INORGANIC NANOPARTICLESIZE35 In th

INORGANIC NANOPARTICLE


SIZE
35 In the spirit of the การประดิษฐ์, the term "nanoparticle" refers to a product, in particular a synthetic
product, with a size in the nanometer range, typically between 1 rim and 500 nm.
The term "crystallite" herein refers to a crystalline product. The size of the crystallite and its structure and composition may be analyzed from X-ray diffractogram.
The term "aggregate of crystallites" refers to an assemblage of crystallites strongly, typically covalently, bound to each other.
5 The nanoparticle of the การประดิษฐ์ is typically a crystallite and/or an aggregate of crystallites.
The terms "size of the nanoparticle" and "largest size of the nanoparticle" herein refer to the "largest dimension of the nanoparticle" or "diameter of the nanoparticle". Transmission Electron Microscopy (TEM) can be used to measure the size of the nanoparticle. As well, Dynamic Light
Scattering (DLS) can be used to measure the hydrodynamic diameter of nanoparticles in solution. 10 These two methods may further be used one after each other to compare size measures and confirm
said size. A preferred method is DLS (Ref. International Standard IS022412 Particle Size
Analysis — Dynamic Light Scattering, International Organisation for Standardisation (ISO)
2008).
The largest dimension of a nanoparticle as herein defined is typically between about 5 nm and about 15 250 nm, ที่ควรใช้คือ between about 10 mn and about 100 nm or about 200 nm, ที่ควรใช้กว่านั้นคือ
between about 20 nm and about 150 nm


รูปทรง
As the รูปทรง of the particle can influence its "biocompatibility", particle having a quite homogeneous 20 รูปทรง is preferred. For pharmacokinetic reasons, nanoparticles being essentially spherical, round or
ovoid in รูปทรง are thus preferred. Such a รูปทรง also favors the nanoparticle interaction with or uptake
by cells. Spherical or round รูปทรง is particularly preferred.
Typically, the largest dimension is the diameter of a nanoparticle of round or spherical รูปทรง, or the longest length of a nanoparticle of ovoid or oval รูปทรง.
25
COMPOSITION/STRUCTURE
The inorganic material of the nanoparticle present in the composition ที่ควรใช้คือ has a theoretical
(bulk) density of at least 7 and may be selected from any material exhibiting this property and
identified in the table from Physical Constants of Inorganic สารประกอบ appearing on page 4-43 in 30 Handbook of Chemistry and Physics (David R. Lide Editor-In-Chief,88th Edition 2007-2008).
The inorganic material constituting the nanoparticle is ที่ควรใช้คือ a material having an effective atomic number (Zeff) of at least 25, ที่ควรใช้คือ at least 40 or 41, ที่ควรใช้กว่าคือ at least 50 or 51, ที่ควรใช้กว่าคือ at least 60, 61, 62 or even 63.
35 Effective atomic number is a term that is similar to atomic number but is used for สารประกอบ (e.g.
water) and ของผสมs of different materials (such as tissue and bone) rather than for atoms. Effective
atomic number calculates the average atomic number for a สารประกอบ or ของผสม of materials. It is abbreviated Zeff•
The effective atomic number is calculated by taking the fractional proportion of each atom in the สารประกอบ and multiplying that by the atomic number of the atom. The formula for the effective

5 atomic number,

2.94



Z

eff, is as follows:

Ze f
where
f„ is the fraction of the total number of electrons associated with each element, and Z„ is the atomic number of each element.
10 The atomic number (also known as the proton number) is the number of protons found in the nucleus
of an atom. It is traditionally represented by the symbol Z. The atomic number uniquely identifies a
chemical element. In an atom of neutral charge, atomic number is equal to the number of electrons.
An example is that of water (H20) which is made up of two hydrogen atoms (Z=1) and one oxygen
atom (Z=8). The total number of electrons is 1+1+8 = 10. The fraction of electrons corresponding to 15 the two hydrogens is 2/10 and the fraction of electrons corresponding to the unique oxygen is (8/10).
Z eff of water is therefore:



Zefff . 2 X


12'94

+ 0.8 x 82'94 = 7.42

Z eff participate to the incoming radiations absorption capacity of nanoparticles.


20 The inorganic material constituting the nanoparticle is typically selected from an oxide, a metal, a
sulfide and any ของผสม thereof.
When the inorganic material constituting the nanoparticle is an oxide, this oxide is advantageously
selected from Cerium (IV) oxide (CeO2), Neodynium (III) oxide (Nd203), Samarium (III) oxide
(Sm203), Europium (111) oxide (Eu203), Gadolinium (111) oxide (Gd203), Terbium (III) oxide (Tb203), 25 Dysprosium (III) oxide (Dy203), Holmium oxide (Ho203), Erbium oxide (Er203), Thullium (III) oxide
(Tm203), Ytterbium oxide (Yb203), Lutetium oxide (1u203), Hafnium (IV) oxide (Hf02), Tantalum (V)
oxide (Ta205), Rhenium (IV) oxide (Re02), Bismuth (III) (Bi203). In the context of the present
การประดิษฐ์, a ของผสม of inorganic oxides can also be used to prepare the nanoparticle of the การประดิษฐ์.


30 When the inorganic material constituting the nanoparticle is a metal, this metal is advantageously
selected from gold (Au), silver (Ag), platinum (Pt), palladium (Pd), tin (Sn), tantalum (Ta), ytterbium
(Yb), zirconium (Zr), hafnium (Hf), terbium (Tb), thulium (Tm), cerium (Ce), dysprosium (Dy),
erbium (Er), europium (Eu), holmium (Ho), iron (Fe), lanthanum (La), neodymium (Nd),
praseodymium (Pr), lutetium (Lu) and ของผสมs thereof. In the context of the การประดิษฐ์นี้, 35 ของผสม of metals is also possible. In the context of the การประดิษฐ์นี้, a ของผสม of an inorganic
oxide and of a metal can also be used to prepare the nanoparticle of the การประดิษฐ์.

-

6
When the inorganic material constituting the nanoparticle is a sulfide, this sulfide is ที่ควรใช้คือ silver sulfide (Ag2S).


ELECTRON DENSITY
5 The electron density of the material constituting the nanoparticle (crystallites or aggregates of
crystallites) is the number of electrons per ปริมาตร of material express in electron/cm3 (e-/cm3). The electron density is calculated using the following equation:




P e-material = dmaterial X e material
10
Wherein:
P e-material corresponds to the electron density of the material constituting the nanoparticle, expressed as the number of electron per cm3 (e-/cm3);
d„,„,erid corresponds to the theoretical (bulk) density of the material constituting the 15 nanoparticle (see table Physical Constants of Inorganic สารประกอบ page 4-43, in Handbook of
Chemistry and Physics; David R. Lide Editor-In-Chief, 88th Edition 2007-2008) and is expressed in g/cm3;
e- material corresponds to the number of electron per gram of material constituting the
nanoparticle (see for example table 5.1 page 63, in The Physics of Radiation Therapy Fourth Edition, 20 Faiz M. Khan 2010) and is expressed in electrons/g (e-/g).

When the inorganic material constituting the nanoparticle is a metal, the number of electron per gram of any metallic element may be calculated using the following formula:


25 No=NxZ/A


No = number of electron per gram of the element
N = Avogadro's number
Z = atomic number of the element
30 A = atomic weight of the element


For example:
for gold element, the number of electron per gram is No = 6.022x1023 x 79 / 196.96 = 2.41x1023
for lead element, the number of electron per gram is No = 6.022x1023 x 82 / 207.2 = 2.38x1023
35 for iron element, the number of electron per gram is No = 6.022x1023 x 26 / 55.845 = 2.80x1023



7
For example, for a spherical gold nanoparticle (GNP) with a diameter equal to 100 nm, the electron density of the nanoparticles is 13.9 times the electron density of the corresponding ปริมาตร of water (i.e. a sphere of diameter equal to 100 nm filled with water molecules).


5 P e-GNP 19.3 x 2.41x1023
= 13.9
P e-water 1.0 x 3.34x1023

For example, for a spherical iron nanoparticle with a diameter equal to 100 nm, the electron density of 10 the nanoparticles is 6.6 times the electron density of the corresponding ปริมาตร of water (i.e. a sphere
of diameter equal to 100 nm filled with water molecules).

P e-iranNP dirouNP X eironNP 7.87 x 2.80x1023
— 6.6
15 P a-water dwater. X 6- water 1.0 x 3.34x1023

When the inorganic material constituting the nanoparticle is typically an oxide or a sulfide, the number of electron per gram of any material constituting the nanoparticle may be calculated using the following formula
20
ematerial= N x Zeiement) / M

6 material = number of electron per gram of the material constituting the nanoparticle N = Avogadro's number
25 Zelement = atomic number of each element constituting the material
M = Molecular weight of the material constituting the nanoparticle


For example:
For water molecules, the number of electron per gram is e-watc,. =6.022x1023 x (1+1+8) / 18 =
30 3.34 x1023
For hafnium oxide material, the number of electron per gram is elf#02=6.022x1023 x (72+8+8) / 210.49 = 2.52 x1023
For bismuth oxide material, the number of electron per gram is eBi203=6.022X1023 (83+83+8+8+8) / 465.96 = 2.45 x1023
35 For tantalum oxide material, the number of electron per gram is eTa205=6.022x1023
(73+73+8+8+8+8+8) / 441.9 = 2.53 x1023



8
For cerium oxide material, the number of electron per gram is eceo2=6.022x1023 x (58+8+8) / (172.12) = 2.59 x1023
For example, for a spherical hafnium oxide nanoparticle (Hf02) with a diameter equal to 100 nm, the 5 electron density of the nanoparticles is 7.3 times the electron density of the corresponding ปริมาตร of
water (i.e. a sphere of diameter equal to 100 nm filled with water m