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Received 00th January 20xx, 

Accepted 00th January 20xx 

DOI: 10.1039/x0xx00000x 

www.rsc.org/ 

Self-Immolative Polymers as novel pH-responsive gate keepers for 

drug delivery   

M. Gisbert
a,b

 , D. Lozano
a,b

, M. Vallet-Regí
a,b

 * and M. Manzano
a,b

  *

A novel pH-sensitive nanocarrier based on mesoporous silica 

nanoparticles with self-immolative polymers blocking the pore 

openings is presented. Triggered release by acid pH is 

demonstrated, together with their in vitro biocompatibility and 

effective cell internalisation, which makes this new material a 

promising candidate for future applications in cancer treatment.  

Nanotechnology, which has the potential to impact nearly 

every area of modern society, is transforming medicine thanks 

to the development of new smart drug delivery systems.1–3 

Those nanocarriers are expected to bring breakthroughs in 

terms of detecting, diagnosing and treating different forms of 

cancer.4 Recently, Mesoporous Silica Nanoparticles (MSNs) 

have drawn much attention for many biomedical applications, 

especially as drug delivery nanocarriers.5–10 The reason for that 

relays on their unique properties, such as a straightforward 

synthesis, a network of cavities ready available to be filled with 

different payloads, tuneable pore diameters and 

morphologies, facile surface functionalisation and hemo- and 

biocompatibility.11,12 

The textural properties of MSNs, such as large surface areas 

(ca. 1000 m2g-1) and large pore volume (ca. 1 cm3g-1), are 

responsible for their high loading capacities. In fact, 

conventional polymeric nanoparticles suffer from the 

drawback of low drug capacity, usually less than 5% of total 

weight, while MSNs allow much greater values.13,14 

However, MSNs present an open structure of the pores, which 

means that is simple to introduce molecules into their network 

of cavities, but it is also easy for them to diffuse out. This is the 

main reason to place gatekeepers on the entrance of the 

pores, so they can be closed once the cargo is loaded, and 

then opened to allow the drug release. The former process can 

be carried out during the production of the nanocarrier, but 

the later event, opening the gates of the pores, must be done 

on-demand inside the body. This approach leads to stimuli-

responsive nanocarriers,
15

 in which the release of the cargo is 

triggered by a stimulus than can be exogenous (temperature, 

light, magnetic fields or ultrasounds) or endogenous (pH, 

redox potential or specific enzymes or analytes). Those 

systems allow tailoring the release profiles with temporal and 

dosage control. 

Among the available stimuli, pH variations offer the possibility 

of controlling the delivery of drugs to different regions of the 

body such as the gastrointestinal tract, the endosomes or 

lysosomes, or the tumour microenvironment. In particular, the 

slightly acidic lysosomal pH value (4.5-5)
16

 has been used for 

the design of pH-targeted nanocarriers that release their cargo 

once inside the cell.
17,18

 Then, an efficient pH-responsive 

system should respond to this subtle change of pH within this 

organelle, triggering the release of the cargo only inside the 

cells (Scheme 1).  

Scheme 1. Representation of the operating principle of our pH 

sensitive nanocarrier. A change in the pH initiates the dissassembling 

of the self-immolative polymer allowing cargo molecules to diffuse out 

of the MSNs. 

There are many polymeric systems with acid-sensitive bonds 

that can be exploited for designing responsive systems. In this 

sense, there are a new class of polymers, the so-called Self-

Immolative Polymers (SIPs), that disassemble from head to tail 

completely when a specific functional group is cleaved from 

the polymer in response to certain stimuli.19,20 One potential 

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advantage is that it is possible to incorporate prodrugs into the 

polymer chain as pendant groups. These groups would turn 

into actual drugs as the self-immolation takes place.
21

 It is also 

possible to modify the rate at which the chain disassembles to 

achieve a more controlled and sustained drug release.
22

 There 

are many triggers that can initiate the fragmentation of the 

polymer into its building blocks, depending on the molecule 

placed at the end of the polymer. Thus, it is possible to design 

a linear polymer based on a polyurethane backbone with a pH 

sensitive capping molecule as trigger. Dropping the pH would 

cleavage the carbamate linkage of the trigger, which would 

start the sequential 1-6 elimination and decarboxylation 

reactions yielding CO2 and the starting monomer.  

Combining both materials, MSNs and SIPs, in a single 

functional responsive nanocarrier would provide access to the 

benefits of both materials, i.e., the high loading capacity of a 

variety of cargoes into MSNs, and the responsiveness of pH-

sensitive SIPs to control the release. Decoration of the MSNs 

pore entrances with pH-responsive SIP gatekeepers that avoid 

premature release of the cargo and unblock the pores upon pH 

drops, represent a new and promising concept that is explored 

here for the first time (Scheme 2).   

Scheme 2. Schematic representation of the nanocarrier response to 

acid pH. Cleavage of the protecting group generates an intermediate 

that undergoes sequential 1,6-elimination and decarboxylation 

reactions to form the initial monomer, disassembling the immolative 

polymer and allowing the cargo release.    

In this work we have developed a smart nanocarrier able to 

respond to changes in the pH for potential applications in 

cancer treatment. For this purpose, we have selected MSNs as 

carriers and a SIP with a trigger sensitive to acid pH to block 

the pore entrances and prevent premature release. The pH 

sensitivity of the nanosystem was evaluated in-vial showing 

that cargo release took place in acidic conditions, while at 

physiological pH there was almost no release. The 

biocompatibility of the system was evaluated with different 

cells, and internalisation of the nanoparticles was also 

demonstrated. 

MSNs were synthesised via sol-gel method under basic 

conditions using hexadecyltrimethylammonium bromide 

(CTAB) as structure directing agent following a previously 

published method.
23

 The sol-gel method allows a fine control 

on the final composition of the nanoparticles under mild 

conditions.
24,25

 The spherical morphology of the as-produced 

MSNs was confirmed through Scanning Electron Microscopy 

(SEM) and Transmission Electron Microscopy (TEM), as can be 

observed in Figure 1a and 1b, with average sizes of ca. 150 nm 

(see ESI, Figure S3 with Dynamic Light Scattering, DLS, studies). 

Figure 1. (a) SEM images of MSNs; (b) TEM images of MSNs; (c) 

Nitrogen adsorption and desorption isotherms of MSN (black solid 

line), MSN-CS (blue dashed line) and MSN-CS-SIP (red dotted line) 

(inset: pore size distribution determined by the BJH method from the 

desorption branch of the isotherm); (d) XRD patterns of MSN (black 

solid line), MSN-CS (blue dashed line) and MSN-CS-SIP (red dotted 

line).   

Typical adsorption-desorption isotherms of MCM-41-like 

materials with cylindrical pores were observed (Figure 1c), 

with pore diameters centred at ca. 2.7 nm. The characteristic 

hexagonal arrangement of the pores was confirmed through 

low angle X-Ray Diffraction (XRD) analyses (Figure 1d), where 

typical well resolved maxima from well-ordered 2D-hexagonal 

structure with p6mm space group were observed. 

A linear self-immolative polymer was produced to cover the 

pore entrances and avoid premature release of the cargo. We 

employed a polyurethane backbone with a BOC protecting 

group on the terminal amine that acted as a trigger. A pH drop 

would cleave the protecting group and initiate the disassembly 

of the polymer. The SIP was synthesised by a modification of a 

previously published method (Figure 2a),
19

 producing the 

monomer 1 from 4-aminobenzyl alcohol and phenyl 

chloroformate. Then, the polymerisation process using DBTL as 

catalyst and 2 as end-group leaded to the polymeric chain 3 

with an average of about 20 monomers (determined by NMR, 

through the ratio benzylic hydrogens at the molecule tail vs. 

those in the polymeric backbone). 

The self-immolative behaviour of the SIP was confirmed by 

treating the polymer with trifluoroacetic acid in CH2Cl2, which 

are the standard conditions for removing BOC protecting 

groups. After the acid treatment, all characteristic NMR peaks 

of SIP had disappeared (Figure S8), as expected. 

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Figure 2. (a) Schematic representation of the SIP synthesis; (b) Schematic representation of the SIP grafting to the MSNs. 

 

The successful attachment of the SIP to the MSNs was 

achieved through a previous modification of the nanoparticles 

with an alkoxysilane bearing chloride groups at the other end 

(denoted CS) (Figure 2b). Those modified-particles (MSN-CS) 

were characterised through thermogravimetric (TG) analysis 

(Fig. S1), where the increase of weight loss confirmed the 

presence of organic matter, together with elemental analysis 

(Table 1), where the increment of C % verifies the linker 

grafting. The C-H stretching bands from Fourier Transform 

Infrared spectroscopy (FTIR, Fig. S2) also confirmed the 

presence of the linker.  

Addition of polymer 3, previously activated with DIPEA, to the 

MSN-CS leaded to SIP coating (MSN-CS-SIP). XRD analyses 

after functionalisation (Figure 1d) showed that the ordered 

mesostructure survived the process, although the progressive 

reduction of the intensity might be ascribed to the partial 

filling of the pores by some polymer chains, as it was 

previously observed when functionalising MSNs with large 

dendrimers.
26

 The successful SIP coating onto MSNs was 

confirmed through different characterisation techniques. The 

great weight loss observed in TG analyses (Fig. S1) is indicative 

of the great amount of SIP present. FTIR spectrum of MSN-CS-

SIP (Fig. S2) exhibits additional bands to those typical from 

silica materials at ca. 1650 cm-1, typical from C-O stretching 

vibrations from carbamates, verifying the presence of the 

polymer. This is in agreement with the data obtained from N2 

analyses (Table 1), in which the reduction of the surface area 

and pore volume is indicative of the presence of the polymer 

blocking the pore entrances. Finally, the increase of N % in the 

elemental analysis in MSN-CS-SIP confirms the presence of the 

polymer. 

Table1. Main properties of the materials produced in this work. 

Material MSN MSN-CS MSN-CS-SIP 

Organic matter by TG (%) 5.3 14.4 20 

Elemental analysis (%) 

 

C: 3.95 

H: 2.09 

N: 0.06 

C: 9.34 

H: 2.34 

N: 0.11 

C: 10.76 

H: 2.46 

N: 0.53 

Surface area (m
2
/g) 1053 914 671 

Pore Volume (cm
3
/g) 1.05 1.02 0.60 

Pore width (nm) 2.74 2.66 2.19 

Size  (nm); PDI 190; 0.467 190; 0.467 190; 0.358 

Zeta Potential (mV) -35.3 -29.0 -23.8 

Finally, the changes in the zeta potential to less negative 

values confirm the correct functionalisation. However, due to 

the small molecular weight of SIP the size was not affected by 

the functionalisation, either at pH 7.4 or pH 5.  

After confirmation of the polymer grafting on the surface of 

MSN, drug delivery capabilities of the system were evaluated. 

Fluorescent cargo, tris(2,2´-bipyridine)dichloro ruthenium (II) 

denoted as Ru, was loaded into the network of cavities of the 

mesoporous nanoparticles overnight before the blocking the 

pore entrances with the SIP polymer (for further details see 

Supporting Information). The successful Ru loading was 

confirmed by the decrease in the pore volume measured 

through N2 adsorption (data not shown).  

The responsiveness to pH of the system here developed was 

evaluated through an in-vial Ru release from sample MSN-CS-

SIP at 37
o
C using transwells at different pHs, i.e. 7.4 and 5. The 

data from the release kinetics, Figure 3, showed that there was 

almost no cargo release at physiological pH, which means that 

the nanocarrier would travel through the blood stream 

without premature release of the payload. However, when the 

pH of the solution dropped to pH 5, there was a fast release of 

the loaded Ru, as it can be observed in Figure 3. This behaviour 

confirmed that the polymer was disassembling as a 

consequence of the acid pH, opening the pore entrances and 

favouring the release of their cargo only at acid environments.  

Figure 3. In-vial cumulative Ru release (in percentage) vs. time from 

MSN-CS-SIP at physiological and acid pHs (Repeated 3 times each 

measurement; Standard Error of the Mean (SEM)). 

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Moreover, after being exposed to acid pH, the zeta potential 

of MSN-CS-SIP increased from -23.8 mV to -10.7 mV. That 

would confirm that the self-immolation actually took place, as 

its residue is a molecule of 4-aminobenzyl alcohol. 

Once the MSNs covered with the SIPs nanocarrier were fully 

characterised and their pH-sensitive release capabilities 

demonstrated in-vial, the next step was analysing their 

behaviour with cells. The in vitro cytotoxicity study was 

determined by the exposition of MC3T3-E1 pre-osteoblastic 

cells to different amounts of nanoparticles (50, 100, 200 and 

300 µg/mL). Figure 4 shows that none of the studied 

concentrations, except 300 µg/mL, induced significant 

cytotoxicity measured by an Alamar Blue assay (cell viability 

was > 99% that of the control). Similar results were obtained in 

LNCaP tumoral cells (Figure S9).  

Figure  4. (a) MC3T3-E1 cell viability in contact with different concentrations 
of nanoparticles at 24, 48 and 72h of cell culture. Similar proliferation results 
were obtained in LNCaP cells. *p<0.05 vs control without nanoparticles 
(Student´s t-test). (b) Fluorescence microscopy images of LNCaP cells 
incubated with nanoparticles at 2 hours of cell culture. From left to right: 
green fluorescence (nanoparticles with fluorescein) and overlay image with 
blue fluorescence (nuclei). 

Cellular internalization of the nanoparticles was observable by 

fluorescence microscopy and analyzed by flow cytometry in LNCaP 

cells in contact with the nanoparticles (100µg/mL) for 2 hours. No 

fluorescence was observed in the end slices corresponding to the 

external cellular surfaces, suggesting that the nanoparticles did not 

adsorb on the cell membranes. Therefore, we observed that the 

nanoparticles at 100µg/mL were internalized by LNCaP cells. The 

cellular uptake observed by fluorescence microscopy was also 

confirmed by flow cytometry (19.25±1.5% of nanoparticles 

incorporation) in the same cells, at 2 hours. The low cellular 

internalization would be in agreement with the fact that positively 

charged
27

 or targeted
28

 nanocarriers show better cellular 

internalization than those negative, as in the case of MSN-CS-SIP. 

Conclusions 

In conclusion, we have developed for the first time Mesoporous 

Silica Nanoparticles capped with acid responsive Self-Immolative 

Polymers. The cargo release can be triggered by acid pH, typical 

from tumours microenvironments. The biocompatibility of this new 

delivery nanoplatform has been demonstrated with different cell 

types, and the effective nanoparticle internalization has been 

achieved in tumoral cells. We envision that the synergy from MSNs 

carriers and SIPs could be of a great interest for future applications 

in nanomedicine to fight against cancer.  

 

The authors thank funding from the EU H2020-NMP-PILOTS-2015 

program through the grant no. 685872 (MOZART) and the European 

Research Council (Advanced Grant VERDI; ERC-2015-AdG Proposal 

no. 694160). D. Lozano is recipient of postdoctoral research 

contract from Ministerio de Economía y Competitividad (FPDI-2013-

17268), Spain. 

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254x190mm (96 x 96 DPI)  

 

 

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DOI: 10.1039/C6RA26771H

http://creativecommons.org/licenses/by/3.0/
http://creativecommons.org/licenses/by/3.0/
http://dx.doi.org/10.1039/c6ra26771h