1. Introduction
The rapid development of nanotechnology over the past few decades has led to the approval of multiple nanoparticle (NP)-based drug delivery systems in clinics [
1,
2]. Furthermore, a large number of NPs are undergoing clinical trials or preclinical studies [
3]. These NPs can be roughly divided into organic NPs and inorganic NPs. Among different inorganic materials, calcium carbonate (CaCO
3) NPs have gained much attention due to their excellent biocompatibility and biodegradability, as well as easy preparation and pH sensitivity [
4]. CaCO
3 exists as an amorphous calcium carbonate (ACC) phase, two hydrated metastable phases (calcium carbonate hexahydrate and monohydrocalcite), and three anhydrous crystalline polymorphs (calcite, aragonite, vaterite) [
5]. Among them, ACC phase displays the highest solubility and is the precursor of anhydrous crystalline polymorphs, which is easily crystallized in solutions to form polymorphs [
6].
By the combination of CaCO3 NPs with imaging contrast agents, different imaging modalities such as fluorescence imaging (FLI), magnetic resonance imaging (MRI) and ultrasound (US) imaging could be realized. By the combination of CaCO3 NPs with drugs, diverse treatments including chemical therapy, gene therapy, photothermal therapy (PTT)/photodynamic therapy (PDT) and immunotherapy could be achieved. Furthermore, by the combination of CaCO3 NPs with both contrast agents and drugs, multimodal theranostics could be reached. Therefore, the development of CaCO3 NPs would contribute to the diagnosis, treatment and theranostics of diseases.
In this review, we will first summarize the advantages and preparation methods of CaCO3 NPs. Then, CaCO3 NP-based biomedical applications will be classified in detail. Finally, we will discuss the challenges and recommendations for future studies of CaCO3 NPs.
2. The Advantages of CaCO3 NPs
2.1. Excellent Biocompatibility/Biodegradability and pH-Sensitive Property
In biological systems, calcium carbonate and calcium phosphate are important components of bones, shells or teeth [
7]. Therefore, it is believed that CaCO
3-based drug delivery systems have excellent biocompatibility due to their chemical similarity with tissues. Furthermore, some common NPs such as Au, Ag, Se, Cr, TiO
2 and ZnO have been demonstrated to improve mutation frequency and reactive oxygen species production, thus, leading to cell apoptosis [
8,
9]. In contrast, CaCO
3 NPs are one of the safest biomaterials because their by-products (only Ca
2+ and CO
32−) already exist in the blood.
In addition, CaCO
3 NPs are stable under normal blood pH (7.4) while decompose quickly in an acidic tumor microenvironment, of which facilitates tumor-targeted delivery [
10].
2.2. Ease of Preparation and Surface Modification
The preparation of CaCO
3 NPs only needs common salts without organic solvents in most cases, which makes them low-cost [
11]. Moreover, the surface of CaCO
3 NPs can be modified with targeted moiety, which promotes these CaCO
3 NPs to arrive at the target sites [
12].
3. The Preparation Methods and Controlled Release of CaCO3 NPs
So far, the commonly used preparation methods of CaCO
3 NPs include the precipitation method [
13], gas diffusion [
14], flame synthesis [
15], decomposition of cockle shells [
16], biomineralization and so on [
17,
18]. Among them, solution precipitation, microemulsion and gas diffusion methods have been widely used for CaCO
3 NP-based drug delivery systems.
3.1. Solution Precipitation Method
The solution precipitation method is the most established technique for CaCO
3 NP preparation, which uses the reaction between the Ca
2+ and CO
32− aqueous solution. This method could produce large quantities of CaCO
3 NPs without a surfactant, thus, reducing the production cost. Because of the mild preparation conditions, many bioactive species, including small molecule drugs, genes and proteins, could load into CaCO
3 NPs during the precipitation process [
4]. Notably, the synthesis parameters such as pH, temperature, ion concentration, stirring speed, solvent species and additives are often used to control the size, shape and phase of CaCO
3 NPs [
13].
3.2. Microemulsion Method
As an extension of the precipitation method, the microemulsion methods are widely used for CaCO
3 NP preparation and gene encapsulation [
19,
20]. Microemulsion methods contain the reversed microemulsion (water in oil, W/O) method and double emulsion method. The reversed microemulsion method used the W/O microemulsion droplets as the nano-reactors [
19]. First, “calcium microemulsion” and “carbonate microemulsion” were, respectively, prepared through adding the Ca
2+ or CO
32− aqueous phase into an organic phase. Then, “calcium microemulsion” and “carbonate microemulsion” were mixed to form CaCO
3 NPs. Finally, a centrifuge was used to separate the CaCO
3 NPs. For example, Huang et al. developed CaCO
3 NP loading with the therapeutic peptide by the reversed microemulsion method for lung cancer treatment [
21].
The double emulsion method is similar to the reversed microemulsion method [
20]. Firstly, W/O “calcium microemulsion” was prepared the same as the reversed microemulsion method. Then, a great deal of aqueous phase (consisting of CO
32−) was mixed with “calcium microemulsion” to form the W/O/W double emulsion. CaCO
3 NPs were formed through the Ca
2+ and CO
32− reaction in the W/O/W double emulsion.
In general, through the microemulsion method, the structure, size and crystallinity of CaCO
3 NPs could be regulated by optimizing the surfactants, temperature, pH and ion concentration [
22].
3.3. Gas Diffusion Method
The gas diffusion method is mainly used for preparing ACC loading with small molecule drugs [
14]. As shown in
Figure 1, CaCl
2 was dissolved in ethanol and transferred into a glass bottle. Then, the bottle was left in a desiccator along with another bottle of ammonia bicarbonate. CO
2 and NH
3 were generated from ammonium bicarbonate, then dissolved in the ethanol solution to form CO
32− and NH
4+. Under an alkaline condition caused by NH
4+, CO
32− was reacted with Ca
2+ to form ACC. In this method, the size, shape and polymorph of the prepared ACC could be controlled through changing the additives, temperature and Ca
2+ concentration [
23].
3.4. Controlled Release of CaCO3 NPs
CaCO
3 NPs could improve the pharmacokinetics of loading drugs through a controlled release, thus, reducing the side effects and enhancing the treatment effect. CaCO
3 NPs release the drugs by three ways, including diffusion, carrier dissolution and recrystallization [
24]. pH is the key parameter for the controlled release of CaCO
3 NPs. Under acidic conditions, free protons react with CO
32− to form HCO
3−, then dissolve CaCO
3 NPs and accelerate the release of loading drugs [
25].
4. The Biomedical Applications of CaCO3 NPs
4.1. CaCO3 NPs for Diagnosis
Through combining CaCO
3 NPs with fluorophores or paramagnetic elements (such as Mn
2+, Gd
3+), FLI and MRI could be realized [
26,
27]. Moreover, CaCO
3 NPs themselves can produce CO
2 bubbles under acidic conditions, which can then enhance the US imaging signal. For example, Kim et al. prepared CaCO
3 NPs for US imaging [
28]. After an intravenous injection, the prepared CaCO
3 NPs showed a remarkable US contrast enhancement in the tumor tissue. In addition, Yi and co-workers reported membrane-cloaking nanoconjugates comprising NaGdF
4 and CaCO
3 NPs [
27], which displayed more than a 60-fold contrast enhancement compared with Magnevist (commercially used contrast agent) in tumor MRI (
Figure 2).
4.2. CaCO3 NPs for Treatment
Because of the excellent biocompatibility/biodegradability, pH-sensitive property, ease of preparation and surface modification, CaCO
3 NPs have been widely used as carriers for a variety of treatments including chemical therapy [
29], gene therapy [
21], PTT/PDT [
30] and combination therapy [
31]. Moreover, CaCO
3 NPs themselves could be used as Ca
2+ generators which induce immunogenic cell death (ICD) and autophagy to activate immunotherapy [
12].
4.2.1. CaCO3 NPs as Carriers for Chemical Therapy
CaCO
3 NPs were able to load both hydrophobic and hydrophilic molecules, making them suitable carriers for chemotherapy [
9]. For instance, Wang et al. designed monostearin-coated CaCO
3 NPs for doxorubicin (DOX) loading [
29]. Monostearin coating induced a lipase-triggered DOX release in a lipase-overexpressed tumor site, which improved the drug penetration (
Figure 3).
4.2.2. CaCO3 NPs as Carriers for Gene Therapy
Gene therapy works by substituting or silencing the defective gene to achieve the therapeutic effect [
32]. However, it has been a challenge for nucleic acid delivery due to their negative charge, large size and easy degradation [
33]. CaCO
3 NPs could bind with nucleic acids, making them promising vehicles for gene therapy [
21]. For example, He et al. constructed CaCO
3 NPs for vascular endothelial growth factor small interfering RNA (VEGF siRNA) delivery [
34]. Both in vitro and in vivo results demonstrated that CaCO
3 NPs are a suitable system for siRNA delivery. In another study, Chen et al. synthesized CaCO
3 NPs and modified them with polyethyleneimine (PEI), named as PEI-CaCO
3 NPs, which could be used for p53 gene adsorption [
35]. After transfected, p53-loaded PEI-CaCO
3 NPs significantly decreased the proliferation of tumor cells.
4.2.3. CaCO3 NPs as Carriers for PTT/PDT
PTT and PDT have become promising strategies for cancer therapy because of the noninvasiveness and specific selectivity [
36,
37]. Recently, Xue et al. fabricated a nanocomposite consisting of CaCO
3, indocyanine green (ICG) and polydopamine (PDA), named as Fe
3O
4@PDA@CaCO
3/ICG (FPCI) NPs, which can achieve the combination of PDA-based PTT and ICG-based PDT (
Figure 4) [
30].
4.2.4. CaCO3 NPs as Ca2+ Generators for Immunotherapy
Immunotherapy works by activating the immune system for searching and destroying cancer cells [
38]. CaCO
3 NPs can be used not only as carriers for immunotherapy drugs themselves, but also could increase Ca
2+ concentration, thus, inducing immunogenic cell death (ICD) and autophagy [
39,
40]. Most recently, Zheng et al. prepared polyethylene glycol (PEG)-decorated CaCO
3 NP loading with curcumin (namely,
PEGCaCUR) [
39].
PEGCaCUR NPs can serve as a Ca
2+ nanomodulator to induce Ca
2+ overload, thus, enhancing the ICD effect and eventually inhibiting tumor growth and migration (
Figure 5a). In another study, An et al. designed ovalbumin (OVA)-loaded CaCO
3 (OVA@CaCO
3) NPs as a Ca
2+ nanogenerator to destroy the autophagy inhibition condition in dendritic cells, promote the damage-associated molecular patterns (DAMPs) and release and upregulate the pH of the tumor microenvironment (
Figure 5b) [
40].
4.2.5. CaCO3 NP-Based Combination Therapy
Combination therapy is able to notably decrease multidrug resistance and increase efficiency [
41]. CaCO
3 NPs are commonly used for the co-delivery of chemotherapeutics and gene drugs, which realized the combination of chemotherapy and gene therapy [
31]. For example, Xiang’s group designed a lipid-coated CaCO
3 NPs for the co-delivery of sorafenib and miR-375 (miR-375/Sf-LCC NPs,
Figure 6a) [
42]. Both in vitro and in vivo results proved that miR-375/Sf-LCC NPs are promising carriers for combination therapy. In another study, Kong et al. developed gold nanorods@CaCO
3 NPs coated with dextran and phospholipid for the incorporation of different molecules, including DOX, 17-(allylamino)-17-demethoxygeldanamycin, afatinib and amylase (
Figure 6b) [
43]. This platform has great potential for the combination of PTT and chemotherapy.
4.3. CaCO3 NPs for Theranostic
The therapeutic effect could be significantly improved through the rational design of novel theranostic platforms with both imaging and treatment functions [
44]. CaCO
3 NPs have shown potential in both diagnosis and therapy, which encourages researchers to design theranostic CaCO
3 NPs for achieving imaging-guided treatment [
4]. Specifically, CaCO
3 NP-based theranostic platforms can be classified as three types according to the imaging mode, including US imaging-guided therapy [
45], FLI-guided therapy [
46] and MRI-guided therapy [
47].
4.3.1. US Imaging-Guided Therapy
CaCO
3 NPs can generate CO
2 bubbles and display potential as a US contrast agent in the acidic tumor microenvironment. As a typical paradigm, Min et al. developed DOX-loaded CaCO
3 NPs that express US imaging and chemotherapy for cancer theranostics (
Figure 7a) [
45]. These NPs displayed a strong echogenic signal and long echo persistence, as well as a simultaneous DOX release at the tumor site, which exhibited efficient antitumor effects guided by US imaging. Recently, Feng and co-workers reported CaCO
3 NP loading with hematoporphyrin monomethyl ether (HMME, a sonosensitizer) [
48]. Under US irradiation, generated CO
2 bubbles could lead to cavitation-mediated necrosis and be used as US contrast agents. Meanwhile, HMME can produce reactive oxygen species for sonodynamic therapy (
Figure 7b). These nanoplatforms provided the US imaging-guided cavitation/sonodynamic combined therapy, which highlighted the possibility of cancer theranostics.
4.3.2. FLI-Guided Therapy
CaCO
3 NPs could be constructed as FLI-guided therapy nanoplatforms through the co-delivery of FLI contrast and therapeutic agents. For example, Huang et al. designed a theranostic CaCO
3 NP encapsulation with DOX and fluorescence contrast agent indocyanine green (ICG) for chemotherapy and fluorescence/US dual-mode imaging [
46]. The prepared CaCO
3 NPs showed a satisfactory treatment effect guided by dual-mode imaging, which demonstrated a promising strategy for dual-mode theranostics.
4.3.3. MRI-Guided Therapy
CaCO
3 NPs can also load with MRI contrast and therapeutic agents for realizing MRI-guided therapy. For instance, Gorin’s group prepared a CaCO
3 NP-capsuling paramagnetic element (Fe
3O
4) and DOX, which could be used for an MRI/photoacoustic imaging-guided precise drug release [
47].
5. The Challenges and Recommendations for Future Studies of CaCO3 NPs
Although CaCO3 NPs have been widely investigated for diverse biomedical applications including diagnosis, treatment and theranostics due to their excellent biocompatibility/biodegradability and pH-sensitive property, as well as their ease of preparation and modifications, there are still several challenges that need to be addressed for clinical translation.
First, long-term potential risks of CaCO
3 NPs need to be noticed [
49,
50]. Although calcium is an essential element in humans, overloaded calcium could induce thrombosis, hypercalcemia and other potential dangers [
51]. Furthermore, the most recent studies only evaluated the short-term toxicity of mice through describing organ damage and immune responses after a CaCO
3 NP injection, which was obviously insufficient for a biosafety evaluation. Thus, for the clinical translation of CaCO
3 NPs, it is necessary to systematically assess the long-term effects of CaCO
3 NPs from rodent models to mammalian models [
4].
Second, the present preparation processes of CaCO
3 NPs are instable, which easily leads to large particles [
9]. Thus, it is necessary to design precise methods for size control, components, and surface modifications, sequentially achieving a large-scale production of CaCO
3 NPs.
Third, the drug release kinetics from CaCO3 NPs is difficult to predict. Although the pH-sensitive property of CaCO3 NPs has been widely studied, their release under a normal pH has not been evaluated in detail.
6. Conclusions
In summary, CaCO3 NPs have great potential in biomedical applications due to their excellent properties, such as biocompatibility/biodegradability, pH-sensitivity, ease of preparation and surface modifications. Although much has been carried out, more efforts are still needed to solve the above challenges. We believe that more efficient CaCO3 NPs will be developed as safe carriers for the diagnosis, treatment and theranostics of diseases.
Author Contributions
Conceptualization, P.Z. and Y.L.; writing—original draft preparation, P.Z.; writing—review and editing, Y.T., J.Y., X.H. and Y.L.; funding acquisition, P.Z. and Y.L. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by Natural Science Foundation of China grants grant (No. 82102080), Natural Science Foundation of Hubei Province in China (2021 CFB336).
Conflicts of Interest
The authors disclose no conflict.
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