IT202100026987A1 - SAMPLE HOLDER FOR A DEVICE FOR SURFACE PLASMON RESONANCE MEASUREMENTS, AND RELATED DEVICE FOR SURFACE PLASMON RESONANCE MEASUREMENTS - Google Patents

Description

Title: ?Specimen holder for a device for surface plasmon resonance measurements, and related device for surface plasmon resonance measurements?

DESCRIPTION

Technical field

This invention? relating to a sample holder for a device for surface plasmon resonance measurements.

Furthermore, ? the object of the present invention is a device for surface plasmon resonance measurements including the aforementioned sample holder.

The object of the present invention is used in the sector of technologies for chemical and biochemical analyses, in particular for the detection of specific chemical and biochemical species.

State of the art

The development of innovative measurement devices, benefiting from phenomena such as surface plasmon resonance (SPR) and localized SPR (LSPR), is becoming increasingly popular. spreading in the community? science in recent decades.

Plasmons are coherent oscillations of free electrons that propagate at the interface between a dielectric medium and a thin metal film (nanofilm). In particular, the excitation of the surface plasmon, by means of light, is described as a surface plasmon resonance (SPR) for planar surfaces or localized SPR (LSPR) for nanometric-sized metallic structures.

Known measurement devices that exploit the physical phenomenon of surface plasmon resonance (SPR) include an optical fiber connected at the end opposite with a light source and a spectrophotometer via respective connectors. In use, the light source generates a beam of light which, transported by the optical fibre, reaches the spectrophotometer which will analyze it. the properties? optics.

In detail, the optical fiber has a measurement section, interposed with the light source and the spectrophotometer. To the optical fiber, in correspondence with the measurement section, ? fixed to a support body configured to receive a chemical or biochemical sample to be analyzed.

The optical fiber and its support body are disposable, i.e. they are used for a single chemical or biochemical analysis and subsequently thrown away. Therefore, for each measurement, replacement operations of the optical fiber and its support body are necessary.

It should be noted that the optical fibre, due to its geometric characteristics and the materials used for its construction, tends to break or be damaged under the action of small stresses; therefore, its handling and installation requires particular attention, delicacy as well as? user experience.

? It is therefore clear that the continuous operations of connecting the optical fiber to the light source and to the spectrophotometer using related connectors, in addition to requiring specialized personnel, significantly increase the set-up times of the measurement devices that exploit the physical phenomenon of surface plasmon resonance.

Purpose of the invention

In this context, the task of the technician behind the present invention is? propose a sample holder for a device for surface plasmon resonance measurements and related device for surface plasmon resonance measurements that overcomes the above-mentioned drawbacks of the prior art.

In particular, ? The aim of the present invention is to make available a sample holder for a device for surface plasmon resonance measurements capable of facilitating the multiple operations of insertion and extraction of the optical fiber into the measurement device, thus? that can be carried out by any operator.

Furthermore, ? The aim of the present invention is to provide a practical and easy-to-use device for plasmon resonance measurements. In other words, ? the aim of the present invention is to provide a device that does not require long set-up operations in preparation for the measurement.

SUMMARY OF THE INVENTION

? object of the present invention is a sample holder for a device for surface plasmon resonance measurements in accordance with the preamble of claim 1.

This sample holder comprises an optical fiber extending along a direction of prevalent extension between a first and a second end. The first and second ends? they define respectively a first and a second connection zone, and are configured to be placed in optical communication with a respective terminal of the device for surface plasmon resonance measurements.

Furthermore, the sample holder includes a support body defining a detection area and presenting a support surface suitable for receiving the chemical sample to be analyzed. In detail, the support body ? fixable to the optical fiber along the direction of prevalent extension between the first and second ends.

The sample holder object of the present invention also includes a coupling body extending between the first and second connection areas passing through the detection area.

In detail, the coupling body ? connectable to the support body in correspondence with the detection area, and includes anchoring means configured to anchor the sample holder to the device for surface plasmon resonance measurements.

Advantageously, during replacement operations, the operator does not come into direct contact with the optical fiber and risks damaging it, but moves it through the sample holder. In detail, during replacement operations, the operator grabs the sample holder which, thanks to the anchoring means, is configured to be conveniently connected to the device for surface plasmon resonance measurements. Therefore, the sample holder object of the present invention is? capable of facilitating optical fiber replacement operations.

Furthermore, ? object of the present invention is a device for surface plasmon resonance measurements in accordance with the preamble of claim 7.

The device for surface plasmon resonance measurements includes a main body that can be connected to the sample holder indicated above and has a cavity shaped to accommodate this sample holder.

Furthermore, the device object of the present invention includes a first and a second terminal respectively configured to be put into optical communication with the first and second ends. of the optical fiber of the sample holder. In particular, the first terminal ? designed to generate a light beam passing through the cavity? of the main body, while the second terminal is? suitable for analyzing the light beam generated by this first terminal.

The device for surface plasmon resonance measurements also includes a launch optical fiber and a receive optical fiber.

Does the launch fiber optic extend inside the cavity? of the main body along a longitudinal direction between a first end, facing the first terminal to receive said light beam, and a second end that can be optically connected to the first end? of the optical fiber of the sample holder.

Does the receiving fiber optic extend inside the cavity? of the main body along the longitudinal direction between a third end, which faces the second terminal to convey the light beam onto it, and a fourth end which can be optically connected to the second end? of the optical fiber of the sample holder.

In detail, the second end of the launch optical fiber and the fourth end of the reception optical fiber are spaced along the longitudinal direction by a cavity suitable for receiving the sample holder.

The device for surface plasmon resonance measurements further comprises gripping means configured to be complementary to the anchoring means of the sample holder so as to fix the position of the sample holder inside the cavity. of the main body.

Advantageously, the gripping means being configured to connect complementary to the anchoring means of the sample holder allow the optical fiber of the sample holder to be put into light signal communication with the launching and receiving optical fibre. In particular, they allow the second end of the launch optical fiber and the fourth end of the receiving optical fiber to face and align respectively with the first end and the second end of the sample holder optical fibre.

? It is therefore clear that the gripping means, by connecting complementary to the anchoring means of the sample holder, make it possible to facilitate and ensure the correct positioning of the optical fiber inside the measuring device, speeding up the set-up operations.

LIST OF FIGURES

Further characteristics and advantages of the present invention will appear clearer from the indicative, and therefore non-limiting, description of a preferred but not exclusive embodiment of a sample holder for a device for surface plasmon resonance measurements and of a related device for resonance measurements surface plasmonics, as illustrated in the attached drawings in which:

- Figure 1 shows a perspective view of a sample holder for a device for surface plasmon resonance measurements in accordance with the present invention;

- Figure 2 shows a view from the front of the sample holder in figure 1;

- Figure 3 shows a view from the side of the sample holder in Figure 1;

- Figure 4 shows a bottom view of the sample holder in Figure 1;

- Figure 5 shows a perspective view of a device for surface plasmon resonance measurements in accordance with the present invention;

- Figure 6 shows a top view of the device for surface plasmon resonance measurements of Figure 5 together with the sample holder of Figure 1.

DETAILED DESCRIPTION

The present invention relates to a sample holder 1 for a device 100 for surface plasmon resonance measurements usable in biochemical chemical analyses, for example for the detection of particular chemical or biochemical species in a chemical or biochemical sample.

This device 100 ? represented in figures 5 and 6, and includes a main body 101 presenting a cavity? 111 suitable to accommodate the sample holder 1. In detail, the cavity? 111 ? accessible by means of an opening 111a which can be selectively opened and closed, at least partially, by means of a lid 112. Preferably, the lid 112 is constrained in rotation to the main body 101 by means of one or more? hinges, however in alternative embodiments it can be of the interlocking type.

The device 100 which is the subject of the present invention also includes a first terminal 102 configured to generate a light beam passing through the cavity. 111 of the main body 101, and a second terminal 103 configured to analyze the properties? of the light beam generated by the first terminal 102.

Preferably, the first terminal 102 comprises a light source and the second terminal 103 a spectrophotometer.

As shown in figures 5 and 6, the device 100 which is the subject of the present invention also includes a launch optical fiber 104 and a receiving optical fiber 105, both extending inside the cavity. 111 along a Y-Y longitudinal direction.

In detail, the launch optical fiber 104 extends between a first end 104a, which faces the first terminal 101 to receive the light beam, and a second end 104b which can be optically connected to the sample holder 1.

Otherwise, the receiving optical fiber 105 extends between a third end 105a, which faces the second terminal 103 to convey the light beam onto it, and a fourth end 105b which can be optically connected to the sample holder 1.

As shown in figure 5, the second end 104b of the launch optical fiber 104 and the fourth end 105b of the reception optical fiber 104 are spaced along the Y-Y longitudinal direction by a cavity 106 suitable for receiving the sample holder 1.

More details on connecting the sample holder 1 to the device 100 will be provided in a later part of the description.

As shown in figures 3 and 4, the sample holder 1 object of the present invention comprises an optical fiber 2, preferably plastic, extending along a direction of predominantly X-X extension between a first end 2nd and a second end? 2b.

In detail, the first and second extremities? 2a, 2b define respectively a first and a second connection zone C1, C2 in correspondence with which the optical fiber 2? placed in optical connection with the device 100. In greater detail, the first and second ends? 2a, 2b of the optical fiber 2 are configured to be placed in optical communication respectively with the first and second terminals 102, 103 of the device 100 by means of the launching 104 and receiving 105 optical fibre.

With reference to figures 5 and 6, can we? note that when the sample holder 1 ? inserted in the cavity 106, the second end 104b of the launch optical fiber 104 is optically connected to the first end? 2a of the optical fiber 2 in correspondence with the first connection area C1, while the fourth end 105a of the receiving optical fiber 105? optically connected to the second end? 2b of the optical fiber 2 in correspondence with the second connection area C2.

Therefore, when sample holder 1 ? inserted into the cavity 106, the optical fiber 2 is optically connected from opposite sides to the first and second terminals 102, 103 respectively by means of the launching and receiving optical fiber 104, 105. In other words, when the sample holder 1 is inserted in the cavity 106, the launch optical fiber 104, the optical fiber 2 of the sample holder 1, and the receiving optical fiber 105 are arranged in series to convey the light beam generated by the first terminal 102 onto the second terminal 103.

Preferably, but not necessarily optical fiber 2 of protample 1? of the multimodal type and has a high numerical aperture. Even more? preferably, to ensure good communication with the terminals 102, 103, the optical fiber 2 of the sample holder 1 has: an acrylic substrate, a numerical aperture between 0.40 and 0.55, a refractive index of the core between 1.45 and 1.58, a cladding refractive index of 1.40 to 1.42, a core diameter of 950 ?m to 1400 ?m, and a cladding diameter of 1000 ?m to 1500 ?m .

Furthermore, preferably, in order to obtain good optical communication with the optical fiber 2 of the sample holder, the launching and receiving optical fibers 104, 105 are of the multimode type and have a high numerical aperture. Even more? preferably, the launch and reception optical fiber 104, 105 have: a numerical aperture between 0.33 and 0.55, a core refractive index between 1.45 and 1.58, a cladding refractive index between 1 .40 and 1.42, a core diameter between 950 ?m and 1400 ?m, and a cladding diameter between 1000 ?m and 1500 ?m.

As shown in figures 1 and 3, the sample holder 1 also includes a support body 3 which can be fixed to the optical fiber 2 along the direction of prevalent extension X-X between the first and second ends. 2a, 2b. Preferably, the support body 3? fixed to the optical fiber 2 at its intermediate section, equidistant from the first and second ends? 2a, 2b, having a ?D?-shaped cross section. Such a ?D?-shaped cross section can? be obtained from the traditional ?O? cross section of the optical fiber 2, for example, through the mechanical lapping process that can be used to obtain a flat surface in the intermediate section of the optical fiber 2.

The support body 3 defines a detection zone R in correspondence with which ? arranged the chemical or biochemical sample to be analyzed. ? it is good to specify that the detection area R? to be understood as the region in correspondence with which the measurement takes place aimed at detecting one or more chemical or biochemical substances present in the chemical or biochemical sample to be analyzed.

In detail, with reference to figure 1, the support body 3 includes a support surface 30 suitable for receiving the chemical or biochemical sample to be analyzed and holding it in correspondence with the detection zone R. Preferably, the support body 3 includes a first and a second support surface 30 arranged on opposite sides of the optical fiber 2.

In the embodiment shown in figures 1-4, the support body 3 is essentially a right prism, however there? does not exclude that in alternative embodiments it may present different geometries.

As shown in figures 1 and 3, the sample holder 1 which is the object of the present invention also includes a coupling body 4 which can be connected to the support body 3 in correspondence with the detection zone R.

In detail, the coupling body 4 extends between the first and second connection zones C1, C2 passing through the detection zone R. Preferably, the coupling body 4 has a central portion 4a arranged in correspondence with the detection zone R and connectable to the support body 3, and a pair of peripheral portions 4b arranged on opposite sides of the central portion 4a along the direction of prevalent extension X-X of the optical fiber 2.

Preferably, as shown in figure 3, when the coupling body 4? connected to the support body 3, the optical fiber 2 is blocked between the support body 3 and the coupling body 4, so as to be at least partly arranged in correspondence with the support surface 20 of the support body 3. Therefore, in I use fiber optic 2 you will find? in proximity? of the chemical or biochemical sample to be analyzed which, in accordance with the above, is? arranged on the support surface 30.

Even more? preferably, as shown in figures 2 and 3, the coupling body 4 includes a pair of fins 45 arranged in correspondence with the detection zone Z and connectable to the support body 3 to hold it from opposite sides. In detail, the support body 3 and the fins 45 have complementary geometries designed to be reversibly connectable.

Furthermore, the coupling body 4 includes anchoring means 40 configured to anchor the sample holder 1 to the device 100, as shown in figure 6.

? It is important to specify that the term anchoring means constraining/blocking the relative motion of the sample holder 1 with respect to the device 100. More details on the attachment of the sample holder 1 to the device for surface plasmon resonance measurements 100 will be provided in a subsequent part of the description.

With reference to figures 1-3, preferably, the anchoring means 40 comprise a first and a second covering portion 41a, 41b which can be respectively associated with the first and second ends? 2a, 2b of the optical fiber 2. The first and second covering portions 41a, 41b are configured to cover, at least partially, a respective portion 20a, 20b of optical fiber 2.

Advantageously, the anchoring means 40 by means of the first and second covering portions 41a, 41b allow the integrity of the device to be preserved. of the optical fiber 2, protect it from possible impacts or contact with external bodies. ? It is therefore clear that the operator, during the phases of replacing the optical fiber 2 between one chemical or biochemical analysis and the next, can operate more? easily and quickly without having to worry too much about damaging the optical fiber 2.

Even more? preferably, the first and second covering portions 41a, 41b of the anchoring means 40 extend along the direction of prevalent extension X-X of the optical fiber 2 respectively from opposite sides of the detection zone R. In detail, the first and second portions covers 41a, 41b extend into a respective peripheral portion 4b of the coupling body 4.

With reference to figures 1 and 3, preferably, the coupling body 4 comprises a channel 42 extending at least between the first and second connection areas C1, C2. In other words, the channel 42 extends along the direction of prevalent extension X-X of the optical fiber 2 between the first and second ends? 2a, 2b.

As shown for example in figure 4, the channel 42 includes a first section 42a suitable for accommodating a first portion 20a of optical fiber 2 comprising the first end 2a, and a second section 42b suitable for receiving the second portion 20b of optical fiber 2 comprising the second end? 2b.

In a possible embodiment of the sample holder 1 object of the present invention, the first and second sections 42a, 42b of the channel 42 are respectively obtained in the first and second covering portions 41a, 41b.

With particular reference to figure 3, each covering portion 41a, 41b includes a covering wall 43a, 43b defining the respective section 42a, 42b of the channel 42. These covering walls 43a, 43b extend along the direction of prevalent extension X-X of the optical fiber 2, and have a concave conformation suitable for receiving the respective portion 20a, 20b of optical fiber 2.

Preferably, each covering portion 41a, 41b has an insertion opening 44a, 44b configured to allow access to the respective section 42a, 42b of the channel 42. In detail, each insertion opening 44a, 44b extends along the prevailing direction X-X extension of the optical fiber, and ? oriented so as to face the respective covering wall 43a, 43b. ? It is important to specify that the insertion openings 44a, 44b are configured to allow the insertion of each portion 20a, 20b of optical fiber 2 in the respective section 42a, 42b of the channel 42. In particular, they are configured to allow the insertion of the portions 20a , 20b of optical fiber 2 along an insertion direction Z-Z oriented transversely to the direction of prevalent extension X-X.

Further details on the device 100 configured to be coupled to the sample holder 1 will now be provided below.

With reference to figure 6, the device 100 includes gripping means 107 configured to be connected to the anchoring means 40 of the sample holder 1, so as to fix the position of the sample holder 1 inside the cavity. 111 of the main body 101.

In detail, the gripping means 107 of the device 100 have a geometry complementary to that of the anchoring means 40 of the sample holder 1, so that they can be coupled together.

In a possible embodiment of the present invention, the gripping means 107a of the device 100 comprise a first wall 107a and a second wall 107b extending along the Y-Y longitudinal direction. The first and second walls 107a, 107b are spaced along the Y-Y longitudinal direction from the interspace 106.

Preferably, the first and second walls 107a, 107b are respectively configured to support launch optical fiber 104 and reception optical fiber 105. In particular, the first and second walls 107a, 107b have respective grooves extending along the Y-Y longitudinal direction suitable for accommodating the launch optical fiber 104 and the receiving optical fiber 105 respectively.

As shown in figure 6, the first and second walls 107a, 107b respectively include a first and a second excavation 117a, 117b arranged in correspondence with the cavity 106 and configured to accommodate within them the anchoring means 40 of the anchoring body 4 of the sample holder 1. Pi? precisely, the first and second excavations 117a, 117b are configured to accommodate the first and second covering portions 41a, 41b of the anchoring means 40.

? It is worth specifying that when the anchoring means 40 of the anchoring body 4 are inserted into the respective excavations 117a, 117b of the first and second walls 107a, 107b, the sample holder 1 occupies the cavity 106 and its movement with respect to the main body 101? inhibited, at least along the longitudinal Y-Y direction and a transverse T-T direction orthogonal to the longitudinal Y-Y direction. As shown in Figure 6, the Y-Y longitudinal direction and the T-T transverse direction are arranged in a plane parallel to the plane in which the cavity opening 111a lies. 111 of the main body 101.

Preferably, the device 100 includes compression means 108 configured to act on the anchoring means 40 of the coupling body 4 to press the sample holder 1 inside the cavity 111. In detail, the compression means 108 act along an insertion-extraction direction P-P orthogonal to the plane in which the opening 111a lies.

? it is good to specify that the insertion-extraction direction P-P? perpendicular to both the longitudinal direction X-X and the transversal direction T-T, as it is orthogonal to the plane in which the opening 111a lies.

Even more? preferably, as shown in figure 5, the compression means 108 are arranged on the lid 112. In a possible embodiment, the compression means are protrusions projecting from the lid 112. In detail, these protrusions, when the lid is placed to close the opening 111a, they are configured to block the movement of the sample holder 1 along the P-P insertion-extraction direction by acting directly on the first and second covering portions 41a, 41b of the anchoring means 40.

Preferably, the gripping means 107 are configured to face and align: the second end 104b of the launch optical fiber 104 at the first end? 20 of the optical fiber 2 of the sample holder 1; and the fourth end 105b of the receiving optical fiber 105 at the second end? 2b of the optical fiber 2 of the sample holder 1.

Even more? preferably, the gripping means 107 are configured to arrange in a linear manner the direction of prevalent extension X-X of the optical fiber 2 of the sample holder 1 and the longitudinal direction Y-Y along which the launching and receiving optical fiber 104, 105 extend. in other words, the gripping means 107 of the device 100, when coupled with the anchoring means 40 of the sample holder, are configured to arrange the launch optical fiber 104, the optical fiber 2 of the sample holder 1, and the receiving optical fiber 105 l ?one in proximity? of the other and oriented along the same direction.

In use, the light beam generated by the first terminal 102 enters the optical fiber 2 of the sample holder 1 through the first end 2a and, after having entirely crossed the optical fiber 2 itself, ? released towards the second terminal 103 from the second end? 2b. ? it is good to specify that, when the light beam passes through the optical fiber 2 from the first to the second end? 2a, 2b, passes through the detection zone Z where, due to the presence of the chemical or biochemical sample to be analysed, it will change? their own properties? optics.

Claims (10)

1. Sample holder (1) for a device (100) for surface plasmon resonance measurements, said sample holder (1) comprising: - an optical fiber (2) extending along a direction of prevalent extension (X-X) between a first and a second end? (2a, 2b), the first and second ends? (2a, 2b) defining respectively a first and a second connection zone (C1, C2) and being configured to be placed in optical communication with a respective terminal (102, 103) of the device (100); - a support body (3) defining a detection zone (R) and presenting a support surface (30) suitable for receiving the chemical or biochemical sample to be analysed, the support body (3) being fixable to the optical fiber (2 ) along the direction of prevailing extension (X-X) between the first and second extremities? (2a, 2b); characterized by the fact of comprising a coupling body (4) extending between the first and second connection zones (C1, C2) passing through the detection zone (R), called coupling body (4): - being connectable to the support body (3) in correspondence with the detection area (R); - comprising anchoring means (40) configured to anchor the sample holder (1) to the device (100). 2. Sample holder (1) in accordance with claim 1, in which the anchoring means (40) comprise a first and a second covering portion (41a, 41b) respectively associatible with the first and second ends? (2a, 2b) of the optical fiber (2), called first and second covering portions (41a, 41b) extending along the direction of prevalent extension (X-X) of the optical fiber (2) respectively from opposite parts of the detection zone (R ). 3. Sample holder (1) in accordance with any of the previous claims in which the coupling body (4) includes a channel (42) extending at least between the first and second connection areas (C1, C2), said channel (42 ) including: - a first section (42a) suitable for accommodating a first portion (20a) of optical fiber (2) including the first end? (2a); And - a second section (42b) suitable for accommodating a second portion (20b) of optical fiber (2) including the second end? (2b). 4. Sample holder (1) according to claim 3, wherein each section (42a, 42b) of the channel (42) is: - defined by a concave covering wall (43a, 43b) of the respective covering portion (41a, 41b) configured to receive the respective portion (20a, 20b) of the optical fiber (2), said covering wall (43a, 43b) developing along the direction of prevalent extension (X-X) of the optical fiber (2); - accessible by means of an insertion opening (44a, 44b) of the covering portion (41a, 41b), said insertion opening (44a, 44b) facing the respective covering wall (43a, 43b) and being configured to allow the insertion of each portion (20a, 20b) of optical fiber (2) in the respective section (42a, 42b) of the channel 42. 5. Sample holder (1) according to any of the previous claims wherein, when the coupling body (4) is? connected to the support body (3), the optical fiber (2) is lockable between the support body (3) and the coupling body (4) so as to be at least partly arranged in correspondence with the support surface (30) of the support body (3). 6. Sample holder (1) in accordance with any of the previous claims in which the coupling body (4) includes a pair of fins (45) arranged in correspondence with the detection zone (Z) connectable to the support body (3) for hold it from opposite sides. 7. Device (100) for surface plasmon resonance measurements (100) comprising: - a main body (101) presenting a cavity? (111); - a first terminal (102) capable of generating a light beam passing through the cavity? (111) of the main body (101), said first terminal (102) being configured to be put into optical communication with a first end? (2a) of an optical fiber (2) of a sample holder (1) according to any of the previous claims at a first connection area (C1); - a second terminal (103) capable of analyzing said light beam generated by the first terminal (102), said second terminal (103) being configured to be put into optical communication with a second end? (2b) of the optical fiber (2) of the sample holder (1) in correspondence with a second connection area (C2); - a launch optical fiber (104) extending inside the cavity? (111) along a longitudinal direction (Y-Y) between a first end (104a), which faces the first terminal (101) to receive said light beam, and a second end (104b) which can be optically connected to the first end? of the optical fiber (2a) of the sample holder (1); - a receiving optical fiber (105) extending inside the cavity? (111) along the longitudinal direction (Y-Y) between a third end (105a), which faces the second terminal (103) to convey the light beam onto it, and a fourth end (105b) which can be optically connected to the second end? (2b) of the optical fiber (2) of the sample holder (1), said second end (104b) of the launch optical fiber (104) and fourth end (105b) of the receiving optical fiber (104) being spaced along the longitudinal direction ( Y-Y) from a cavity (106) suitable for receiving the sample holder (1); characterized by the fact of understanding: - gripping means (107) configured to be additionally connected to anchoring means of the sample holder (40) so as to fix the position of the sample holder (1) inside the cavity? (111) of the main body (101). 8. Device (100) in accordance with the previous claim, in which the gripping means (107) are configured to arrange in a collinear manner the direction of prevalent extension (X-X) of the optical fiber (2) of the sample holder (1) and the longitudinal direction (Y-Y) along which the launch and reception optical fiber extend (104, 105). Device (100) according to claim 7 or 8, wherein the gripping means (107) comprise: - a first wall (107a) presenting a first excavation (117a) capable of accommodating inside it a first covering portion (41a) of the anchoring means (40) of the sample holder (1); - a second wall (107b) presenting a second excavation (117b) capable of accommodating inside it a second covering portion (41b) of the anchoring means (40) of the sample holder (1). 10. Device (100) according to any one of claims 7 to 9, wherein the launching and receiving optical fibers (104, 105) comprise numerical apertures between 0.33 and 0.55.