effect of above-mentioned technical scheme to lie in:

this low limbs fracture system that resets utilizes patient's side of health image to establish contrast standard when aassessment fracture deformity, the reverse aassessment fracture deformity, do not set for unified reference standard, but use patient's side of health as reference standard, vary from person to person, more compound each patient's self condition, do not receive the shooting angle of X ray image, the influence of factors such as shooting distance and patient's limbs are put, and carry out computational analysis aassessment through the computer, further improved aassessment and the accuracy that resets, can guarantee that the postoperative limbs have good recovery, bilateral limbs are symmetrical.

Drawings

FIG. 1 is a perspective view of a side healthy tab of a C-arm machine symmetrical to a surgical segment;

FIG. 2 is a perspective view of an orthographic view of a C-arm machine of a surgical segment;

FIG. 3 is a perspective of a side blade of the side of the C-arm machine symmetrical to the surgical segment;

FIG. 4 is an elevational view of the C-arm machine perspective surgical segment;

fig. 5 is a schematic view of a portion of a fracture line in an orthostatic sheet of a surgical level.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Example one

Referring to fig. 1-5, a lower limb fracture reduction system is disclosed, which can be used for the early reduction of the length of a limb and the reduction of a lateral deformity, and the operation method comprises pre-operation evaluation, intra-operation reduction and re-evaluation correction after reduction.

The patient lies down upwards, the C-arm machine perspectives the operation section positioning sheet and the positioning sheet on the healthy side symmetrical to the operation section, and transmits the positioning sheets to the computer operation interface to define the front, back, inner and outer directions.

Assessment of bone length displacement before surgery

(1.1) according to the determined element A, the computer evaluates whether the two sections of fractured bones have displacement in the length direction on the operative section correction sheet.

The method for evaluating the displacement of two broken bones in the length direction, which is included in the predetermined element A, comprises the following steps:

whether a fracture exists between the far end of the near-end fractured bone and the near end of the far-end fractured bone or not; and

Preoperative assessment of lateral deformity of fractured bones, including assessment of lateral angulation deformity and lateral displacement:

(2.2) according to the determined element B, the computer acquires actual values K1 ', K2' corresponding to the reference values K1, K2 on the surgical segment positive position sheet;

(2.3) comparing the actual value with the reference value in the computer operation interface and generating a result, if the difference between K1 'and K1 is greater than an allowable error value, then assessing that the fractured bone has lateral angulation deformity, if the difference between K2' and K2 is greater than an allowable error value, then assessing that the fractured bone has lateral displacement, otherwise, no lateral deformity exists;

(2.4) if there is a lateral angulation deformity and/or lateral displacement, the computer evaluates the angulation and/or displacement either inward or outward according to a given factor B1.

The method for obtaining the reference values K1 and K2 included in the given element B comprises the following steps:

on a healthy side positioning sheet which is symmetrical with the operation section in C-arm machine perspective, a central axis L of the healthy side near-end bone in the positive direction is made ₁ And the central axis L of the healthy distal bone in the normal direction ₂ ,L ₁ And L ₂ The intersection angle alpha is recorded as a reference value K1, L ₁ And L ₂ Distance L between two points intersecting the fracture line _AB Is noted as reference K2.

making a central axis L of the operative side near-end bone in the positive direction on a C-arm machine perspective operation segment positioning sheet ₁ ', and axial line L of the distal bone at the operative side ₂ ’,L ₁ ' and L ₂ The intersection angle α 'is recorded as the actual value K1', L ₁ ' and L ₂ ' distance L between two points intersecting the fracture line _AB 'to be recorded as the actual value K2'.

The central axis is obtained by the following method:

on healthy side, two marking lines connecting two side edges of each end bone are transversely made in the positive direction of each end bone, and the middle axis of the end bone is obtained by connecting the midpoints of the two marking linesA wire; and on the operation side, the healthy side is mirrored to the operative side, and the healthy side healthy sheet is rotated for the first time to make the healthy side near end coincide with the operative side near end, at this time L ₁ Is at the position of L ₁ ' then, the healthy side orthotopic piece is rotated a second time so that the healthy side distal end coincides with the operative side distal end, at which time L ₂ Is at the position of L ₂ ’。

The central axis of the operation side is made at the same position of the operation side by using the image of the central axis of the healthy side, so that the positions of the central axes made twice on the bone are the same, and the feasibility of comparison is ensured.

In the result generated in the step (2.3), when K1' -K1 is more than 2 degrees, the fractured bone is evaluated to have lateral angulation deformity; when K2' -K2 > 2mm, the fractured bone is evaluated to have lateral displacement.

The determination criteria for the given element B1 are, for example, the central axis L of the distal end ₂ The proximal end of' is located at L ₁ The medial aspect of the' is then inwardly angled or displaced, e.g., about the central distal axis L ₂ The proximal end of' is located at L ₁ The outer side of' is then angled or displaced outwardly.

The intraoperative reduction comprises the following operations:

(1.2) if the fractured bone has displacement in the length direction, performing traction reduction operation;

and (2.5) if the fractured bone has the lateral deformity, performing reduction operation on the lateral deformity of the fractured bone. When the reduction is carried out, the far end of the broken bone is reduced, and if the reduction is unsuccessful, the near end of the broken bone is reduced.

According to the lower limb fracture reduction method, when the fracture deformity is evaluated, the contrast standard is established by using the healthy side image of the patient, the fracture deformity is evaluated reversely, the unified reference standard is not set, but the healthy side of the patient is used as the reference standard, the conditions of each patient are compounded according to different people, the influences of factors such as the shooting angle and shooting distance of an X-ray image and the placement of the limbs of the patient are avoided, the evaluation and reduction accuracy is further improved by performing calculation analysis and evaluation through a computer, the postoperative limbs can be guaranteed to have good recovery, and the limbs on both sides are symmetrical.

Example two

There may also be a posterior-anterior deformity following a fracture of a limb, and thus the fracture reduction system also includes the assessment and correction of the anterior-posterior deformity of the fractured bone. The method also includes pre-operative assessment, intra-operative reduction, and post-reduction re-assessment correction.

The preoperative evaluation comprises evaluation on malformation around fractured bones, specifically comprises evaluation on angulation deformity around fractured bones and displacement around fractured bones, and the operation steps comprise:

the patient lies down upwards, the C-arm machine perspectives a side sheet of the operation section and a side sheet of a healthy side symmetrical to the operation section, and transmits the side sheets to the computer operation interface to define four directions of front, back, inner and outer;

(3) assessment of deformity around fractured bone

(3.3) comparing the actual value with the reference value in the computer operation interface, and generating a result, if the difference value between K3 'and K3 is greater than an allowable error value, assessing that the fractured bone has anterior-posterior angulation deformity, if the difference value between K4' and K4 is greater than the allowable error value, assessing that the fractured bone has anterior-posterior displacement, otherwise, no anterior-posterior deformity exists;

(3.4) if there is anterior-posterior angulation and/or anterior-posterior displacement, the computer evaluates anterior or posterior angulation and/or displacement according to a given factor C1.

The method for obtaining the reference values K3 and K4 included in the given element C comprises the following steps:

perspective and operation joint for C-arm machineOn the side position sheet of the healthy side with symmetrical sections, a central axis L of the healthy side near-end bone side direction is made ₃ And a medial axis L lateral to the healthy distal bone ₄ ,L ₃ And L ₄ The intersection angle beta is recorded as a reference value K3, L ₃ And L ₄ Distance L between two points intersecting the fracture line _CD Is noted as reference K4.

making a medial axis L of the lateral direction of the proximal bone of the operation side on a C-arm machine perspective operation section lateral position sheet ₃ ', and axial line L in the lateral direction of the distal bone ₄ ', L3' and L ₄ The ' intersection angle β ' is recorded as the actual value K3 ', L ₃ ' and L ₄ ' distance L between two points intersecting the fracture line _CD 'noted as actual value K4'.

The central axis is obtained by the following method:

In the operation side, the side sheet marked with the central axis on the health side is mirrored on the side sheet on the operation side, and the health side sheet is rotated for the first time to make the health side near end coincide with the operation side near end, at this moment, L ₃ Is at the position of L ₃ ' then, the side healthy slice is rotated for the second time to make the distal healthy end coincide with the distal operative end, at this time, L ₄ Is at the position of L ₄ ’。

In the results generated in the step (3.3), when K3' -K3 is more than 2 degrees, the fractured bone is evaluated to have anterior and posterior angulation deformity; when K4' -K4 > 2mm, the presence of bone fragments was assessed for anteroposterior displacement.

The determination criteria for the given element C1 are, for example, the central axis L of the distal end ₄ The proximal end of' is located at L ₃ The anterior aspect of the' is then angled or shifted anteriorly, e.g., in the direction of the central distal axis L ₄ The proximal end of' is located at L ₃ The posterior side of' is then angled or displaced posteriorly.

The intraoperative reduction comprises the following steps:

and (3.5) if the fractured bone has front and back deformity, resetting the front and back deformity of the fractured bone. When the reduction is carried out, the far end of the broken bone is reduced, and if the reduction is unsuccessful, the near end is reduced.

The re-evaluation includes:

EXAMPLE III

The limb may also be subject to deformity by rotation, and the fracture reduction system may therefore also include assessment and correction of deformity by rotation for reduction of deformity by fracture of the lower limb. The method also includes pre-operative assessment, intra-operative reduction, and post-reduction re-assessment correction.

The preoperative evaluation comprises the evaluation of the deformity of the fractured bone rotation, and the operation steps comprise:

(4.1) establishing a reference standard at the healthy side, and acquiring at least one reference value K5 capable of evaluating whether the fractured bone is in the rotational deformity on the orthostatic sheet at the healthy side by the computer according to the established element D;

(4.2) according to the determined factor D, the computer acquires an actual value K5' corresponding to the reference value K5 on the surgical segment orthotopic sheet;

(4.3) comparing the actual value with the reference value in the computer operation interface and generating a result, if the difference value between K5' and K5 is greater than an allowable error value, evaluating that the fractured bone has rotational deformity, otherwise, not evaluating that the fractured bone does not exist;

and (4.4) if the rotation deformity exists, the rotation deformity exists at the far end can be defaulted, and the pronation or the supination deformity is judged according to the pointing direction of the tiptoe.

The method for obtaining the reference value for evaluating whether the fractured bone is rotationally malformed, which is included in the given element D, comprises the following steps:

The method for acquiring the actual value relative to the reference value, which is contained in the given element D, comprises the following steps:

The intraoperative reduction comprises the following steps:

and (4.5) if the fractured bone has the rotational deformity, performing the reduction operation of the internal rotation or the external rotation deformity. When the reduction is carried out, the far end of the broken bone is reduced, and if the reduction is unsuccessful, the near end is reduced.

The re-evaluation includes:

repeating the pre-operative assessment (4), re-assessing whether there is any anterior-posterior angular deformity of the reduced surgical segment, and repeating the intra-operative reduction (4.5) until the pronation or supination shift is corrected.

Example four

Based on the third embodiment, the method for evaluating the rotation deformity of the fractured bone further comprises or is replaced by:

the computer obtains the distance value L between the inner side end point of the fracture line at the proximal end of the fractured bone and the inner side end point of the fracture line at the distal end of the fractured bone on the C-arm fluoroscopy operation segment correction sheet _{Inner part} Obtaining the distance value L between the outer side end point of the fracture line at the proximal end of the fractured bone and the outer side end point of the fracture line at the distal end of the fractured bone _{Outer cover} And generating a result when L _{Inner part} ≠L _{Outer cover} If so, evaluating that the fractured bone has rotational deformity, otherwise, evaluating that the fractured bone does not exist.

According to any of the disclosed embodiments, during the reduction during the operation, the lower limb traction device described in the Chinese patent application CN201910832613.4 by the applicant can be used for traction reduction, pushing reduction and the like. And during reduction, the healthy side image is used for reversely reducing the fracture far end, if the reverse reduction of the fracture far end is unsuccessful, then the fracture near end is reversely reduced.

The above is only a preferred embodiment of the invention, and any simple modifications, variations and equivalents of the invention may be made by anyone in light of the above teachings and fall within the scope of the invention.

Claims

1. A reduction system for a rotation deformity of a fractured bone of a lower limb fracture, comprising:

a C-arm machine and computer for preoperative evaluation, the system performing the following procedure:

(1) the patient lies down upwards, the C-arm machine perspectives the operation section positioning sheet and the positioning sheet on the healthy side symmetrical to the operation section, and transmits the positioning sheet to the computer operation interface to define four directions of front, back, inner and outer;

(2) the computer begins to evaluate various parameters including the deformity of the fractured bone

Establishing a reference standard on the healthy side, and acquiring at least one reference value K5 capable of evaluating whether the fractured bone is in rotational deformity on the orthostatic sheet on the healthy side by the computer according to the setting of the established element D; wherein

The predetermined element D includes a method for obtaining a reference value K5, and a maximum value L of the width of the knee joint on the healthy side is obtained on the healthy side orthotopic sheet _Knee And the maximum value L of the ankle joint width _{Ankle joint} ；

According to the setting of the determined element D, the computer acquires an actual value K5' corresponding to the reference value K5 on the surgical segment positive position sheet; wherein

The predetermined element D is a method including obtaining a reference value K5', and obtaining a maximum value L of the width of the operative knee joint on the operative segmental orthotopic _Knee ' and maximum value of ankle joint width L _{Ankle joint} ’；

Comparing the actual value with the reference value in the computer operation interface and generating a result, if the difference value between K5' and K5 is larger than an allowable error value, evaluating that the fractured bone has rotational deformity, otherwise, not evaluating that the fractured bone has rotational deformity;

in the generated result, when L is _Knee ’≠L _Knee When the bone is abnormal, the proximal broken bone has a rotation deformity, when L is _{Ankle joint} ’≠L _{Ankle joint} When the bone is broken, the distal broken bone has rotational deformity;

if the rotation deformity exists, the rotation deformity exists at the far end can be defaulted, and the inward rotation or outward rotation deformity is judged according to the direction of the tiptoe;

(3) the system also comprises a lower limb traction device used for intraoperative reduction;

if the fractured bones have rotation deformity, the lower limb traction device performs the reduction operation of the internal rotation or the external rotation deformity;

(4) the C-arm machine, the computer and the lower limb traction device are used for evaluating and resetting again;

repeating the assessment of the preoperative fractured bone rotation deformity, re-assessing whether the reduced operative segment still has the rotation deformity, if the rotation deformity still exists, repeating the intraoperative reduction, and performing the pronation or supination deformity reduction operation by using the lower limb traction device until the pronation or supination displacement is corrected;

in addition, the method for evaluating the rotation deformity of the fractured bone further comprises the following steps:

the computer obtains the distance value L between the inner side end point of the fracture line at the proximal end of the fractured bone and the inner side end point of the fracture line at the distal end of the fractured bone on the operation segment correction sheet _{Inner part} Obtaining the distance value L between the outer side end point of the fracture line at the proximal end of the fractured bone and the outer side end point of the fracture line at the distal end of the fractured bone _{Outer cover} And generating a result when L _{Inner part} ≠L _{Outer cover} If so, evaluating that the fractured bone has rotational deformity, otherwise, evaluating that the fractured bone does not exist.